Abstract:
A method and a system for selective-content processing of panoramic multimedia signals are disclosed. Features of panoramic cameras and low-latency virtual-reality headsets are exploited to create an advanced efficient system for covering events of diverse and fast-motion actions for the purpose of both broadcasting and data streaming. The disclosed system employs a virtual-reality headset to produce a display of a multimedia signal and generate geometric data defining a view region of the display. A content-filtered signal is extracted from the multimedia signal, according to the geometric data, for broadcasting and dissemination to client devices of a universal streaming server.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    The present application is a continuation-in-part of U.S. application Ser. No. 15/340,193, entitled “METHOD AND SYSTEM FOR FLOW-RATE REGULATION IN A CONTENT-CONTROLLED STREAMING NETWORK”, filed on Nov. 1, 2016, which claims the benefit from U.S. provisional application 62/249,599 filed on Nov. 2, 2015, and which in turn is a continuation-in-part of U.S. application Ser. No. 15/259,952, entitled “METHOD AND SYSTEM FOR PANORAMIC MULTIMEDIA STREAMING” filed Sep. 8, 2016, which claims the benefit from provisional application 62/216,326, entitled “METHOD AND SYSTEM FOR PANORAMIC MULTIMEDIA STREAMING” filed Sep. 9, 2015. 
         [0002]    The present application also claims the benefit from U.S. provisional application 62/361,627 entitled “METHOD AND SYSTEM FOR FLOW-RATE REGULATION IN A CONTENT-CONTROLLED STREAMING NETWORK”, filed Jul. 13, 2016. 
         [0003]    The entire content of all of the aforementioned applications are incorporated herein by reference. 
     
    
     FIELD OF THE INVENTION 
       [0004]    The present invention relates to broadcasting and/or streaming content-filtered multimedia signals of content selected from output of a multimedia signal source, including panoramic camera. 
       BACKGROUND 
       [0005]    Current broadcasting methods of covering events exhibiting several activities are based on employing multiple cameras to capture activities taking place in different parts of a field of events. At any time, a person selects content captured by one of the cameras to broadcast. 
         [0006]    The availability of panoramic cameras, each of which covering a view of a solid angle of up to 4π Steradians, motivates exploring alternate methods of covering such events. 
         [0007]    Conventionally, streaming servers have been used to perform multimedia signal adaptation and distribution to individual client devices. With panoramic multimedia-signals, a high-capacity path need be established between the multimedia source and the streaming server, paths of adaptive capacities need be established between the streaming server and multiple client devices, and the streaming server need be equipped with powerful processing facilities. A streaming server may transmit multimedia data to multiple client devices. The server may perform transcoding functions to adapt data according to characteristics of client devices as well as to conditions of network paths from the server to the client devices. The multimedia data may represent video signals, audio signals, static images, and text. 
         [0008]    Streaming multimedia data containing panoramic video signals require relatively higher capacity transport resources and more intensive processing. A panoramic video signal from a video source employing a panoramic camera occupies a relatively high bandwidth of a transmission medium. Sending the panoramic video signal directly from the video source to a client device requires a broadband path from the video source to the client&#39;s device and high-speed processing capability at the client device. Additionally, the video signal may require adaptation to suit differing characteristics of individual client devices. 
         [0009]    In a panoramic-multimedia streaming system, it is desirable to provide clients with the capability to adaptively select view regions of panoramic scenes during a streaming session. It is, therefore, an object of the present invention to provide a flexible streaming server with the capability of client-specific signal-content filtering as well as signal processing to adapt signals to different types of client devices and to varying capacities of network paths to client devices. It is another object of the present invention to provide a method and a system for regulating data flow rate in a network hosting a streaming server. The system relies on a flexible streaming server with adaptive processing capability and adaptive network connectivity where the capacity of network paths to and from multimedia data sources, including panoramic video sources, and client devices may vary temporally and spatially. 
       SUMMARY 
       [0010]    One of the objectives of the present invention is to provide an efficient broadcasting and streaming system employing a 4π panoramic camera to cover an event with an operator wearing a low-tracking latency Virtual Reality (VR) headset. On going research in the area of positional tracking aims at reducing tracking latency to a few milliseconds. The operator need not be located at the field of events. 
         [0011]    A panoramic camera produces a raw signal of very high bit rate which may be transmitted over a high-speed transmission link to a “monitoring facility” which may be on board of a vehicle situated close to the field of events. The raw signal may be sent without compression, or after undergoing light compression, to the monitoring facility if transmission link is a fiber-optic link or a very short wireless link. At the monitoring facility, the received panoramic signal is decompressed, where applicable, and de-warped. 
         [0012]    In accordance with one aspect, the present invention provides a method of communication comprising acquiring a source signal from a panoramic signal source and employing a virtual-reality headset to produce a virtual-reality display of a pure signal comprising multimedia signals and generate geometric data defining a selected view-region definition data of the display. The virtual-reality display may be produced from the pure signal using an internal display device of the virtual-reality headset and/or an external display device. 
         [0013]    A content filter extracts a content-filtered signal from the pure signal according to the geometric data. The content-filtered signal is forwarded to a broadcasting apparatus and optionally to a streaming server which generates content-filtered signals based on viewers&#39; selections. The virtual-reality headset comprises a processor and memory devices to perform the process of generating the geometric data and tracking of changing gaze orientation of an operator wearing the virtual-reality headset. 
         [0014]    A sensor within the virtual-reality headset provides parameters defining a current gaze orientation of the operator. A content filter is devised to determine the selected view region according to the current gaze orientation and a predefined shape of the view region. 
         [0015]    The pure signal is produced from a source signal received from a panoramic signal source. The source signal includes multimedia signal components and a signal descriptor identifying the multimedia signal. The signal descriptor identifies content of the source signal as one of: a de-warped raw signal, herein called a pure signal; an unprocessed raw signal; a raw (warped) compressed signal; and a de-warped compressed signal. If the content of the source signal is not the pure signal, the source signal is supplied to a matching pure-signal generator to produce the pure signal. 
         [0016]    The process of generating the geometric data comprises steps of determining a gaze position of a viewer of the virtual-reality display, and determining spatial coordinates of a contour of a predefined form surrounding the gaze position. 
         [0017]    The content-filtered signal is extracted from the pure signal according to the geometric data. The content-filtered signal comprises samples of the pure signal corresponding to points within the contour. The function of the content filter may be performed within the virtual-reality headset so that extracting the content-filtered signal may be performed using processor executable instructions stored in a memory device of the virtual-reality headset. Alternatively, extracting the content-filtered signal may be performed at an independent content filter coupled to the virtual-reality headset and comprising a respective processor and a memory device. 
         [0018]    The content-filtered signal may be compressed to produce a compressed filtered signal. The compressed filtered signal may then be transmitted to a broadcasting station, through channel, and/or a Universal Streaming Server, through channel and network. 
         [0019]    The source signal received from the panoramic signal source may be relayed, using repeater, to a streaming apparatus that comprises an acquisition module and a Universal Streaming Server. The acquisition module generates a replica of the pure signal which is supplied to the Universal Streaming Server. The Universal Streaming Server is configured to provide viewer content control to a plurality of viewers. 
         [0020]    In accordance with another aspect, the present invention provides a communication system configured to receive a modulated carrier source signal and extract a content-filtered multi-media signal for broadcasting. The system comprises a virtual-reality headset, a content filter, and a transmitter. 
         [0021]    The virtual-reality headset is configured to present a virtual-reality display of a pure signal derived from the received modulated carrier source signal. The content filter is configured to generate a content-filtered signal from the pure signal according to the geometric data. The transmitter sends the content-filtered signal along a channel to a broadcasting station. 
         [0022]    The virtual-reality headset comprises a sensor of gaze orientation of an operator wearing the virtual-reality headset and a memory device storing processor executable instructions causing a processor to generate geometric data defining a view region of the display according to the gaze orientation. The content filter comprises a respective processor and a memory device. 
         [0023]    The communication system further comprises an acquisition module for deriving the pure signal from the received panoramic multimedia signal. The acquisition module comprises a receiver, a set of pure-signal generators for generation the pure signal, and a selector. Receiver generates from a modulated carrier source signal a source multimedia signal and a corresponding signal descriptor. Selector directs the source multimedia signal to a matching pure-signal generator according to the corresponding signal descriptor. 
         [0024]    The virtual-reality headset is further configured to determine a gaze position of the operator and the geometric data as representative spatial coordinates of a contour of a predefined form surrounding the gaze position. The content-filtered signal comprises samples of the pure signal corresponding to content within the contour. 
         [0025]    Optionally, the communication system may comprise a repeater for relaying the modulated carrier source signal sent from a panoramic signal source to a streaming apparatus. The streaming apparatus comprises an acquisition module for generating a replica of the pure signal and a Universal Streaming Server receiving the pure signal and providing content-filtered signals based on individual viewer selection. 
         [0026]    In accordance with a further aspect, the present invention provides a method of communications comprising generating at an acquisition module a pure signal from a multimedia signal, received from a panoramic multimedia source and employing a content selector configured to extract from the pure signal content-filtered signals corresponding to varying view-regions of a displayed view regions. 
         [0027]    The content selector performs processes of employing a virtual-reality headset to view a display of the pure signal and determining a current gaze position from the virtual-reality headset. 
         [0028]    A displacement of the current gaze position from the reference gaze position is then determined, the reference gaze position being initialized, for example as a Null value. The reference gaze position is updated to equal the current gaze position subject to a determination that the displacement exceeds a predefined threshold. 
         [0029]    View-definition data are then generated using the reference gaze position and a predefined contour shape (such as a rectangle). A content-filtered signal is extracted from the pure signal according to the view-definition data and transmitted to a broadcasting facility. 
         [0030]    The gaze position is represented as a vector of multiple dimensions and the displacement is determined as Euclidean distance between a first vector representing the reference gaze position and a second vector representing the current gaze position. The multiple dimensions may be selected as tilt, pan, and zoom parameters acquired from a sensor of the virtual-reality headset. The view-definition data may be retained for reuse for cases where the displacement is less than or equal to the predefined threshold. 
         [0031]    Thus, methods and systems for selective content processing based on a panoramic or another multimedia camera and a virtual-reality headset have been provided. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0032]    Embodiments of the present invention will be further described with reference to the accompanying exemplary drawings, in which: 
           [0033]      FIG. 1  illustrates a system for panoramic multimedia streaming comprising a panoramic multimedia source and a universal streaming server, in accordance with an embodiment of the present invention; 
           [0034]      FIG. 2  illustrates a system for panoramic multimedia streaming comprising multiple panoramic multimedia sources and multiple universal streaming servers, in accordance with an embodiment of the present invention; 
           [0035]      FIG. 3  illustrates communication options between a panoramic multimedia source and a universal streaming server, in accordance with an embodiment of the present invention; 
           [0036]      FIG. 4  illustrates communication paths corresponding to the communication options of  FIG. 3 ; 
           [0037]      FIG. 5  illustrates components of an end-to-end path corresponding to a first communication option of the communication options of  FIG. 3 , in accordance with an embodiment of the present invention; 
           [0038]      FIG. 6  illustrates components of an end-to-end path corresponding to a second communication option of the communication options of  FIG. 3 , in accordance with an embodiment of the present invention; 
           [0039]      FIG. 7  illustrates components of an end-to-end path corresponding to a third communication option of the communication options of  FIG. 3 , in accordance with an embodiment of the present invention; 
           [0040]      FIG. 8  illustrates components of an end-to-end path corresponding to a fourth communication option of the communication options of  FIG. 3 , in accordance with an embodiment of the present invention; 
           [0041]      FIG. 9  illustrates multimedia signals and control signals at input and output of a universal streaming server, in accordance with an embodiment of the present invention; 
           [0042]      FIG. 10  illustrates components of an exemplary universal streaming server employing client-specific adaptation modules, in accordance with an embodiment of the present invention; 
           [0043]      FIG. 11  details a client-specific adaptation module of the exemplary universal streaming server of  FIG. 10 , in accordance with an embodiment of the present invention; 
           [0044]      FIG. 12  illustrates temporal variation of flow rate of a compressed video signal; 
           [0045]      FIG. 13  illustrates modules for generating video signals of reduced flow rates yet suitable for exhibiting panoramic full spatial coverage to enable a client to select a preferred partial-coverage view, in accordance with an embodiment of the present invention; 
           [0046]      FIG. 14  illustrates a process of requesting and acquiring a content-filtered video signal, in accordance with an embodiment of the present invention; 
           [0047]      FIG. 15  illustrates temporal flow-rate variation of video signals transmitted from a universal streaming server to a client device, the video signals including a frame-sampled video signal followed by a compressed video signal; 
           [0048]      FIG. 16  illustrates the signal-editing module of  FIG. 4  structured as a content-filtering stage and a signal-processing stage, in accordance with an embodiment of the present invention; 
           [0049]      FIG. 17  illustrates the content-filtering stage of  FIG. 16  implemented as an array of content filters for concurrent generation of different partial-content signals from a full-content signal, in accordance with an embodiment of the present invention; 
           [0050]      FIG. 18  illustrates a signal-processing unit of the signal-processing stage of  FIG. 16 ; 
           [0051]      FIG. 19  illustrates the signal-editing module of  FIG. 16  including details of the content-filtering stage and signal-processing stage, in accordance with an embodiment of the present invention; 
           [0052]      FIG. 20  illustrates processes of video signal editing for a target client device, in accordance with an embodiment of the present invention; 
           [0053]      FIG. 21  details a module for determining permissible flow rates; 
           [0054]      FIG. 22  illustrates components of a client device, in accordance with an embodiment of the present invention; 
           [0055]      FIG. 23  illustrates communication paths between a universal streaming server and panoramic multimedia sources in accordance with an embodiment of the present invention; 
           [0056]      FIG. 24  illustrates communication paths between a universal streaming server and panoramic multimedia sources and communication paths between the universal streaming server and a plurality of heterogeneous client devices of a streaming system, in accordance with an embodiment of the present invention; 
           [0057]      FIG. 25  illustrates communication paths between a universal streaming server and a multimedia signal source and communication paths between the universal streaming server and two client devices where an automaton associated with a client device may send commands to the universal streaming server, in accordance with an embodiment of the present invention; 
           [0058]      FIG. 26  illustrates a modular structure of the universal streaming server, in accordance with an embodiment of the present invention; 
           [0059]      FIG. 27  illustrates a learning module coupled to the universal streaming server of  FIG. 26 , in accordance with an embodiment of the present invention; 
           [0060]      FIG. 28  illustrates processes performed at a universal streaming server where a panoramic video signal is adapted to client-device types then content filtered, in accordance with an embodiment of the present invention; 
           [0061]      FIG. 29  illustrates processes performed at universal streaming server where a panoramic video signal is content filtered then adapted to client-device types, in accordance with another embodiment of the present invention; 
           [0062]      FIG. 30  is a flow chart depicting processes of acquisition of a panoramic multimedia signal and adapting the acquired multimedia signal to individual clients, in accordance with an embodiment of the present invention; 
           [0063]      FIG. 31  is a flow chart depicting executing the processes of  FIG. 30  in a different order, in accordance with another embodiment of the present invention; 
           [0064]      FIG. 32  illustrates a streaming-control table maintained at the universal streaming server for a specific video-source, in accordance with an embodiment of the present invention; 
           [0065]      FIG. 33  illustrates a process of initial adaptation of a multimedia signal for a specific client, in accordance with an embodiment of the present invention; 
           [0066]      FIG. 34  illustrates a table recording a count of viewing-preference patterns for each type of client devices, in accordance with an embodiment of the present invention; 
           [0067]      FIG. 35  illustrates processes of flow-rate control based on signal-content changes and performance metrics, in accordance with an embodiment of the present invention; 
           [0068]      FIG. 36  illustrates a control system of a universal streaming server, in accordance with an embodiment of the present invention; 
           [0069]      FIG. 37  illustrates a combined process of content filtering and flow-rate adaptation of a signal in the streaming system of  FIG. 23  and  FIG. 24 , in accordance with an embodiment of the present invention; 
           [0070]      FIG. 38  illustrates a content filter of a universal streaming server, in accordance with an embodiment of the present invention; 
           [0071]      FIG. 39  illustrates initial processes performed at the universal streaming server to start a streaming session, in accordance with an embodiment of the present invention; 
           [0072]      FIG. 40  illustrates a method of adaptive modification of content and flow rate of a signal, in accordance with an embodiment of the present invention; 
           [0073]      FIG. 41  illustrates criteria of determining a preferred encoding rate of a signal based on performance measurements pertinent to receiver condition and network-path condition, in accordance with an embodiment of the present invention; 
           [0074]      FIG. 42  illustrates processes of determining a preferred encoding rate of a signal based on the criteria illustrated in  FIG. 41 , in accordance with an embodiment of the present invention; 
           [0075]      FIG. 43  illustrates a method of eliminating redundant processing of content selection in a universal streaming system serving numerous clients, in accordance with another embodiment of the present invention; 
           [0076]      FIG. 44  illustrates transient concurrent content-filtering of a video signal to enable seamless transition from one view region to another, in accordance with another embodiment of the present invention; 
           [0077]      FIG. 45  illustrates coupling the universal streaming server to a router-switch of a network, in accordance with an embodiment of the present invention; 
           [0078]      FIG. 46  illustrates prior-art system for selective content broadcasting using multiple cameras, multiple displays, and a selector (switcher); 
           [0079]      FIG. 47  illustrates an arrangement for broadcasting operator-defined content of multimedia signals in accordance with an embodiment of the present invention; 
           [0080]      FIG. 48  illustrates a first system for combined broadcasting and streaming comprising a broadcasting subsystem and a streaming subsystem in accordance with an embodiment of the present invention; 
           [0081]      FIG. 49  illustrates an acquisition module for extracting a pure multimedia signal, comprising a pure video signal and other multimedia components, from a modulated carrier signal received from a panoramic multimedia signal source in accordance with an embodiment of the present invention; 
           [0082]      FIG. 50  illustrates an arrangement for content selection for broadcasting, in accordance with an embodiment of the present invention; 
           [0083]      FIG. 51  illustrates a first broadcasting subsystem for selective content broadcasting employing a panoramic camera and a virtual reality (VR) headset, in accordance with an embodiment of the present invention; 
           [0084]      FIG. 52  illustrates a second broadcasting subsystem for selective content broadcasting and streaming comprising an augmented content selector equipped with a content buffer and a distant content selector, in accordance with an embodiment of the present invention; 
           [0085]      FIG. 53  illustrates control data sent from the distant content selector to the augmented content selector of the broadcasting subsystem of  FIG. 52 , in accordance with an embodiment of the present invention; 
           [0086]      FIG. 54  illustrates data exchange between the augmented content selector and the distant content selector of the broadcasting subsystem of  FIG. 52 , in accordance with an embodiment of the present invention; 
           [0087]      FIG. 55  illustrates frame-data flow through the content buffer of the augmented content selector of the broadcasting subsystem of  FIG. 52 ; 
           [0088]      FIG. 56  illustrates a second system for combined selective content broadcasting and streaming employing a panoramic camera and a VR headset, the system comprising a routing facility and a distant content selector, in accordance with an embodiment of the present invention; 
           [0089]      FIG. 57  details the routing facility of the system of  FIG. 56 ; 
           [0090]      FIG. 58  details the distant content selector of the system of  FIG. 56 ; 
           [0091]      FIG. 59  illustrates a hybrid system for selective content broadcasting using a panoramic camera, a bank of content filters, and a conventional switcher, in accordance with an embodiment of the present invention; 
           [0092]      FIG. 60  is a flowchart depicting basic processes of the broadcasting subsystem of  FIG. 51 ; 
           [0093]      FIG. 61  is a flowchart depicting basic processes of the hybrid system of  FIG. 59 ; 
           [0094]      FIG. 62  is a flowchart depicting basic processes of the first system of  FIG. 48  and  FIG. 51 ; 
           [0095]      FIG. 63  illustrates a method of content-filtering of a panoramic multimedia signal to produce an operator-defined content for broadcasting, in accordance with an embodiment of the present invention; 
           [0096]      FIG. 64  illustrates processes performed at the remote content controller of the system of  FIG. 56 , in accordance with an embodiment of the present invention; and 
           [0097]      FIG. 65  illustrates processes  6500  performed at augmented content selector of the system of  FIG. 56 , in accordance with an embodiment of the present invention. 
       
    
    
     TERMINOLOGY 
       [0000]    
       
         Geometric data: Data defining a selected view-region of a display of a video signal is herein referenced as “geometric data”. 
         Gaze position: A point at which an operator of a virtual-reality headset is perceived to be looking is referenced herein as a “gaze position”. Generally, the gaze position may be represented as a set of parameters or a vector in a multidimensional space. In one implementation, a gaze position is defined according to conventional “tilt, pan, and zoom” parameters. 
         Multimedia signal: A multimedia signal may comprise a video signal component, an audio signal component, a text, etc. Herein, the term multimedia signal refers to a signal which contains a video signal component and may contain signal components of other forms. All processes pertinent to a multimedia signal apply to the video signal component; processes—if any—applied to other signal components are not described in the present application. 
         Signal: A data stream occupying a time window is herein referenced as a “signal”. The duration of the time window may vary from a few microseconds to several hours. Throughout the description, the term “signal” refers to a baseband signal. The term “transmitting a signal” over a network refers to a process of a signal modulating a carrier, such as an optical carrier, and transmitting the modulated carrier. The term “receiving a signal” from a network refers to a process of receiving and demodulating a modulated carrier to recover a modulating base band signal. 
         Panoramic video signal: A video signal of an attainable coverage approximating full coverage is referenced as a panoramic video signal. The coverage of a panoramic video signal may exceed 2π steradians. 
         Panoramic multimedia signal: A composite signal comprising audio signals, image signals, text signals, and a panoramic video signal is herein called a panoramic multimedia signal. 
         Universal streaming server: A streaming server distributing panoramic multimedia signals with client-controlled content selection and flow-rate adaptation to receiver and network conditions is referenced as a “universal streaming server”. A universal streaming server may be referenced as a “server” for brevity. The server comprises at least one hardware processor and at least one memory device holding software instructions which cause the at least one processor to perform the functions of acquiring multimedia signals and generating client-specific content-filtered multimedia signals under flow control. 
         Full-content signal: A multimedia signal may contain multiple components of different types, such as an encoded audio signal, an encoded video signal, a text, a still image, etc. Any component may be structured to contain multiple separable parts. For example, a panoramic video component of a panoramic signal may be divided into sub-components each covering a respective subtending solid angle of less than 4π steradians. 
         Partial-content signal: The term refers to a signal derived from a full-content signal where at least one separable part of any component is filtered out and possibly other components are filtered out. 
         Coverage of a video signal: The coverage (or spatial coverage) of a video signal is defined herein as the solid angle subtended by a space visible to a camera that produces the video signal. 
         Full-coverage video signal: A video signal of coverage of 4π steradians is referenced as a full-coverage video signal. A full-coverage video signal may be a component of a full-content signal. 
         Signal filtering: The term signal filtering refers to conventional operations performed at a signal receiver to eliminate or reduce signal degradation caused by noise and delay jitter; a signal-filtering process does not alter the content of the signal. 
         Content filtering: The term refers to a process of modifying the information of a signal (following a process of signal filtering) to retain only specific information; content-filtering of a full-coverage (attainable coverage) video signal yields a partial-coverage video signal corresponding to a reduced (focused) view region. 
         Full-coverage camera (or 4π camera): A camera producing a full-coverage video signal is herein referenced as a full-coverage camera or a 4π camera. 
         Attainable-coverage video signal: A full-coverage video signal is produced by an ideal camera. The actual coverage of a video signal produced by a camera is referenced as the attainable coverage. 
         Partial-coverage video signal: A video signal of coverage less than the attainable coverage is referenced as a partial-coverage video signal. A partial-coverage video signal may be a component of a partial-content signal. 
         Partial-coverage multimedia signal: A composite signal comprising audio signals, image signals, text signals, and a partial-coverage video signal is herein called a partial-coverage multimedia signal. 
         Source: A panoramic multimedia source comprises a full-coverage camera as well as de-warping and decompression modules; the term “source” is used herein to refer to a panoramic multimedia source. 
         Raw video signal: The signal produced by a camera is referenced as a “raw video signal”. 
         Corrected video signal: A de-warped raw video signal is referenced as a “corrected video signal”. 
         Source video signal: A video signal received at a panoramic multimedia server from a panoramic multimedia source is referenced as a “source video signal”; a source video signal may be a raw video signal, corrected video signal, compressed video signal, or a compact video signal. 
         Source multimedia signal: A multimedia signal received at a panoramic multimedia server from a panoramic multimedia source is referenced as a “source multimedia signal”; a source multimedia signal may contain a source video signal in addition to signals of other forms such as an audio signal or a text signal. 
         Processor: The term “processor” used herein refers to at least one hardware (physical) processing device which is coupled to at least one memory device storing software instructions which cause the at least one hardware processing device to perform operations specified in the software instructions. 
         Compression module: The term refers to a well known device comprising a processor and a memory device storing software instructions which cause the processor to encode an initial video signal to produce a compressed video signal of a reduced bit rate in comparison with the bit rate resulting from direct encoding of the initial video signal. 
         Decompression module: The term refers to a well known device comprising a processor and a memory device storing software instructions which cause the processor to decompress a compressed video signal to produce a replica of an initial video signal from which the compressed video signal was generated. 
         Source compression module: A compression module coupled to a video-signal source to generate a compressed video signal from a raw video signal, or from a de-warped video signal generated from the raw video signal, is a source compression module. Compression module  340  ( FIGS. 3, 4, 7, and 8 ) is a source compression module. 
         Server compression module: A compression module coupled to a server to generate a compressed video signal from a source video signal video signal is herein referenced as a “server compression module”. Compression modules  1160  ( FIG. 11 ),  1340 ,  1360  ( FIG. 13 ), and  2030  ( FIG. 20 ) are server compression modules. 
         Server decompression module: A decompression module coupled to a server to generate a replica of a raw video signal or a replica of a de-warped video signal generated from the raw video signal, is herein referenced as a “server decompression module”. Decompression module  350  ( FIGS. 3, 4, 7, and 8 ) is a server decompression module. 
         Client decompression module: A decompression module coupled to a client device to generate a replica of a pure video signal, or a content-filtered video signal, generated at a server, is herein referenced as a “client decompression module”. Compression module  2270  ( FIG. 22 ) is a client decompression module. 
         Compressed video signal: A compressed raw video signal is referenced as a “compressed video signal”. 
         Compact video signal: A compressed corrected signal is referenced as a “compact video signal”. 
         Rectified video signal: Processes of de-warping a raw video signal followed by compression, then decompression or processes of compressing a raw video signal followed by decompression and de-warping yield a rectified video signal. 
         Pure video signal: A corrected video signal or a rectified video signal is referenced herein as a pure video signal. A pure video signal corresponds to a respective scene captured at source. 
         Signal sample: The term refers to a video signal of full coverage (attainable coverage) derived from a pure video signal, or from a transcoded video signal derived from the pure video signal. The flow rate (bit rate) of a signal sample would be substantially lower than the flow rate of the video signal from which the signal sample is derived. A signal sample is sent to a client device to enable a viewer at the client device to select and identify a preferred view region. 
         Encoder: An encoder may be an analogue to digital converter or a digital-to-digital transcoder. An encoder produces an encoded signal represented as a stream of bits. 
         Encoding rate: The number of bits per unit time measured over a relatively short period of time is considered an “instantaneous” encoding rate during the measurement period. Rapid natural variation of the encoding rate may take place due to the nature of the encoded signal. A controller may force encoding-rate variation in response to time-varying conditions of a communication path through a network shared by numerous (uncoordinated) users. Forced encoding-rate variations are typically slower than spontaneous variations of the encoding rate. 
         Flow rate: Without data loss, the flow rate of a signal along a path to destination equals the encoding rate of the signal at a server. Because of the natural fluctuations of the encoding rate, a parametric representation of the encoding rate may be specified by a user or determined at a controller. The parametric representation may be based on conjectured statistical distribution of naturally varying encoding rates. 
         Metric: A metric is a single measure of a specific property or characteristic derived from sufficient performance measurements using, for example, regression analysis. 
         Acceptance interval: A metric is considered to reflect a favourable condition if the value of the metric is bounded between a lower bound and an upper bound defining an “acceptance interval”. An acceptance interval is inclusive, i.e., it includes the values of the lower bound and the upper bound in addition to the values in between. 
         Metric index: A metric may be defined to be in one of three states: a state of “−1” if the value of the metric is below the lower bound of a respective acceptance interval, a state of “1” if the value is above a higher bound of the acceptance interval, and a state “0” otherwise, i.e., if the value is within the acceptance interval including the lower and higher bounds. A metric index is the state of the metric. 
         Transmitter: The term refers to the conventional device which modulates a carrier wave (an optical carrier or a microwave carrier) with a baseband signal to produce a modulated carrier. 
         Receiver: The term refers to the conventional device which demodulates a modulated carrier to extract the transmitted baseband signal. 
         Processor: The term refers to a hardware device (a physical processing device) 
         Gb/s, Mb/s: Gigabits/second (10 9  bits/second), Megabits/second (10 6  bits/second) 
       
     
         [0142]    The server of the present invention receives and disseminates panoramic multimedia signals. A panoramic multimedia signal contains a panoramic video signal in addition to signals of other forms, such as an audio signal and text. The description and the claimed subject mater focus on novel features relevant to the video-signal component. However, it is understood that the server delivers to client devices edited panoramic video signals together with signals of other types. 
       REFERENCE NUMERALS 
       [0000]    
       
           100 : System for streaming panoramic multimedia signals 
           110 : Panoramic multimedia source 
           115 : Transmission medium 
           120 : Universal streaming server (referenced as a “server” for brevity) 
           150 : Network 
           180 : Client device 
           200 : Streaming system comprising multiple sources and multiple servers 
           310 : Panoramic 4π camera 
           312 : Raw signal 
           320 : De-warping module at server 
           322 : Corrected signal 
           324 : Rectified signal 
           330 : De-warping module at source 
           340 : Compression module 
           342 : Compressed signal 
           343 : Compact signal 
           350 : Decompression module 
           352 : Decompressed signal 
           420 : Pure video signal 
           460 : Signal-editing module 
           480 : High-capacity path 
           490 : Lower-capacity path 
           500 : First communication path 
           520 : Source transmitter 
           528 : Modulated carrier signal to server 
           540 : Server receiver 
           542 : Baseband signal (warped) 
           560 : Interfaces to client-devices 
           585 : Modulated carrier signals to clients 
           600 : Second communication path 
           628 : Modulated carrier signal to server 
           642 : Baseband signal (de-warped) 
           685 : Modulated carrier signals to clients 
           700 : Third communication path 
           720 : Source transmitter 
           728 : Modulated carrier signal to server 
           740 : Server receiver 
           742 : Baseband signal (warped, compressed) 
           785 : Modulated carrier signals to clients 
           800 : Fourth communication path 
           828 : Modulated carrier signal to server 
           842 : Baseband signal (de-warped, compressed) 
           885 : Modulated carrier signals to clients 
           900 : Source video signal ( 312 ,  322 ,  342 , or  343 ) 
           905 : Control data from panoramic multimedia source 
           925 : Control data to panoramic multimedia source 
           935 : Upstream control signals from client devices 
           940 : Edited multimedia signals to client devices 
           945 : Downstream control signals to client devices 
           1000 : Components of a server 
           1005 : All data from/to sources and client devices 
           1008 : At least one dual link to network 
           1010 : Server-network interface 
           1022 : Source control-data module 
           1024 : Source signal-processing module 
           1026 : Client control-data module 
           1060 : Client-specific adaptation module 
           1061 : Client control bus 
           1090 : Combiner of edited multimedia signals 
           1120 : Content-filtering module; also called “content filter” for brevity 
           1122 : Content-filtered video signal 
           1132 : Content-filtered transcoded video signal 
           1140 : Transcoding module 
           1142 : Transcoded content-filtered video signal 
           1152 : Transcoded video signal 
           1160 : Server compression module 
           1220 : Mean bit rate 
           1225 : Effective bit rate 
           1230 : Specified peak bit rate 
           1300 : Selective-viewing options 
           1320 : Frame-sampling module 
           1322 : Full-coverage frame-sampled signal 
           1340 : Spatial-temporal server compression module 
           1342 : Full-coverage compressed signal 
           1360 : Spatial-temporal server compression module 
           1362 : Succession of pre-selected content-filtered signals 
           1364 : Succession of partial-coverage signals 
           1402 : Message from client to server requesting server 
           1404 : Message from client to server defining a selected view region 
           1440 : Compressed content-filtered video signal from server to client 
           1520 : Mean bit rate of compressed video signal 
           1525 : Effective bit rate of compressed video signal 
           1600 : Basic components of signal-editing module 
           1610 : Content-filtering stage 
           1612 : Selected content 
           1630 : Signal-processing unit 
           1650 : Conditioned multimedia signals to a set of client devices 
           1710 : Server-network interface 
           1720 : Content identifier 
           1725 : Decompression module and/or de-warping module 
           1840 : Transcoding module 
           1842 : Signal adapted to a client device 
           1860 : Flow-rate adaptation modules 
           1861 : Buffer for holding a data block 
           1862 : Memory device storing processor-executable instruction for flow-rate adaptation 
           1900 : Exemplary implementation of a signal-editing module 
           1922 : Buffer for holding a data block of a content-filtered signal 
           1923 : memory device storing processor executable instructions which cause a processor to modify the frame rate and/or resolution 
           2000 : Processes of video signal editing for a target client device 
           2012 : Identifier of a preferred view region 
           2014 : Traffic-performance measurements 
           2016 : Nominal frame rate and frame resolution 
           2030 : Server compression module 
           2040 : Module for determining a permissible flow rate as well as a frame rate and frame resolution, compatible with a target client device 
           2050 : Transmitter 
           2052 : Video signal together with accompanying multimedia signals (such as audio signals and/or text) and control signals 
           2060 : Network path 
           2110 : Process of determining requisite flow rate at the display device of the target client device 
           2120 : process of determining a permissible flow rate (reference  2122 ) between the server and the target client device 
           2122 : Permissible flow rate 
           2130 : Process of determining requisite compression ratio 
           2140 : Process of determining whether a compression ratio is acceptable 
           2150 : Module for determining a revised frame rate and or resolution 
           2152 : Revised frame rate and/or a revised resolution 
           2210 : Memory device storing client-device characterizing data 
           2220 : Memory device storing software instructions for interacting with specific servers 
           2230 : Client transmitter 
           2240 : Client receiver 
           2242 : Interface module 
           2250 : Processor 
           2260 : Memory device holding data blocks of incoming multimedia data 
           2270 : Client decompression module 
           2280 : Memory for holding blocks of display data 
           2290 : Display device 
           2314 : Dual control path between a source  110  and a server  120   
           2412 : Network path 
           2512 : dual control path carrying control signals  905  from the source  110  to the server  120  and control signals  925  from the server  120  to the source  110   
           2525 : multimedia payload signal path from a server  120  to a client device  180   
           2526 : Dual control path between a server  120  and a client device 
           2545 : Automaton associated with a client device 
           2610 : At least one hardware processor 
           2620 : A set of modules devised to process a received panoramic video signal  900   
           2621 : Signal-filtering module 
           2640 : Client-device related modules 
           2641 : Client profile database 
           2642 : Client-device characterization module 
           2643 : Module for signal adaptation to client device 
           2651 : Server-source interface 
           2652 : Source characterization module 
           2660 : Client-specific modules 
           2661 : Server-client interface 
           2662 : Module for signal adaptation to client environment 
           2663 : Module for signal adaptation to client viewing preference 
           2725 : Learning module 
           2820 : Decompression modules and de-warping modules 
           2830 : Module employing at least one respective hardware processor for signal adaptation to client-device type 
           2925 : Memory device storing predefined partial-coverage definitions 
           2940 : Module for signal adaptation to client&#39;s device 
           3010 : Process of acquiring a panoramic multimedia signal from a selected panoramic multimedia source 
           3012 : Process of filtering a source video signal to offset degradation caused by noise and delay jitter 
           3014 : Process of decompression of a source video signal if the signal has been compressed at source 
           3018 : Process of video signal de-warping if the signal has not been de-warped at source 
           3020 : Process of receiving a service request from a client 
           3022 : Process of adapting a pure video signal to characteristics of a client&#39;s device 
           3026 : Process of compressing a video signal adapted to characteristics of a client device 
           3028 : Process of signal transmission to a client device 
           3030 : A control signal from the client specifying a preferred view region 
           3032 : Process of ascertaining viewing preference 
           3034 : Process of content filtering 
           3000 : Method of acquisition of a panoramic multimedia signal and adapting the acquired multimedia signal to individual clients 
           3100 : A variation of method  3000   
           3200 : Streaming-control table 
           3300 : Process of adaptation of a video-signal for a specific client device 
           3310 : Process of receiving from a client device a request for service at client-interface module 
           3312 : Process of identifying type of client device 
           3314 : Process of determining prior identification of client device 
           3316 : Process of identifying an existing stream category corresponding to a client device type 
           3320 : Process of creating a new stream category for a new device type 
           3322 : Process of adapting a pure video signal to device type 
           3324 : Process of recording new stream category 
           3326 : Process of selecting an existing stream or creating a new stream 
           3330 : Process of signal transmission to a specific client device 
           3400 : Table indicating a count of viewing options for each type of client devices 
           3500 : Processes of flow-rate control based on signal-content changes and performance metrics 
           3510 : Process of receiving performance measurements 
           3512 : Process of computing performance metrics based on the performance measurements 
           3514 : Process of determining whether a current performance is acceptable 
           3520 : Process of receiving definition of a new content 
           3522 : Process of filtering content of a pure video signal according to received definition of the new content 
           3524 : Process of determining flow-rate requirement corresponding to the new content 
           3540 : process of determining whether to enforce a current permissible flow rate in signal encoding or to acquire a new (higher) permissible flow rate from a network controller 
           3542 : Process of enforcing a current flow rate 
           3544 : Process of communicating with a network controller to acquire an enhanced permissible flow rate 
           3550 : Process of signal encoding under constraint of a permissible flow rate (current or enhanced) 
           3600 : Flow-control system of a universal streaming server 
           3610 : Flow controller 
           3612 : content-definition parameters (content selection parameters) 
           3616 : performance measurements 
           3625 : Server-network interface 
           3630 : Processor of a flow controller 
           3635 : Module for determining a preferred flow rate (Module  3635  may implement processes  3500 ) 
           3650 : Partial-content signal (content-filtered signal) 
           3640 : Encoder of partial-content signal  3650   
           3660 : Compressed signal transmitted to the client device 
           3700 : Combined processes of content filtering and signal flow-rate adaptation 
           3710 : Process of receiving control data from client devices in the form of content-definition parameters and performance measurements. 
           3720 : Process of examining content-definition parameters received from a client device to determine whether content-change is due 
           3730 : Process of determining a preferred flow rate 
           3740 : Process of determining whether a flow-rate change is needed 
           3750 : Process of communicating requisite flow rate to an encoder 
           3760 : Process of communicating content-definition parameters to content filter 
           3770 : An imposed artificial delay to ensure that received client&#39;s control data correspond to the changed signal content 
           3822 : Processor dedicated to a content filter 
           3824 : Software instructions causing processor  3822  to extract a partial-content signal from a full-content signal 
           3826 : Buffer holding blocks of full-content signals 
           3828 : Buffer holding blocks of partial-content signals 
           3860 : Updated content signal 
           3900 : Initial processes performed at a server to start a streaming session 
           3910 : Process of receiving a compressed full-content signal from a signal source 
           3915 : Process of decompressing the full-content signal to recover the original signal generated at source 
           3920 : Process of receiving a connection request from a client device 
           3925 : Process of determining whether connection request specifies content-definition parameters 
           3930 : Process of specifying default content-definition parameters 
           3940 : Process of extracting a partial-content signal based on default content-definition parameters or specified content-definition parameters 
           3950 : Process of determining whether a flow rate for the extracted signal is specified in the connection request 
           3955 : Process of providing a default flow rate to an encoder 
           3960 : Process of signal encoding at a specified flow rate 
           3970 : Transmitting an encoded signal to a target client device 
           4000 : A method of adaptive modification of content and flow rate of an encoded signal 
           4010 : Process of receiving content preference from an automaton associated with a client device 
           4020 : Process of determining whether content-change is requested 
           4030 : Process of extracting a partial-content signal from the full-content signal 
           4040 : Process of signal encoding at a nominal encoding rate 
           4050 : Process of determining encoding rate based on performance data 
           4060 : Process of encoding content-specific signal at a preferred encoding rate 
           4070 : Transmitting encoded content-specific flow-rate-controlled signal to a target client device 
           4100 : Criteria of determining a preferred encoding rate of a signal 
           4110 : Maintaining a current permissible flow rate 
           4120 : Process of determining a permissible flow-rate based on primary metrics 
           4130 : Process of determining a permissible flow-rate based on secondary metrics 
           4140 : Process of determining a permissible flow-rate based on primary metrics and secondary metrics 
           4210 : Process of determining primary metrics based on performance data relevant to a client&#39;s receiver 
           4220 : Process of determining whether any primary metric is above a respective acceptance interval 
           4225 : Process of determining a reduced permissible flow rate based on the primary metrics 
           4230 : Process of determining a secondary metrics based on performance data relevant to conditions of a network path from the server to a client&#39;s device 
           4240 : Process of determining whether any secondary metric is above a respective acceptance interval 
           4245 : Process of determining a reduced permissible flow rate based on the secondary metrics 
           4250 : Process of determining whether each primary metric is below its predefined acceptance interval and each secondary metric is below its predefined acceptance interval 
           4255 : State of maintaining a current encoding rate 
           4260 : Process of determining a new encoding rate based on the primary and secondary metrics 
           4280 : Process of communicating requisite encoding rate to a respective encoder 
           4310 : Process of receiving a full-content signal at a server 
           4320 : Process of creating a register for holding parameters of already extracted partial-content signals 
           4330 : Process of receiving parameters defining partial-content of the full-content signal from a specific client 
           4340 : Process of examining the register to ascertain presence, or otherwise, of a previously extracted partial-content signal 
           4350 : Process of selecting either process  4360  or  4370   
           4360 : Process of providing access to a matching partial-content signal 
           4370 : Process of extracting a new partial-content signal according to new content-definition parameters 
           4380 : Process of adding new content-definition parameters to the register for future use 
           4390 : Process of directing a partial-content signal an encoder 
           4420 : Buffer holding data blocks generated by a signal-editing module  460   
           4450 : Multiplexer 
           4460 : Multiple content-filtered streams 
           4540 : A router-switch connecting to at least one server and/or other router-switches 
           4541 : An input port of a router-switch  4540   
           4542 : An output port of a router-switch  4540   
           4600 : Prior-art system for selective content broadcasting 
           4610 : One of multiple signal sources each signal source including a camera operator, a camera, and a communication transmitter which may include an antenna or a cable access—a signal source may be stationary or mobile 
           4612 : A camera operator 
           4614 : A camera 
           4616 : A transmitter coupled to an antenna or cable access 
           4620 : Transmission medium 
           4630 : A receiver and decompression module with multiple output channels at a broadcasting station 
           4640 : Baseband signal, acquired from receiver  4630 , corresponding to a respective signal source  4610   
           4650 : One of multiple display devices 
           4660 : A content-selection unit for selecting one of baseband signals fed to the display devices  4650   
           4662 : An operator viewing the display screens  4650  to select a corresponding baseband signal  4640   
           4664 : Manually operated selector (switcher) for directing one of the baseband signals produced at the output of the receiver  4630  to a transmitter 
           4680 : Transmitter 
           4690 : Channels to broadcasting stations and/or a Universal Streaming Servers 
           4700 : Arrangement for producing operator-defined multimedia content for broadcasting 
           4710 : Panoramic multimedia signal source 
           4712 : Source signal (modulated carrier) 
           4714 : Source processing unit 
           4715 : Module for inserting in each frame data block a respective cyclic frame number 
           4716 : Source transmitter 
           4718 : Transmission medium 
           4720 : Acquisition module 
           4725 : An operator wearing a virtual-reality (VR) headset to view a panoramic display 
           4730 : Pure multimedia signal 
           4732 : Signal descriptor 
           4740 : Content selector for broadcasting 
           4750 : Virtual-reality headset (VR headset) extracting, from a pure multimedia signal  4730 , a filtered signal corresponding to operator&#39;s preferred angle of viewing 
           4752 : Control signals between the VR headset and a content-filter defining a view-region 
           4760 : Content filter 
           4764 : content-filtered signal 
           4770 : At least one panoramic-display device for received 4π video signal 
           4800 : First streaming and broadcasting system 
           4804 : Broadcasting subsystem 
           4808 : Streaming subsection 
           4810 : Repeater; basically an amplifier and physical (not content) signal processing 
           4820 : Streaming apparatus 
           4812 : Transmission medium 
           4862 : Compression module 
           4864 : Compressed content-filtered signal 
           4870 : Transmitter 
           4880 : Channel to broadcasting station 
           4890 : Channel to network  150   
           4940 : Receiver 
           4943 : Source multimedia signal 
           4946 : Selector of a pure-signal generator  4950   
           4947 : Output selector 
           4950 : Pure-signal generators 
           5090 : External display 
           5100 : Broadcasting subsystem of system  4800  for selective content broadcasting 
           5120 : Monitoring facility 
           5200 : Broadcasting subsystem for selective content broadcasting using an augmented content selector having a content buffer 
           5210 : Augmented content selector 
           5220 : Content-filter controller 
           5222 : Frame identifier 
           5230 : Content buffer (a circular buffer) 
           5240 : Distant content selector 
           5250 : Communication path to augmented content selector 
           5260 : Transmission medium 
           5270 : Control signals from distant content selector  5240  to augmented content selector  5210   
           5400 : Data exchange between the augmented content selector  5210  and the distant content selector  5240   
           5410 : Frame data block 
           5420 : Control data from distant content selector  5240   
           5430 : Frame period (for example 20 milliseconds for a frame rate of 50 frames per second) 
           5440 : Transfer delay of multimedia signals from the augmented content selector  5210  to the distant content selector  5240   
           5450 : Latency of the VR headset  4750   
           5460 : Transfer delay of control signals  5270  from the distant content selector  5240  to the augmented content selector  5210   
           5500 : Frame-data flow through content buffer  5630   
           5510 : Frame-data blocks held in content buffer  5230   
           5520 : Address of a frame data block in content buffer  5230   
           5600 : A second system for combined selective content broadcasting and streaming 
           5620 : Routing facility 
           5622 : Transmission channel from signal source  4710  to routing facility  5620   
           5624 : Transmission channel from routing facility  5620  to network  5630   
           5626 : Transmission channel from network  5630  to routing facility  5620   
           5628 : Transmission channel from routing facility  5620  to a broadcasting station  5680   
           5630 : Shared network (the Internet, for example) 
           5640 : Remote content controller 
           5644 : Channel from network  5630  to content controller 
           5646 : Channel from distant content selector to network  5630   
           5651 : Modulated carrier from routing facility  5620  directed to distant content selector  5640  through network  5630   
           5652 : Modulated carrier from routing facility  5520  directed to server  120  through a cloud computing network  5670   
           5670 : Cloud computing network 
           5680 : Broadcasting station (Television Station) 
           5710 : Repeater for carrier signal directed to server  120  and distant content selector  5240   
           5770 : Receiver 
           5810 : Frame-number extraction module 
           5812 : Frame-number insertion module 
           5820 : Refresh module 
           5925 : A bank of content filters  5932   
           5932 : Content filter 
           5940 : Baseband signal—output of a content filter  5932   
           6000 : Method of selective content broadcasting relevant to the system of  FIG. 51   
           6100 : Method of selective content broadcasting relevant to the system of  FIG. 59   
           6200 : Method of combined broadcasting and streaming relevant to the system of  FIG. 47 . 
           6210 : Process of receiving modulated carrier signal  4712  from panoramic multimedia source  4710   
           6212 : Process of acquiring a pure multimedia signal  4730  (acquisition module  4720 ) 
           6214 : Process of generating operator-defined content-filtered multimedia signal  4764   
           6220 : Process of transmitting content-filtered signals to a broadcasting facility and a Universal Streaming Server 
           6230 : Process of relaying modulated carrier signal  4712  to streaming subsystem 
           6240 : Process of acquiring pure multimedia signal  4730  at streaming subsystem 
           6242 : Process of sending the full content of the pure multimedia signal, at a reduced flow rate, to client devices accessing Universal Streaming Server 
           6244 : Process of receiving client-specific viewing preferences 
           6246 : Produce content-filtered signals according to viewers preferences 
           6248 : Process of retaining operator-defined and viewers-defined content-filtered signals for further use 
           6320 : Process of receiving a source signal (a modulated carrier signal)  4712  at content selector  4740   
           6330 : Process of acquiring a pure multimedia signal  4730  from the source signal 
           6340 : Process of displaying a multimedia signal (including a video-signal component) 
           6342 : Process of initializing a gaze position as a null position 
           6344 : Process of determining a current gaze position from an output of a virtual-reality headset 
           6346 : Process of determining a displacement of a current gaze position from a reference gaze position 
           6348 : Process of selecting a subsequent process (process  6350  or process  6370 ) according to value of gaze-position displacement 
           6350 : Process of updating a reference gaze position 
           6360 : Process of generating and storing view-region definition corresponding to a reference gaze position and a predefined contour around the reference gaze position 
           6370 : Process of extracting a content-filtered signal  4764  from a pure multimedia signal  4730   
           6372 : Process of compressing a content-filtered signal before broadcasting 
           6374 : Process of transmitting a content-filtered signal (compressed or otherwise) 
           6380 : Process of observing a subsequent gaze position and repeating process  6344  to  6374   
           6410 : Process of receiving a source signal (a modulated carrier signal)  4712  at distant content selector  5240   
           6420 : Process of initializing a gaze position as a null position 
           6430 : Process of acquiring a pure multimedia signal  4730  from the source signal  4712  at distant content selector  5240   
           6440 : Process of displaying a multimedia signal at distant content selector  5240   
           6450 : Processes performed at Refresh module  5820  collocated with distant content selector  5240  ( FIG. 58 ) 
           6452 : Process of determining a cyclic frame number 
           6454 : Process of determining a current gaze position from an output of a virtual-reality headset of the distant content selector  5240   
           6456 : Process of determining a displacement of a current gaze position  6454  from a reference gaze position 
           6458 : Process of selecting a subsequent process (process  6470  or process  6474 ) according to value of gaze-position displacement 
           6470 : Process of updating a reference gaze position 
           6472 : Process of forming a control message containing a frame identifier and a reference gaze position 
           6474 : Process of forming a control message containing a frame identifier and a Null gaze position 
           6478 : Process of transmitting the control message of process  6472  or  6474  to augmented content selector  5210   
           6500 : Processes performed at augmented content selector  5210   
           6510 : Process of receiving a new gaze position and a corresponding frame identifier from distant content selector  5240   
           6512 : Received frame identifier 
           6520 : Process of determining an address of a frame data block in content buffer  5230   
           6530 : Process of reading a frame data block  5232   
           6540 : Process of selecting process  6550  or process  6560   
           6550 : Process of generating and storing view-region definition based on new gaze position and a predefined region shape (contour) at augmented content selector  5210   
           6560 : Process of generating a content-filtered signal  4764  based on latest view-region definition when a control message includes a null gaze position indicating change, or an insignificant change, of gaze position 
           6562 : Process of compressing a content-filtered signal at a routing facility  5620  ( FIG. 57 ) supporting the augmented content selector  5210   
           6564 : Process of transmitting the compressed content-filtered signal from the routing facility 
           6580 : Process of receiving a subsequent content-selection data (new gaze position and frame identifier) from refresh module  5820  which is coupled to the distant content selector  5240   
       
     
       DETAILED DESCRIPTION 
       [0540]    A conventional streaming server performs multimedia signal adaptation and distribution to individual client devices. With panoramic multimedia-signals, a high-capacity path need be established between the multimedia source and the streaming server, and paths of adaptive capacities need be established between the streaming server and multiple client devices. 
         [0541]    The streaming server may acquire performance metrics of a connection between the streaming server and a client device and adjust the flow rate allocated to the connection according to the performance metrics. If the connection is allocated a guaranteed constant flow rate, for example through a dedicated link or reserved capacity of a network path, the performance metrics would depend on the value of the constant flow rate and the characteristics of the client device. If the connection is allocated a nominal flow rate, for example through shared links of a network, the performance metrics would depend on the value of the nominal flow rate, the fluctuation of the intensity of network data traffic from other data sources, and the characteristics of the client device. 
         [0542]    The streaming server may also be configured to process a signal received from a panoramic multimedia source to derive signals of partial content. The streaming server of the present invention may receive a signal from a source containing a full coverage panoramic video signal covering a solid angle of 4π steradians and derive a signal of partial coverage. With such capability, a person viewing a display of the video signal may select, using an input device, a specific partial coverage according to the person&#39;s viewing preference. The information content of the preferred video signal depends largely on the selected coverage. Thus, the performance metrics would depend on the value of the nominal flow rate, the fluctuation of the intensity of network data traffic from other data sources, the characteristics of the client device, and the selected information content. 
         [0543]    Instead of specifying a nominal flow rate, a viewer may specify a fidelity level and information content. The multimedia server may translate the fidelity level into a requisite flow rate. 
         [0544]    A streaming server providing both content selection and flow-rate adaptation to receiver and network conditions is herein referenced as a universal streaming server. 
         [0545]      FIG. 1  illustrates a streaming system  100  comprising a panoramic multimedia source  110  coupled to a universal streaming server  120  through a transmission medium  115 . Transmission medium  115  may be a dedicated medium, such as a fiber-optic link or a wireless link, or may be a switched path through a shared telecommunication network. The panoramic multimedia server may communicate with a plurality of client devices  180 , individually identified as  180 ( 0 ) to  180 ( m ), m&gt;1, through a network  150 . The panoramic multimedia source  110  comprises a full-coverage camera and may comprise a de-warping module and/or a compression module. A full-coverage camera, herein also called a 4π camera, produces a full-coverage video signal. A multimedia signal, herein referenced as a “source multimedia signal”, transmitted from the panoramic multimedia source  110  to universal streaming server  120  may contain a video signal in addition to signals of other forms such as an audio signal or a text signal. 
         [0546]      FIG. 2  illustrates a streaming system  200  comprising a number ν, ν≧1, of panoramic multimedia sources  110 , individually identified as  110 ( 0 ) to  110 (ν−1), and a number μ of universal streaming servers, μ≧1, individually identified as  120 ( 0 ) to  120 (μ−1) which may concurrently serve a number M, M&gt;1, of client devices of a plurality of client devices  180 . The universal streaming servers  120  may communicate with the panoramic multimedia sources  110  and the client devices through network  150 . Alternatively, the universal streaming servers  120  may communicate with the panoramic multimedia sources  110  through one shared network (not illustrated) but communicate with the client devices  180  through another network (not illustrated). 
         [0547]    A multimedia panoramic source  110  preferably employs a full-coverage panoramic camera, herein referenced as a 4π camera, providing view coverage of up to 4π steradians. An output signal of a 4π camera is herein referenced as a 4π video signal. A display of a 4π video signal of a captured scene on a flat screen may differ significantly from the actual scene due to inherent warping. To eliminate or significantly reduce the display distortion, an artificial offset distortion may be applied to the camera-produced signal so that the display closely resembles a captured scene. Numerous processes, called “de-warping”, for correcting the distorted video signal are known in the art. 
         [0548]    The de-warping process may be implemented at source, i.e., directly applied to a camera&#39;s output signal, or implemented at the universal streaming server  120 . 
         [0549]    The video signal at a source  110  may be sent directly to a universal streaming server  120  over a high-capacity communication path or compressed at source to produce a compressed signal, occupying a (much) reduced spectral band, which is sent to a universal streaming server  120  over a lower-capacity communication path to be decompressed at the universal streaming server. 
         [0550]      FIG. 3  illustrates four communication options between a multimedia panoramic source  110  and a server  120 . The multimedia panoramic source includes a 4π camera which produces a raw signal  312  and may include a de-warping module  330  and/or a source compression module  340 . The raw signal  312  need be de-warped before display or before further processing to condition the signal to specific recipients. 
         [0551]    Communication devices coupled to the source are not illustrated in  FIG. 3 . As illustrated in  FIG. 3 , a first source comprises the 4π camera, a second source comprises the 4π camera and a de-warping module  330 , a third source comprises the 4π camera and a source compression module  340 , and a fourth source comprises the 4π camera, a de-warping module  330 , and a source compression module  340 . 
         [0552]    According to one embodiment, the raw signal  312  may be sent to a server  120 A equipped with a de-warping module  320  which produces a corrected signal  322  which is further processed to produce recipient-specific signals. The corrected signal is considered a “pure video signal” which corresponds to the respective scene captured at source. 
         [0553]    According to another embodiment, the raw signal  312  may be processed at a de-warping module  330  coupled to the source  110  to produce a corrected signal (pure video signal)  322  which is sent to a server  120 B for further processing to produce recipient-specific signals. 
         [0554]    According to a further embodiment, the raw signal  312  may be processed at a source compression module  340  coupled to the source  110  to produce a compressed signal  342  which is sent to a server  120 C. Server  120 C is equipped with a server decompression module  350  which decompresses compressed signal  342  to produce a decompressed signal  352  to be processed at de-warping module  320  to produce a rectified signal  324 . The rectified signal is a “pure video signal” as defined above. With a lossless compression process and an ideal decompression process, the decompressed signal  352  would be a replica of raw signal  312 . With ideal de-warping, rectified signal  324  would be a faithful representation of the captured scenery. 
         [0555]    According to a further embodiment, the raw signal  312  may be processed at a de-warping module  330  coupled to the source  110  to produce a corrected signal  322  which is processed at a source compression module  340  to produce a compact signal  343  to be sent to a server  120 D. Server  120 D is equipped with a server decompression module  350  which decompresses compact signal  343  to produce a rectified signal  324 . With an ideal de-warping module  330 , a lossless compression process, and an ideal decompression process, the rectified signal would be a faithful representation of the captured scenery, i.e., a “pure video signal”. 
         [0556]    Thus, the present invention provides a method of video-signal streaming implemented at a server which comprises multiple physical processors and associated memory devices. The server is devised to acquire a panoramic multimedia signal comprising a video signal from:
       (1) a signal source comprising a panoramic camera;   (2) a signal source comprising a panoramic camera and a de-warping module;   (3) a signal source comprising a panoramic camera and a compression module; or   (4) a signal source comprising a panoramic camera, a de-warping module, and a compression module.       
 
         [0561]    The method comprises a process of accessing a panoramic multimedia source to acquire a video signal. If the acquired video signal is uncompressed and has not been de-warped at source, the video signal is de-warped at the server to produce a “pure video signal” which may be displayed on a screen or further processed for distribution to client devices. If the acquired video signal is uncompressed and has been de-warped at source, the video signal constitutes a “pure video signal”. If the acquired video signal has been compressed but not de-warped at source, the video signal is decompressed then de-warped at the server to produce a “pure video signal. If the acquired video signal has been de-warped and compressed at source, the video signal is decompressed at the server to produce a “pure video signal. 
         [0562]      FIG. 4  illustrates communication paths corresponding to the communication options of  FIG. 3 . 
         [0563]    According to the first communication option, a panoramic signal produced at a 4π camera  310 , of panoramic multimedia source module  110 A, is transmitted over a high-capacity path  480  to server  120 A which comprises a de-warping module  320  and a signal-editing module  460  which performs both content filtering and signal adaptation to client devices under flow-rate constraints. Server  120 A comprises at least one processor (not illustrated in  FIG. 4 ) and memory devices storing processor executable instructions (software instructions) organized as the de-warping module  320  and the signal-editing module  460 . The software instructions of de-warping module  320  are executed to cause the at least one processor to use the received signal and known characteristics of the camera to produce a de-warped corrected signal  322  which may be directly presented to a flat display device or further processed in signal-editing module  460 . Signal-editing module  460  may perform content filtering processes to produce selective partial-coverage streams, each tailored to a respective recipient. Signal-editing module  460  may also produce full-coverage streams each tailored to a respective recipient. 
         [0564]    According to the second communication option, source module  110 B comprises a 4π camera  310 , a de-warping module  330 , and a processor (not illustrated) applying software instructions of de-warping module  330  to the output signal (raw signal  312 ) of the 4π camera. The resulting de-warped signal is sent over a high-capacity communication path  480  to server  120 B which comprises a signal-editing module  460  as in the first implementation option above. 
         [0565]    According to the third communication option, source module  110 C comprises a 4π camera  310 , a source compression module  340 , and a processor (not illustrated) applying software instructions of source compression module  340  to the output signal (raw signal  312 ) of the 4π camera. The resulting compressed signal  342  is sent over a communication path  490 , of a lower-capacity compared to communication path  480 , to server  120 C which comprises a server decompression module  350 , a de-warping module  320 , and signal-editing module  460 . Server  120 C comprises at least one processor (not illustrated) which implements software instructions of server decompression module  350  to produce decompressed signal  352 . The at least one processor also implements software instructions of the de-warping module  320  to produce a rectified signal  324 . Signal-editing module  460  performs content filtering of rectified signal  324  to produce selective partial-coverage streams, each tailored to a respective recipient. Signal-editing module  460  may also produce full-coverage streams each tailored to a respective recipient. 
         [0566]    According to the fourth communication option, source module  110 D comprises a 4π camera  310 , a de-warping module  330 , a source compression module  340 , and a processor (not illustrated) applying software instructions of the de-warping module  330  to the output signal (raw signal  312 ) of the 4π camera to produce a corrected signal  322 . The processor applies the software instructions of the source compression module  340  to produce a compact signal  343 . The compact signal  343  is sent over a lower-capacity communication path  490  to server  120 D which comprises a server decompression module  350  and the signal-editing module  460 . Server  120 D comprises at least one processor (not illustrated) which implements software instructions of server decompression module  350  to reconstruct the corrected signal  322 . As in the previous communication options, signal-editing module  460  performs content filtering of rectified signal  324  to produce selective partial-coverage streams, each tailored to a respective recipient. Signal-editing module  460  may also produce full-coverage streams each tailored to a respective recipient. 
         [0567]    With the first or second communication option, a corrected video signal  322  is presented to a signal-editing module  460 . With the third or fourth communication options, a rectified video signal  324  is presented to a signal-editing module  460 . Each of the corrected video signal  322  and the rectified video signal  324  is considered a pure video signal corresponding to a respective scene captured at source. 
         [0568]      FIG. 5  illustrates components of an end-to-end path  500  corresponding to the first communication option of the communication options of  FIG. 3 . Source  110 A produces (baseband) raw signal  312  which is transmitted over high-capacity path  480  to server  120 A. The high-capacity path  480  comprises a source transmitter  520  collocated with source  110 A, transmission medium  115 , and server receiver  540  collocated with server  120 A. Receiver  540  demodulates modulated carrier signal  528  received through transmission medium  115  to acquire a replica  542  of the raw signal  312 . Server  120 A comprises a memory device storing software instructions constituting de-warping module  320  and a memory device storing software instructions constituting signal-editing module  460 . Server  120 A also comprises client-devices interfaces  560  which include server transmitters. Output signals  585  of server  120 A are communicated through network  150  to respective client devices  180 . 
         [0569]      FIG. 6  illustrates components of an end-to-end path  600  corresponding to the second communication option of the communication options of  FIG. 3 . Source  110 B comprises 4π camera  310  and a memory device storing software instructions constituting de-warping module  330  which cause a processor (not illustrated) to produce corrected signal  322 . Corrected signal  322  is transmitted over high-capacity path  480  to server  120 B. The high-capacity path  480  comprises a source transmitter  520  collocated with source  110 B, transmission medium  115 , and server receiver  540  collocated with server  120 B. Receiver  540  demodulates modulated carrier signal  628  received through transmission medium  115  to acquire a replica  642  of the corrected signal  322 . Server  120 B comprises a memory device storing software instructions constituting signal-editing module  460 . Server  120 B also comprises client-devices interfaces  560  which include server transmitters. Output signals  685  of server  120 B are communicated through network  150  to respective client devices  180 . 
         [0570]      FIG. 7  illustrates components of an end-to-end path  700  corresponding to the third communication option of the communication options of  FIG. 3 . Source  110 C comprises 4π camera  310 , which produces (baseband) raw signal  312 , and a memory device storing software instructions constituting source compression module  340 . Source compression module  340  compresses raw signal  312  into compressed signal  342  which is transmitted over path  490  to server  120 C. Path  490  comprises a source transmitter  720  collocated with source  110 C, transmission medium  115 , and server receiver  740  collocated with server  120 C. Receiver  740  demodulates modulated carrier signal  728  received through transmission medium  115  to acquire a replica  742  of compressed signal  342 . Server  120 C comprises a memory device storing software instructions constituting server decompression module  350 , a memory device storing software instructions constituting de-warping module  320 , and a memory device storing software instructions constituting signal-editing module  460 . Server  120 C also comprises client-devices interfaces  560  which include server transmitters. Output signals  785  of server  120 C are communicated through network  150  to respective client devices  180 . 
         [0571]      FIG. 8  illustrates components of an end-to-end path  800  corresponding to the fourth communication option of the communication options of  FIG. 3 . Source  110 D comprises 4π camera  310 , a memory device storing software instructions constituting de-warping module  330  which cause a processor (not illustrated) to produce corrected signal  322 , and a memory device storing software instructions constituting source compression module  340  which cause a processor (not illustrated) to produce compact signal  343 . Compact signal  343  is transmitted over path  490  to server  120 D. Path  490  comprises a source transmitter  720  collocated with source  110 D, transmission medium  115 , and server receiver  740  collocated with server  120 C. Receiver  740  demodulates modulated carrier signal  828  received through transmission medium  115  to acquire a replica  842  of compact signal  343 . Server  120 D comprises a memory device storing software instructions constituting server decompression module  350 , and a memory device storing software instructions constituting signal-editing module  460 . Server  120 D also comprises client-devices interfaces  560  which include server transmitters. Output signals  885  of server  120 D are communicated through network  150  to respective client devices  180 . 
         [0572]      FIG. 9  illustrates multimedia signals and control signals at input and output of a universal streaming server  120 . The server  120  receives from a source  110  a multimedia signal including a video signal  900  which may be a raw signal  312 , a corrected signal  322 , a compressed signal  342 , or a compact signal  343 . A video signal received at a server from a source  110  is herein referenced as a “source video signal”. 
         [0573]    The server  120  may receive multimedia signals from different panoramic multimedia sources  110  as illustrated in  FIG. 2 . The server may, therefore receive a raw video signal  312  from a first source  110 , a corrected video signal  322  from a second source  110 , a compressed signal  342  from a third source, and/or a compact signal  343  from a fourth source. Preferably, then, the server may be equipped with a de-warping module  320  and a server decompression module  350  to be able to engage with sources  110  of different types and produce a pure video signal  420  which may be a corrected video signal  322  or a rectified video signal  324 . 
         [0574]    The server  120  receives upstream control signals  935  from client devices  180  and control signals  905  from sources  110 . The server transmits downstream control signals  945  to client devices and may transmit control signals  925  to the source  110 . Regardless of the source type, the kernel of the server, which is signal-editing module  460 , processes the pure video signal  420  based on control signals  935  and  905 . 
         [0575]    The upstream control signals  935  may include clients&#39; characterizing data and clients&#39; requests. The downstream control signals  945  may include responses to clients&#39; requests. The downstream control signals  945  may also include software modules to be installed at client devices  180  to enable each subtending client device to communicate preferred viewing regions to the server. Control signals  905  may include data relevant to source characteristics and operations already performed at source, such as de-warping and/or data compression. Control signals  925  may include information characterizing the server. 
         [0576]    The signal-editing module  460  of the server  120  produces edited multimedia signals  940 , each edited multimedia signal being individually conditioned to: viewing preference of a respective client; capability of a respective client&#39;s device; and condition of a network path from the server to the respective client&#39;s device. The server  120  transmits to client devices the edited multimedia signals  940 . 
         [0577]      FIG. 10  illustrates components  1000  of an exemplary server  120 . The server comprises at least one processor (not illustrated) and multiple memory devices storing processor executable instructions organized into a number of modules including a server-network interface  1010 , a source control-data module  1022 , a source signal-processing module  1024 , a client control-data module  1026 , and a set of client-specific adaptation modules  1060 . The server-network interface  1010  is coupled to at least one dual link  1008  to at least one network which carries all signals  1005  originating from, or destined to, signal sources and client devices. The server-network interface  1010  comprises a server receiver  540  ( FIG. 5  and  FIG. 6 ) or  740  ( FIG. 7  and  FIG. 8 ) which demodulates a modulated carrier (optical carrier or wireless microwave carrier) to detect the baseband source video signal  900  (raw signal  312 , corrected signal  322 , compressed signal  342 , or compact signal  343 ) sent from a source  110  ( 110 A,  110 B,  110 C, or  110 D). A dual link of the at least one dual link  1008  carries: control data to and from at least one source  110  and a plurality of client devices; source multimedia signals; and edited multimedia signals directed to the plurality of client devices. 
         [0578]    The source video-signal-processing module  1024  may be equipped with a de-warping module  320  and/or a server decompression module  350  to produce a pure video signal  420  which may be a corrected video signal  322  or a rectified video signal  324 . 
         [0579]    Server-network interface  1010  directs source video signals  900  to source video-signal-processing module  1024  and control signals  905  to source-control data processing module  1022 . Source video-signal-processing module  1024  performs processes of:
       (1) video-signal de-warping (module  320 ,  FIG. 5 );   (2) video-signal decompression (module  350 ) and de-warping (module  320 ,  FIG. 7 ); or   (3) video-signal decompression (module  350 ,  FIG. 8 ).       
 
         [0583]    Modules  1022  and  1024  are communicatively coupled as indicated in  FIG. 10 . Outputs of module  1022  may influence processes of module  1024 . Module  1024  may generate control data  925  directed to a source  110  to be communicated through module  1022  and server-network interface  1010 . 
         [0584]    Module  1024  directs pure video signals  420  to a number m, m&gt;1, of client-specific adaptation modules  1060 , individually identified as  1060 ( 0 ) to  1060 ( m− 1). Client-specific adaptation modules  1060  preferably employ independent hardware processors. Each client-specific adaptation module  1060  comprises a memory device storing instructions which cause a respective processor to perform requisite transcoding functions. 
         [0585]    The signals received from client devices comprises upstream control signal  935 . The data directed to client devices comprises control signals  945  and edited multimedia signals  940 . Upstream control signals  935  are extracted at server-network interface  1010  and directed to clients&#39; control-data module  1026 . The client-specific adaptation modules  1060  access upstream control data  935  through a client control bus  1061 , where client-specific control signals are held in buffers  1062 , or through other means known in the art. Downstream control data generated at the client-specific adaptation modules  1060  are distributed to respective client devices  180  through client control bus  1061 , client control-data module  1026 , server-network interface  1010 , and the at least one dual link  1008 . The edited client-specific multimedia signals  940  are combined (combiner  1090 ) and the aggregate stream  1095  is distributed to respective client devices  180  through server-network interface  1010 , the at least one dual link  1008 , and at least one network. 
         [0586]      FIG. 11  details a client-specific adaptation module  1060 . The module comprises at least one memory device storing processor-executable instructions which, when executed, cause at least one processor to perform processes of content filtering of a video signal to extract a signal corresponding to a selected view region and transcoding the content-filtered video signal to be compatible with the capability of a target client device  180 . The video signal may be compressed under the constraint of a permissible flow rate which may be a representative value of a time-varying flow rate. 
         [0587]    A client-specific adaptation module  1060  comprises a content-filtering module (content filter)  1120 , a transcoding module  1140  for signal adaptation to client-device capability, and a server compression module  1160  for producing a video signal having a flow rate within a permissible flow rate. 
         [0588]    In accordance with one embodiment, content filter  1120  processes the pure video signal  420  to extract signal portions which correspond to a specified view region yielding a content-filtered signal  1122 . The mean flow rate of content-filtered signal  1122  would be lower than the mean flow rate of pure video signal  420 . If content-filtered signal  1122  is compatible with the capability of a target client device and has a flow rate satisfying a respective permissible value, the signal may be transmitted to the target client device. Otherwise, transcoding module  1140  is applied to transcode content-filtered signal  1122  to be compatible with characteristics of the target client device such as an upper bound of a frame rate and a frame resolution upper bound. If the resulting transcoded content-filtered signal  1142  has a flow rate not exceeding the permissible value, signal  1142  may be transmitted to the target client device. Otherwise, server compression module  1160  may be applied to compress signal  1142  according to the permissible flow rate yielding signal  940  which is a compressed, transcoded, and content-filtered signal. 
         [0589]    In accordance with another embodiment, transcoding module  1140  may be applied to transcode pure video signal  420  to yield a transcoded signal  1152  compatible with the capability of the target client device. Content filter  1120  processes signal  1152  to extract signal portions which correspond to a specified view region yielding a content-filtered transcoded signal  1132 . The mean flow rate of content-filtered transcoded signal  1132  would be lower than the mean flow rate of pure video signal  420 . If signal  1132  has a flow rate satisfying a permissible value, the signal may be transmitted to the target client device. Otherwise, server compression module  1160  may be applied to compress signal  1132  according to the permissible flow rate yielding signal  940  which is now a compressed, transcoded, and content-filtered signal. 
         [0590]    An uncompressed or decompressed video signal which is de-warped at the source or at the server is a pure video signal. To provide service to a specific client device, the pure video signal is transcoded to produce a transcoded signal compatible with the client device. The pure video signal corresponds to an attainable coverage of a solid angle of up to 4π Steradians and is likely to have a large flow rate (bit rate), of multi Gb/s for example, which may exceed the available capacity of a path from the server to the client device. The transcoded signal may also have a flow rate that exceeds the capacity of the path. Thus, the transcoded signal may be compressed to yield a flow rate not exceeding the capacity of the path. 
         [0591]    The compressed transcoded signal is transmitted to the client device to be decompressed and displayed at the client device. A viewer at the client device may then identify a preferred view region and send descriptors of the preferred view region to the server. The signal may then be content-filtered to retain only portions of the signal that correspond to the preferred view region. The content-filtered signal may be compressed then transmitted to the client device. 
         [0592]    When the server accesses the panoramic multimedia source  110 , the panoramic multimedia source provides a multimedia signal comprising the video signal as well control data including indications of any signal processing applied to the video signal, such as de-warping and compression. The acquired video signal is a panoramic video signal which may be produced by a single camera or produced by combining video signals from multiple cameras. 
         [0593]    To enable a user of the client device to communicate identifiers of a preferred view region, the server sends to the client device a software module devised for this purpose. The server may be partially or entirely installed within a shared cloud-computing network where the physical processors and associated memory devices are allocated as the need arises. 
         [0594]      FIG. 12  illustrates temporal variation of the flow rate (bit rate) of a compressed video signal. As well known in the art, a number of descriptors may be used to characterize a variable-flow-rate signal (also called a variable-bit-rate) such as a mean value  1220  and a peak value  1230  of the flow rate, and a parameter representing signal-burst duration. The descriptors and the capacity of a shared network path designated to transport the variable-bit-rate signal may be used to determine an effective flow rate (effective bit rate)  1225  which need be allocated in a communication path to transport the signal. Server compression module  1160  would be devised to ensure that the effective flow rate (effective bit rate) does not exceed a permissible flow rate of a (purchased) network connection. 
         [0595]      FIG. 13  illustrates modules  1300  for generating time-limited video signals of reduced flow rates yet suitable for exhibiting panoramic full spatial coverage to enable a client receiving a time-limited video signal to select a preferred partial-coverage view. 
         [0596]    Frame-sampling module  1320  comprises processor executable instructions which cause a processor to sample a pure video signal  420 , or a transcoded video signal derived from the pure video signal, during distant frame intervals to produce a frame-sampled video signal  1322  corresponding to full spatial-coverage sampled images. Frame-sampled video signal  1322  is not compressed and has a constant flow rate not exceeding a permissible flow rate. The frame-sampled video signal  1322  may be displayed at a client device. 
         [0597]    Pure video signal  420  may be a corrected signal  322  or a rectified signal  324  ( FIG. 3 ). The inter-frame sampling period is selected so that the (constant) flow rate of the stream of sampled portions of a pure video signal  420  does not exceed a permissible flow rate. For example, if the data flow rate of a pure video signal  420  is 1 Gb/s and the permissible flow rate is 5 Mb/s, then frame-sampling module  1320  would select one frame out of each set of 200 successive frames. A specific client device  180  receiving the sampled frames would then display each frame repeatedly during a period of 200 frame intervals (5 seconds at a frame rate of 40 frames per second). The server  120  starts to send a respective edited multimedia signal  940  ( FIG. 9 ) and terminates transmitting frame samples after the server receives an indication of a preferred view region from the specific client device. 
         [0598]    The server  120  may send view-selection software instructions to each client device to facilitate client&#39;s selection of a preferred view region. The software instructions may be sent along the same path carrying downstream control data  945  ( FIG. 9 ). 
         [0599]    Thus, server  120  may employ a frame-sampling module comprising processor executable instructions which cause a processor to sample a video signal during distant frame intervals to produce a frame-sampled video signal. The server further comprises a memory device storing software modules for distribution to the plurality of client devices to enable users of the client devices to communicate identifications of preferred viewing regions to the server. 
         [0600]    Spatial-temporal server compression module  1340  comprises processor executable instructions which cause a processor to compress pure video signal  420 , or a transcoded video signal derived from the pure video signal, to produce a compressed signal  1342  corresponding to full spatial-coverage images. Compressed signal  1342  would have a fluctuating flow rate as illustrated in  FIG. 12  and server compression module  1340  ensures that the effective flow rate (effective bit rate) does not exceed a permissible flow rate. 
         [0601]    A spatial-temporal compression module  1360 , similar to spatial-temporal server compression module  1340 , causes a processor to compress preselected content-filtered signals (partial coverage signals)  1362  derived from a pure video signal  420 . A succession of compressed content filtered signals  1364 , occupying successive time windows, is sent to a target client device. Each of compressed signals  1364  would have a fluctuating flow rate as illustrated in  FIG. 12  and compression module  1360  ensures that the effective flow rate (effective bit rate) of each compressed signal  1364  does not exceed a permissible flow rate. 
         [0602]      FIG. 14  illustrates a process of providing a content-filtered video signal to a client device. At an instant of time t 1 , a user of a specific client device  180  sends a message  1402  to a server  120  requesting viewing of a specific event. The message is received at the server  120  at time t 2 . Several view-selection methods may be devised to enable a user of the specific client device to communicate identifiers of a preferred view region to the server. 
         [0603]    In one view-selection method, the server sends a frame-sampled signal  1322 , which corresponds to selected full spatial-coverage panoramic images, at time t 3 . At time t 4 , the client device  180  starts to receive frame-sampled signal  1322  which is submitted to a display device after accumulating content of one frame. At time t 5 , the user of the specific client device sends a message  1404  providing parameters defining a selected view region. Message  1404  is received at the server at time t 6 . The server  120  formulates a respective content filtered video signal corresponding to the selected view region. The respective content filtered video signal may be compressed to produce a compressed content-filtered signal (partial-spatial-coverage signal)  1440 . The server terminates transmission of the frame-sampled signal  1322  at time t 7  and starts to send compressed content-filtered signal  1440  to the client device  180  at time t 9 . Signal  1440  is decompressed and displayed at the client device. The client device receives the last frame of frame-sampled signal  1322  before time t 8  and starts to receive compressed signal  1440  at time t 10 . Transmission of compressed signal  1440  ends at time t 11  and receiving the signal at the client device ends at time t 12 . 
         [0604]    In another view-selection method, the server generates a full-coverage video signal  1342  that is client-device compatible and compressed to a permissible flow rate as illustrated in  FIG. 13 . The server sends the signal  1342  at time t 3  and the client device  180  starts to receive the compressed signal at time t 4 . The compressed signal  1342  is decompressed at the client device and submitted to a display device. The sequence of events after time t 4  would be similar to the sequence of events corresponding to the case of frame-sampled video signal  1322 . 
         [0605]    In a further view-selection method, the server derives from pure video signal  420  several content-filtered video signals  1362  corresponding to preselected view regions as illustrated in  FIG. 13 . Each of the derived content-filtered video signals would be compatible with the capability of the client device and compressed to a permissible flow rate. A succession of compressed signals  1364  may be sent to the client device and a user of the client device may send a message to the server indicating a preferred one of the preselected view regions. 
         [0606]    Thus the present invention provides a method of signal streaming comprising editing content of the video signal to produce a set of content-filtered signals corresponding to a predefined set of view regions. Each content-filtered signal is transcoded to produce a set of transcoded signals compatible with a particular client device. Each of the transcoded signals is compressed to produce a set of compressed signals. The compressed signals are successively transmitted to the client device. Upon receiving from the particular client device an identifier of a specific compressed signal corresponding to a preferred view region, only the specific compressed signal is subsequently transmitted to the client device. 
         [0607]      FIG. 15  illustrates temporal bit-rate variation (flow rate variation) of video signals transmitted from a server  120  to a client device  180 . The bit rate of frame-sampled signal  1322  is constant and set at a value not exceeding a predefined permissible bit rate. The bit rate of compressed content-filtered signal  1440  is time variable. As well known in the art, a variable bit rate may be characterized by parameters such as a mean bit rate, a peak bit rate, and a mean data-burst length. The parameters, together with the capacity of a respective network path, may be used to determine an “effective bit rate”  1525  which is larger than the mean bit rate  1520 . The formulation of the frame-sampled signal  1322  ensures that the resulting constant bit rate does not exceed the predefined permissible bit rate (which may be based on a service-level agreement or network constraints). The compression process at the server  120  is devised to ensure that the effective bit rate of the compressed signal  1440  does not exceed the permissible bit rate. 
         [0608]    To provide service to a set client devices of a specific client device, the pure video signal may be transcoded to produce a transcoded signal compatible with the client-device type. The transcoded signal may have a flow rate that exceeds the capacity of some of the paths from the server to the client devices. To provide the client devices with a full-coverage (attainable-coverage) view, a signal sample of a reduced flow rate is generated and multicast to client devices. A signal sample may be a frame-sampled transcoded signal or a compressed transcoded signal. Upon receiving from a particular client device an identifier of a respective preferred view region, the transcoded signal is content-filtered to produce a client-specific signal corresponding to the respective preferred view region. The client-specific signal is compressed and transmitted to the particular client device. 
       Signal-Editing Module 
       [0609]      FIG. 16  illustrates basic components  1600  of signal-editing module  460  ( FIG. 4  to  FIG. 8 ) of a server  120 . In a first stage  1610 , the pure video signal  420  is processed to produce a number K, K≧1, of content-filtered signals  1612 . In a second stage  1620 , each content-filtered signal  1612  is adapted to a respective client device or a group of client devices  180 . Each content-filtered signal is directed to a respective signal-processing unit  1630  to produce a respective conditioned signal  1650  satisfying a number of conditions including upper bounds of frame-rate, resolution, and flow rate (bit rate). A conditioned signal  1650  may be suitable to multicast to a number of client devices. The content-filtered signals  1612  are individually identified as  1612 ( 0 ) to  1612 (K−1). The signal-processing units  1630  are individually identified as  1630 ( 0 ) to  1630 (K−1). The conditioned signals  1650  are individually identified as  1650 ( 0 ) to  1650 (K−1). 
         [0610]      FIG. 17  illustrates a content-filtering stage  1610  comprising K content filters  1120 , individually identified as  1120 ( 0 ) to  1120 (K−1), for concurrent generation of different partial-content signals from a full-content signal. A full-content signal  900  received through server-network interface  1710  may be decompressed and/or de-warped (modules  1725 ) to produce a pure video signal  420  which is routed to inputs of all content filters  1120 . Parameters identifying requested contents are distributed to control inputs  1720  of the content filters  1120 . 
         [0611]    Each content filter  1120  is devised to cause a physical processor (not illustrated) to extract portions of pure video signal  420  which corresponds to a specified view region. The pure video signal  420  is submitted to each content filter  1120  which is activated to produce a corresponding content-filtered signal  1612 . A particular content-filtered signal  1612  may be multicast to a number of clients that have indicated preference of the view region corresponding to the particular content-filtered signal. However, the client devices may have different characteristics, the capacities of network paths to the client devices may differ, and the permissible flow rates to the client devices may differ due differing network-path capacities and time-varying traffic loads at the client devices. Thus, content-filtered signals  1612  are processed in the second stage  1620  for adaptation to client devices and network-paths. 
         [0612]      FIG. 18  illustrates a signal-processing unit  1630 , of the second stage  1620  of the signal-editing module  460 , comprising a transcoding module  1840  for signal adaptation to client-device types and modules  1860  for signal flow-rate adaptation to conform to permissible flow-rates. A transcoding module  1840  may adapt a video signal to have a frame rate and resolution within the capability of a respective client device. With N types of active client devices, N≧1, a transcoding module  1840  produces N signals  1842 , individually identified as  1842 ( 0 ) to  1842 (N−1), each adapted to a respective device type. A module  1860  may further reduce the flow rate of a signal if the flow rate exceeds a permissible value. Each module  1860 ( j ), 0≦j&lt;N, comprises a buffer  1861  for holding a data block of a respective signal  1842  and a memory device  1862  storing processor-executable instruction for flow-rate adaptation. 
         [0613]      FIG. 19  illustrates a complete structure  1900  of the signal-editing module  460 . The content filtering stage  1610  comprises K content filters  1120  as illustrated in  FIG. 17 . Each content-filtered signal  1612  is submitted to a transcoding module  1840  to adapt the signal to a respective client-device type. A transcoding module  1840  comprises a buffer  1922  for holding a data block of a content-filtered signal  1612  and a memory device  1923  storing processor executable instructions which cause a processor to modify the frame rate and/or resolution to be compatible with the capability of a client-receiver. Each output signals  1842  of a transcoding module  1840  may be further processed at a flow-rate adaptation module  1860 . 
         [0614]    As illustrated in  FIG. 17 , K content filters  1120 , individually identified as  1120 ( 0 ) to  1120 (K−1), K&gt;1, may be activated simultaneously to extract different content-filtered signals  1612 ( 0 ) to  1612 (K−1) each further processed at a respective signal-processing unit  1630  to produce a signal  1650  suitable for display at a respective client device or a set of client devices. As illustrated in  FIG. 18 , a content-filtered signal  1612  is transcoded to be compatible with a target client device  180  and further adapted to a flow rate not exceeding a permissible upper bound. 
         [0615]      FIG. 20  illustrates processes  2000  of video signal editing for a target client device  180 . Control signals  935  may provide traffic-performance measurements  2014 , a nominal frame rate and frame resolution  2016 , and identifiers  2012  of a preferred view region. A pure video signal  420  is directed to a content filter  1120 ( j ) to extract content of pure video signal  420  that corresponds to a view region j identified by a user of the target client device. Flow-rate computation module  2040  is activated to determine a permissible flow rate Φ as well as a frame rate and frame resolution, compatible with the target client device  180 , to be used in transcoding module  1840 ( j ). Transcoding module  1840 ( j ) is activated to adapt the extracted content-filtered signal  1612 ( j ) to the frame rate and frame resolution determined by flow-rate computation module  2040 . Server compression module  2030  produces an edited video signal  940  ( FIG. 9 ) which corresponds to an identified view region and is adapted to the capability of the target client device  180  and the capability of the network path from the server  120  to the target client device  180 . Transmitter  2050  sends a signal  2052  to the target client device. Signal  2052  comprises video signal  940  together with accompanying multimedia signals (such as audio signals and/or text) and control signals. Signal  2052  is routed to the target client device along a network path  2060 . 
         [0616]      FIG. 21  details flow-rate computation module  2040 . Starting with a nominal frame rate and nominal frame resolution of the target client device  180 , which may be stored at the server or included in control signals  935  received from the target client, process  2110  determines the requisite flow rate R at the display device of the target client device  180  as a direct multiplication of the frame rate, the number of pixels per frame, and the number of bits per pixel. Independently, process  2120  determines a permissible flow rate Φ (reference  2122 ) between the server and the target client device based on measurements of traffic performance along the network path  2060  and the occupancy of a receiving buffer at the client device. The traffic-performance measurements include a data-loss indicator (if any) and delay jitter. The traffic-performance measurements are determined using techniques well known in the art. Determining the permissible flow rate based on measured traffic performance may be based on empirical formulae or based on a parameterized analytical model. 
         [0617]    Process  2140  determines whether the compression ratio (determined in process  2130 ) of the requisite flow rate R at the display device of the target client server to the permissible flow rate Φ along the network path  2060  is suitable for server compression module  2030 . If the flow rate R is to be reduced to satisfy a compression-ratio limit, process  2150  may determine a revised frame rate and/or a revised resolution  2152  to be communicated to transcoding module  1840  ( FIG. 20 ). The permissible flow rate Φ may be communicated to server compression module  2030 . 
         [0618]      FIG. 22  illustrates components of a client device  180 . A memory device  2210  stores client-device characterizing data, such as upper bounds of a frame rate and frame resolution of a display device. A memory device  2220  stores software instructions for interacting with specific servers  120 . The instructions may include software modules to enable a user of a client device to communicate identifications of preferred viewing regions to the server. The software instructions may be installed by a user of a client device or sent from a server  120  together with the downstream control signals  945  ( FIG. 9 ). A client transmitter  2230  transmits all control data from the client device to respective servers  120 . A client receiver  2240  receives all signals from server(s)  120  including edited video signal  940  (which may be compressed), other multimedia data (audio signals and text), and control signals  945 . An interface  2242  directs control signals  945  to processor  2250  and edited video signal  940 , together with accompanying audio signals and text, to a memory device  2260  which buffers data blocks of incoming multimedia data comprising the video signal  940 , audio data, and text. If the incoming multimedia data is not compressed, the data may be presented to the display device  2290 . Otherwise, client decompression module  2270  decompresses the compressed data block buffered in memory device  2260  to produce display data to be held in memory device  2280  coupled to the display device  2290 . Notably, a data block corresponding to one frame of a full-coverage frame-sampled signal  1322  ( FIG. 13 ,  FIG. 14 ) may be displayed numerous times before dequeueing from memory device  2280 . 
         [0619]      FIG. 23  illustrates communication paths between a universal streaming server  120  and two panoramic multimedia sources  110 - 0  and  110 - 1  through network  150 . A multimedia source  110  comprises a panoramic camera  310  (e.g., a 4π camera), and may include a de-warping module  330  and/or a source compression module  340  as illustrated in  FIGS. 3 to 8 . Although only two panoramic multimedia sources  110  are illustrated, it should be understood that the universal streaming server  120  may simultaneously connect to more multimedia sources  110  as illustrated in  FIG. 2 . In a preferred implementation, the universal streaming server is cloud-embedded so that the network connectivity and processing capacity of the universal streaming server may be selected to suit varying activity levels. A source multimedia signal from a panoramic multimedia source  110  is transmitted to the universal streaming server  120  through a network path  480 / 490  ( FIG. 4 ) of an appropriate transmission capacity. The source multimedia signal includes a source video signal  900 . 
         [0620]    With an ideal network path  480 / 490 , the received multimedia signal at the universal streaming server  120  would be a delayed replica of the transmitted video signal. The network path  480 / 490 , however, may traverse a data router at source, a data router at destination, and possibly one or more intermediate data routers. Thus, the received multimedia signal may be subject to noise, delay jitter, and possibly partial signal loss. With signal filtering at the server  120  and flow-rate control, the content of the received multimedia signal would be a close replica of the content of the transmitted multimedia signal. 
         [0621]    The source video signal  900  may be a “raw” video signal  312  produced by a panoramic camera, a corrected video signal  322 , a compressed video signal  342 , or a compact video signal  343  as illustrated in  FIG. 3 . A corrected video signal  322  is produced from the raw video signal using de-warping module  330 . A compressed video signal  342  is produced from the raw signal  312 , using source compression module  340  ( FIG. 3 ), according to one of standardized compression methods or a proprietary compression method. A compact video signal  343  is produced from a corrected video signal  322  using a source compression module  340 . The raw video signal may be produced by a single panoramic camera or multiple cameras. 
         [0622]    The universal streaming server  120  may send control signals  925  ( FIG. 9 ) to the panoramic multimedia source  110  through a network path  2314 , which would be of a (much) lower transmission capacity in comparison with the payload path  480 / 490 . 
         [0623]      FIG. 24  illustrates a network  150  supporting a universal streaming server  120 , a signal source  110  providing panoramic multimedia signals, and a plurality of client devices  180 . Although only one signal source is illustrated, it should be understood that the universal streaming server  120  may simultaneously connect to multiple signal sources as illustrated in  FIG. 2 . Communication paths are established between the universal streaming server  120  and a plurality of heterogeneous client devices  180 . The universal streaming server  120  sends edited multimedia signals  940  ( FIG. 9 ) to the client devices through network paths  2412 . The universal streaming server  120  receives control data  935  from individual client devices  180  through control paths (not illustrated) within network  150 . The control data  935  may include requests for service and selection of view regions. 
         [0624]    A source multimedia signal from the source  110  is transmitted to the server  120  through a payload network path  480 / 490  of sufficiently high capacity to support high-flow rate. The multimedia signal includes a source video signal  900  ( FIG. 3, 312, 322, 342 , or  343 ). Control signals from the server  120  to the signal source  110  are transmitted over a control path which would be of a much lower capacity in comparison with the payload network path  480 / 490 . A video signal component  900  of the source multimedia signal may be an original uncompressed video signal produced by a panoramic camera or a compressed video signal produced from the original video signal according to one of standardized compression methods or a proprietary compression method. The original video signal may be produced by a single panoramic camera or multiple cameras. 
         [0625]    With an ideal network path, the received video signal at the server  120  would be a delayed replica of the transmitted video signal. The network path, however, may traverse a data router at source, a data router at destination, and possibly one or more intermediate data routers. Thus, the received multimedia signal may be subject to noise, delay jitter, and possibly partial signal loss. The universal streaming server  120  receives commands from individual client devices  180 . The commands may include requests for service, selection of viewing patterns, etc. 
         [0626]    The video signals, individually or collectively referenced as  940 , from the universal streaming server to client devices  180  are individually adapted to capabilities of respective client devices  180 , available capacities (“bandwidths”) of network paths, and clients&#39; preferences. Control data from individual client devices to the universal streaming server are collectively referenced as  935  ( FIG. 9 ). The universal streaming server  120  may be implemented using hardware processing units and memory devices allocated within a shared cloud computing network. Alternatively, selected processes may be implemented in a computing facility outside the cloud. 
         [0627]      FIG. 25  illustrates a path  480 / 490  carrying multimedia signals from a source  110  to a server  120  and a dual control path  2512  carrying control signals  905  from the source  110  to the server  120  and control signals  925  from the server  120  to the source  110 . Downstream network path  2525  carries multimedia signals from the server  120  to a client  180 . Dual control path  2526  carries downstream control signals to a client device  180  and upstream control signals  935  from the client device  180  to the server  120 . An automaton  2545  associated with a client device  180  may send commands to the universal streaming server. The automaton would normally be a human observer. However, in some applications, a monitor with artificial-intelligence capability may be envisaged. 
         [0628]    Client-specific multimedia signals  940  adapted from a panoramic multimedia signal  900  generated at the multimedia source  110  may be multicast to the plurality of heterogeneous client devices  180 . The multimedia signals  940  are individually adapted to capabilities of respective client devices, available capacities (“bandwidths”) of network paths, and clients&#39; preferences. 
         [0629]      FIG. 26  illustrates a modular structure of the universal streaming server  120  comprising at least one hardware processor  2610 . A server-source interface  2651  controls communication with the multimedia source  110 . A source-characterization module  2652  characterizes the multimedia source  110  and communicates source-characterization data to a set  2620  of modules devised to process the received panoramic video signal  900 . The source-characterization data may be determined from characterization data communicated by a panoramic multimedia source or from stored records. The set  2620  of modules includes a signal filtering module  2621 , for offsetting signal degradation due to transmission noise and delay jitter, and may include a server decompression module  350  and a de-warping module  320  ( FIG. 3 ). The signal-filtering module  2621  offsets signal degradation caused by noise and delay jitter. If the “raw” video signal  312  ( FIG. 3 ) has been de-warped at source to produce a “corrected signal”  322  that is further compressed at source, the server decompression module  350  applies appropriate decompression processes to produce a replica of the corrected signal  322 . Otherwise, if the raw video signal  312  has been compressed at source without de-warping, the server decompression module  350  applies appropriate decompression processes to produce a replica of the raw signal  312  which is then de-warped using de-warping module  320 . 
         [0630]    The client-device related modules  2640  include a client-device characterization module  2642  and a module  2643  for signal adaptation to client-device characteristics. The client-device characterization module  2642  may rely on a client-profile database  2641  that stores characteristics of each client-device type of a set of client-device types or extract client-device characteristics from characterization data received via server-client interface  2661 . A client&#39;s device characteristics may relate to processing capacity, upper bounds of frame rate, frame resolution, and flow rate, etc. 
         [0631]    Client-specific modules  2660  include server-client interface  2661 , a module  2662  for signal adaptation to a client&#39;s environment, and a module  2663  for signal adaptation to a client&#39;s viewing preference. 
         [0632]      FIG. 27  illustrates a universal streaming server  120  including a learning module  2725  for tracking clients&#39; selections of viewing options. The learning module may be configured to retain viewing-preference data and correlate viewing preference to characteristics of client devices and optionally clients&#39; environment. 
         [0633]    Thus, the server comprises a network interface module devised to establish, through at least one network, communication paths to and from at least one panoramic video source; and a plurality of client devices. Various designs may be considered to construct the universal streaming server  120  based on the following modules:
       a decompression module devised to decompress a video signal that has been compressed at source;   a de-warping module devised to de-warp a video signal which has not been de-warped at source;   a transcoding module devised to adapt a video signal to characteristics of any client device of the plurality of client devices;   a content filter devised to edit content of a video signal to correspond to an identified view region; and   a control module devised to communicate with at least one panoramic video source to acquire source video signals, present video signals to the transcoding module and the content filter to generate client-specific video signals, and send the client-specific video signals to respective client devices.       
 
         [0639]    The server may further use a learning module devised to retain viewing-preference data and correlate viewing preference to characteristics of client devices. 
         [0640]      FIG. 28  illustrates processes performed at universal streaming server  120  where a panoramic video signal is adapted to client-device types then content filtered. In process  2820 , a received source video signal  900  is decompressed if the source video signal  900  has been compressed at source. The received source video signal  900  is de-warped if the source video signal has not been de-warped at source. Process  2820  produces a pure video signal  420  ( FIG. 4  to  FIG. 8 ), which may be a corrected video signal  322  or a rectified video signal  324  ( FIG. 3 ) as described above. Multiple processes  2830  may be executed in parallel to transcode pure video signal  420  to video signals adapted to different types of client devices. 
         [0641]    Each of processes  2830  is specific to client-device type. A process  2830  transcodes the pure video signal  420  resulting from process  2820  to produce a modified signal suitable for a respective client-device type. Several clients may be using devices of a same type. However, the clients may have different viewing preferences. A video signal produced by a process  2830  is adapted in content filter  1120  to a view-region selection of a respective (human) client. However, if two or more clients using devices of a same type also have similar viewing preferences, a single content-filtering process may be executed and the resulting adapted signal is transmitted to the two or more clients. 
         [0642]      FIG. 29  illustrates processes performed at universal streaming server  120  where a panoramic video signal is content filtered then adapted to client-device types. As in process  2820  of  FIG. 28 , a received source video signal  900  is decompressed if the source video signal  900  has been compressed at source. The received source video signal  900  is de-warped if the source video signal  900  has not been de-warped at source. Process  2820  produces a pure video signal  420 , which may be a corrected video signal  322  or a rectified video signal  324  ( FIG. 3 ) as described above. A memory device stores a set  2925  of predefined descriptors of partial-coverage view regions. 
         [0643]    Multiple processes of content filtering of pure video signal  420  may be executed in parallel to produce content-filtered video signals corresponding to the predefined descriptors of partial-coverage view regions. Multiple processes  2940  may be executed in parallel to adapt a content-filtered video signal to different types of client devices. If two or more clients select a same view region and use client devices of a same type, a single process  2940  is executed and the resulting adapted video signal is transmitted to the two or more clients. 
         [0644]      FIG. 30  illustrates a method  3000  of acquisition of a panoramic multimedia signal and adapting the acquired multimedia signal to individual clients. The universal streaming server  120  acquires a panoramic multimedia signal and, preferably, respective metadata from a selected panoramic multimedia source  110  (process  3010 ). The acquired panoramic multimedia signal includes a source video signal which may be a raw video signal  312 , corrected video signal  322 , compressed video signal  342 , or a compact video signal  343  as illustrated in  FIG. 3 . The source video signal is filtered to offset degradation caused by noise and delay jitter (process  3012 ) and decompressed if the signal has been compressed at source (process  3014 ). The so-far-processed signal is de-warped if not originally de-warped at source (process  3018 ). Processes  3010  to  3018  yield a pure video signal  420 . 
         [0645]    When a service request is received from a client (process  3020 ), the pure video signal  420  is adapted to the characteristics of the client&#39;s device (process  3022 ). The adapted signal is compressed (process  3026 ) and transmitted to the client device (process  3028 ). Process  3026  takes into consideration flow-rate constraints which may be dictated by condition of the network path from the server to the client device. 
         [0646]    The client may prefer a specific view region and communicate with the universal streaming server  120  to define the preferred view region. Upon receiving a control signal  3030  from the client specifying a preferred view region (process  3032 ), the adapted signal produced in process  3022  is content filtered (process  3034 ), compressed (process  3026 ), and transmitted to the client device (process  3028 ). The pure view signal  420  may be content-filtered several times during a streaming session. 
         [0647]      FIG. 31  illustrates a method  3100 , similar to the method of  FIG. 30 , of acquisition of a panoramic multimedia signal and adapting the acquired multimedia signal to individual clients. The only difference is the order of executing processes  3010 ,  3020 , and  3022 . 
         [0648]      FIG. 32  illustrates an exemplary streaming-control table  3200 , maintained at the universal streaming server  120 , corresponding to a specific panoramic multimedia source  110 . An edited multimedia signal  940  ( FIG. 9 ,  FIG. 24 ) delivered to a specific client device  180  depends on the characteristics of the client device and on the viewing preference of a viewer using the client device. With a large number of client devices  180  connecting concurrently to a universal streaming server  120  (watching an activity in real time), it is plausible that:
       (i) numerous clients use client devices  180  of the same characteristics but the clients have differing viewing preferences;   (ii) numerous clients have similar viewing preferences but use client devices of differing characteristics; and/or   (iii) two or more clients use client devices of the same characteristics and have the same viewing preference.       
 
         [0652]    Thus, to reduce the processing effort of the universal streaming server  120 :
       module  2643  of signal adaptation to client device may be exercised only once for all client devices of the same characteristics then module  2663  of signal adaptation to client viewing preference is exercised only once for all clients having similar client devices and similar viewing preferences; or   module  2663  of signal adaptation to client viewing preference may be exercised only once for all clients having similar viewing preferences then module  2643  of signal adaptation to client device is exercised only once for all clients having similar viewing preferences and similar client devices.       
 
         [0655]    As described earlier, module  2643  is devised for signal adaptation to client-device characteristics and module  2663  is devised for signal adaptation to a client&#39;s viewing preference. 
         [0656]    The clients&#39; requests for service may arrive in a random order and a simple way to track prior signal adaptation processes is to use a streaming-control table  3200  ( FIG. 32 ). Streaming-control table  3200  is null initialized. In the example of  FIG. 32 , there are eight types of client devices  180 , denoted D 0 , D 1 , . . . , D 7 , and there are six view options denoted V 0 , V 1 , . . . , V 5 , quantified, for example, according to viewing solid angles. A first client accessed the universal streaming server  120  using a client device of type D 1  and requested viewing option V 3 . A stream denoted stream- 0  is then created and indicated in streaming-control table  3200 . Another stream, denoted stream  1 , is created for another client using a client device  180  of type D 5  and specifying viewing option V 2 , and so on. Only six streams are identified in streaming-control table  3200 , but it is understood that with a large number of simultaneously connected client devices  180  there may be numerous streams. When a new request from a client is received, streaming-control table  3200  is accessed to determine whether a new stream need be created or an existing stream be directed to the client. All of the streams corresponding to a device type are herein said to form a “stream category”. 
         [0657]      FIG. 33  illustrates a streaming control process  3300  of initial adaptation of a video-signal for a specific client device  180 . A request for service is received at server-client interface module  2661  from a client device  180  (process  3310 ) and the type of client device  180  is identified (process  3312 ). Process  3314  determines whether the device type has been considered. 
         [0658]    If the client device type has not been considered (process  3314 ), a new stream category is created (process  3320 ) and the corresponding pure video signal  420  is adapted to the device type (process  3322 ). The new stream category is recorded (process  3324 ), a new stream is created (process  3326 ) and transmitted to the specific client device (process  3330 ). 
         [0659]    If the device type has already been considered (process  3314 ), a stream category is identified (process  3316 ). At this point, the client may not have indicated a viewing preference and a default viewing option may be assigned. If a stream corresponding to an identified view region has already been created (process  3326 ), the stream is transmitted to the specific client device (process  3330 ). Otherwise, a new stream is created (process  3326 ) and transmitted to the specific client device (process  3330 ). 
         [0660]      FIG. 34  illustrates an exemplary table  3400  produced by the learning module  2725  indicating a count of viewing options for each type of client devices  180 . Eight client-device types denoted D 0 , D 1 , . . . , D 7  and six viewing options denoted V 0 , V 1 , . . . , V 5  are considered. The table may accumulate a count of selections of each stream defined by a device type and a viewing option over a predefined time window which may be a moving time window. 
         [0661]    In the exemplary table of  FIG. 34 , the most popular viewing option for clients using the client-device denoted D 1  is viewing option V 3  (selected 64 times over the time window). Thus, a new request for service received at the universal streaming server  120  from a client device of type D 1  may be initially assigned viewing option V 3 . 
         [0662]    Thus, the invention provides a method of signal streaming implemented at a server which may be implemented using hardware processing units and memory devices allocated within a shared cloud-computing network. The method comprises processes of multicasting a signal to a plurality of clients, receiving from a specific client a request to modify content of the signal, producing a modified signal, and transmitting the modified signal to the specific client. The signal may be derived from a panoramic multimedia signal containing a panoramic video signal produced by a single camera or produced by combining video signals from multiple cameras. The modified signal may be a partial-coverage multimedia signal. 
         [0663]    In order to produce the modified signal, the method comprises processes of de-warping a video-signal component of the signal to produce a de-warped video signal and adapting the de-warped video signal to the client device to produce a device-specific video signal. The device-specific signal may be adapted to a viewing-preference of a client. The viewing preference may be stated in a request received from a client or be based on a default value specific to a client-device type. 
         [0664]    The method comprises a process of acquiring characteristics of client devices which communicate with the server to request streaming service. A record of the characteristics of the client device and viewing preference may be added to a viewing-preference database maintained at the server. 
         [0665]    The invention further provides a method of signal streaming performed at a server which may be fully or partially implemented using resources of a cloud computing network. The server may acquire a panoramic multimedia signal then decompress and de-warp a video-signal component of the panoramic multimedia signal to produce a pure video signal. For a given client device of a plurality of client devices:
       (i) the pure video signal is content filtered to produce a respective content-filtered signal which corresponds to a selected view region; and   (ii) the content-filtered signal bound to a client device is adapted to characteristics of the client device as well as to characteristics of a network path from the server to a target client device;       
 
         [0668]    Each client device comprises a processor, a memory device, and a display screen. A client device may send an indication of viewing preference to the server. The server produces a respective content-filtered signal, corresponding to the viewing preference, to be sent to the client device. 
         [0669]    The server may further perform processes of:
       (a) retaining data relating viewing preference to characteristics of clients&#39; devices; and   (b) using the retained data for determining a default viewing preference for each client device of the plurality of client devices.       
 
         [0672]    The server may acquire a panoramic video signal that is already de-warped and compressed at source then decompress the panoramic video signal to produce a pure video signal. A set of modified signals is then produced where each modified signal corresponds to a respective partial-coverage pattern of a predefined set of partial-coverage patterns. Upon receiving connection requests from a plurality of client devices, where each connection request specifies a preferred partial-coverage pattern, the server determines for each client device a respective modified signal according a respective preferred partial-coverage pattern. The respective modified signal bound to a particular client device may further be adapted to suit characteristics of the particular client device and characteristics of a network path to the particular client device. 
         [0673]      FIG. 35  illustrates processes  3500  of downstream signal flow-rate control based on signal-content changes and performance metrics. A flow controller of the server implements one of two flow-control options. In a first option (option  0 ), an encoder of a content-filtered video signal enforces (Process  3542 ) a current permissible flow rate. In a second option (option  1 ), the flow controller communicates (process  3544 ) with a controller of a network which provides a path from the server to a client device to reserve a higher path capacity or to release excess path capacity. 
         [0674]    A network interface ( 1010 ,  FIG. 10 ) of server  120  receives upstream control data from a client device  120  which may contain definition of a preferred video-signal content as well as performance measurements. The traffic performance of a communication path connecting a first device to a second device may be evaluated by exchanging control data between the first device and the second device. The first device may send indications of transmitting time and data-packet indices, the second device may detect delay jitter and/or data-packet loss and communicate relevant information to the first device. Additionally, the second device may track processing delay or packet-buffer occupancy at a decoder of the second device; such information would be indicative of a current processing load at the second device which may require reducing the flow rate from the first device to the second device. 
         [0675]    The network interface receives the upstream control data and extracts performance-measurement data (process  3510 ). The flow controller determines performance metrics using methods well known in the art. The performance measurement may include data loss, delay jitter, and occupancy of a buffer at a client device holding data detected from carrier signals received at the client device from the server  120 . The performance measurements correspond to a current permissible flow rate. The flow controller determines (process  3512 ) performance metrics based on the performance measurement and compares (process  3514 ) the performance metrics with respective acceptance levels which may be based on default values or defined in the upstream control data. If the performance is acceptable, the content-filtered video signal is encoded (process  3550 ) under the current permissible flow rate. If the performance is not acceptable, the flow controller either instructs an encoder to encode the content-filtered video signal at a lower flow rate (option  0 , processes  3540 ,  3542 ) or communicate with a network controller to acquire a path of a higher capacity (option  1 , processes  3540 ,  3544 ). The second option may not be selected if the traffic measurements indicate an unacceptable processing load at the client device. 
         [0676]    The network interface also extracts (process  3520 ) data defining a preferred partial content of the full-content pure video signal and communicates the information to a content filter. The content filter extracts a new content-filtered signal (process  3522 ) from the pure video signal to generate a content-filtered video signal according to received definition of the new content. The flow controller determines (process  3524 ) a tentative flow-rate requirement corresponding to the new content. If the tentative flow rate does not exceed the current permissible flow rate (process  3526 ), the new content-filtered video signal is encoded (process  3550 ) under the permissible flow rate. Otherwise, the flow controller either instructs the encoder to encode the new content-filtered video signal encoded under constraint of the current permissible flow rate (option  0 , processes  3540 ,  3542 ) or communicate with the network controller to acquire a path of a higher capacity (option  1 , processes  3540 ,  3544 ). 
         [0677]      FIG. 36  illustrates a flow-control system of a universal streaming server  120  comprising a flow controller  3610 . The flow controller comprises a processor  3630  and a memory device storing instructions forming a module  3635  for determining a preferred flow rate. Module  3635  may implement processes  3500  of  FIG. 35 . A server-network interface  3625  receives content-definition parameters  3612  and performance measurements  3616 . A content filter  1120  receives a pure video signal  420  ( FIG. 4 ) and extracts partial-content signal  3650  according to content-definition parameters  3612  of requested partial content received from an automaton  2545  ( FIG. 25 ) associated with a client device. Module  3635  uses performance measurements  3616  received from the client device to determine a preferred flow rate. Encoder  3640  encodes the partial-content signal at the preferred flow rate and produces a compressed signal  3660  to be transmitted to the client device. Encoder  3640  comprises a transcoder and a server compression module (not illustrated). 
         [0678]    At the universal streaming server  120 , a received signal from a source may be decompressed to reproduce an original full-content signal; preferably a source sends signals compressed using lossless compression techniques. The full-content signal is processed in a content filter to produce a partial-content signal according to specified content-definition parameters. A preferred flow rate of the partial-content signal is determined based on either receiver performance measurements or network-performance measurements as will be described in further detail in  FIG. 41 . Thus, the partial-content signal is encoded to produce a compressed partial content signal to be transmitted to a respective client device. 
         [0679]      FIG. 37  illustrates a combined process  3700  of content filtering and flow-rate adaptation of a signal in the streaming system of  FIG. 24 . The universal streaming server  120  continuously receives (process  3710 ) from client devices and associated automata control data from clients in the form of content-definition parameters and performance measurements. If the content-definition parameters from a client indicate a request to change content, the content-definition parameters are directed to a content filter  1120  (processes  3720  and  3760 ) and process  3710  is activated after imposing an artificial delay  3770  in order to ensure that received client&#39;s control data correspond to the changed signal content. Otherwise, if the content-definition parameters indicate maintaining a current content, the universal streaming server determines a preferred flow rate (process  3730 ). If the preferred flow rate is the same as a current flow rate, or has an insignificant deviation from the current flow rate, no action is taken and process  3710  is revisited (process  3740 ). If the preferred flow rate differs significantly from the current flow rate, the new flow rate is communicated to encoder  3640  (processes  3740  and  3750 ) and process  3710  is activated after an artificial delay  3770  to ensure that received client&#39;s control data correspond to the new flow rate. The artificial delay should exceed a round-trip delay between the universal streaming server and the client&#39;s device. 
         [0680]      FIG. 38  illustrates a content filter  1120  of a universal streaming server. The content filter  1120  comprises a processor  3822 , a buffer  3826  for holding data blocks of a pure video signal  420 , and a memory device  3824  storing software instructions causing the processor to extract an updated content signal  3860  of partial content from buffered data blocks of the pure video signal. Blocks of the partial-content signal are stored in a buffer  3828 . Processor  3822  executes software instructions which cause transfer of data in buffer  3828  to a subsequent processing stage which may include a transcoding module and/or a compression module. 
         [0681]    Thus, the present invention provides a universal streaming server  120  comprising a network interface  1010 , a content filter  1120 , a flow controller  3610 , and an encoder  3640 . 
         [0682]    The network interface is devised to receive a source video signal  900  from a panoramic signal source  110 , content-definition parameters  3612 , and performance measurements  3616  from a client device  180 . A source signal-processing module  1024 , which comprises a decompression module and a de-warping module, generates a pure video signal  420  from the source video signal  900 . The pure video signal  420  is a full-coverage signal which corresponds to a respective scene captured at source 
         [0683]    The content filter  1120  is devised to extract an updated content signal  3860  from the pure video signal  420  according to the content-definition parameters  3612 . A processor of the content filter is devised to determine a ratio of size of the updated content signal to size of a current content signal. 
         [0684]    The flow controller  3610  comprises a memory device storing flow-control instructions  3635  which cause a hardware processor  3630  to determine a current permissible flow rate of the partial-coverage signal based on the performance measurements and the ratio of size of the updated content signal to size of a current content signal. 
         [0685]    The encoder  3640  comprises a transcoder module and a compression module and is devised to encode the partial-coverage signal under the current permissible flow rate. 
         [0686]    The flow controller  3610  is devised to communicate with a network controller (not illustrated) to acquire a path compatible with a requisite flow rate between the universal streaming server  120  and the client device. 
         [0687]    The flow-control instructions  3635  cause the hardware processor to retain an indication of a difference between the current permissible flow rate and a preceding permissible flow rate. If the difference exceeds a predefined threshold, the instructions cause the processor to delay the process of determining a succeeding permissible flow rate for a predefined delay period to ensure that the received performance measurements correspond to the current permissible flow rate. 
         [0688]    The content filter  1120  comprises a respective processor  3822  and a respective memory device storing content-selection instructions  3824  which cause the respective processor to extract the updated content signal from the pure video signal  420 . A first buffer  3826  holds Data blocks of the full-coverage video signal. A second buffer  3828  holds data blocks of the updated content signal  3860 . 
         [0689]    The content-selection instructions  3824  further cause the respective processor to determine the ratio of size of the updated content signal to size of a current content signal based on sizes of data blocks of the full-content signal and sizes of corresponding data blocks of the updated signal to be used in determining the current permissible flow rate. 
         [0690]    The universal streaming server further comprises a frame-sampling module  1320  comprising a memory device storing frame-sampling instructions which cause a respective hardware processor to sample the pure video signal  420  during distant frame intervals to derive a frame-sampled video signal  1322  ( FIG. 13  and  FIG. 15 ). The frame intervals are selected so that the frame-sampled video signal has a constant flow rate not exceeding a nominal flow rate, and wherein the network interface is further devised to transmit the frame-sampled video signal to the client. 
         [0691]    The content filter  1120  may be devised to derive a set of preselected content-filtered signals corresponding to different view regions from the full-content video signal. A compression module comprising a memory device storing signal-compression instructions may be devised to compress the preselected content-filtered signals to generate a succession of compressed content filtered signals occupying successive time windows. The network interface is further devised to transmit the succession of compressed content filtered signals to the client device, receive an indication of a preferred content-filtered signal of the set of preselected content-filtered signals, and communicate the indication to the content filter. 
         [0692]      FIG. 39  illustrates initial processes  3900  performed at the universal streaming server  120  to start a streaming session. The universal streaming server receives a de-warped compressed full-content signal from a signal source (process  3910 ) and decompresses (process  3915 ) the full-content signal to produce a pure video signal corresponding to a respective scene captured at source. The server receives a connection request from a client device (process  3920 ); the request may include parameters of a partial-content of the signal. If the content-definition parameters are not provided, a default content selection is used (processes  3925 ,  3930 ). A content filter of the universal streaming server extracts (process  3940 ) a partial-content signal based on the default content selection or the specified partial-content selection. The initial content selection may be set to be the full content. A flow rate for the extracted signal may be specified in the connection request in which case an encoder of the universal streaming server may encode the signal under the constraint of the specified flow rate (processes  3950  and  3960 ). Otherwise, a default flow rate may be provided to the encoder (process  3955 ). A compressed encoded partial-content (or full-content) signal is transmitted to the target client device (process  3970 ). 
         [0693]      FIG. 40  illustrates a method  4000  of adaptive modification of video-signal content and flow rate of the transmitted encoded signal. The universal streaming server receives (process  4010 ) a new content preference from an automaton (a person) associated with a client device. If the new content is the same as a current content (processes  4020  and  4050 ), a content filter of the universal streaming server maintains its previous setting and a preferred encoding rate based on received performance data is determined (process  4050 , module  3635  of determining a preferred flow rate,  FIG. 36 ). The signal is encoded at the preferred encoding rate (process  4060 ) and transmitted to the target client device (process  4070 ). If process  4020  determines that the new content differs from the current content, a content filter of the universal streaming server extracts a partial-content signal from the pure video signal (processes  4020  and  4030 ) and encodes the signal at a nominal flow rate (process  4040 ). A compressed encoded partial-content signal is transmitted to the target client device (process  4070 ). 
         [0694]      FIG. 41  illustrates criteria  4100  of determining a preferred encoding rate of a signal based on performance measurements pertinent to receiver condition and network-path condition. A universal streaming server serving a number of client devices receives from a client device performance data relevant to the client&#39;s receiver condition and performance data relevant to a network path from the universal streaming server to the client&#39;s receiver. A module coupled to the universal streaming server determines primary metrics relevant to the receiver&#39;s condition and secondary metrics relevant to the network-path conditions. An acceptance interval, defined by a lower bound and an upper bound, is prescribed for each metric. The metrics are defined so that a value above a respective upper bound indicates unacceptable performance while a value below a respective lower bound indicates better performance than expected. A metric may be considered to be in one of three states: a state of “−1” if the value is below the lower bound of a respective acceptance interval, a state of “1” if the value is above a higher bound of the acceptance interval, and a state “0” otherwise, i.e., if the value is within the acceptance interval including the lower and higher bounds. The terms “metric state” and “metric index” are herein used synonymously. 
         [0695]    The receiver&#39;s condition and the network-path condition are not mutually independent. The network path may affect data flow to the receiver due to delay jitter and/or data loss. The preferred encoding rate (hence flow rate) may be determined according to rules (i) to (iv) below.
       (i) If any primary metric deviates from a respective predefined acceptance interval indicating unacceptable receiver performance, i.e., if a primary metric is above the predefined acceptance interval, a new judicially reduced permissible flow-rate (process  4120 ) is determined based on the primary metrics regardless of the values of the secondary metrics.   (ii) If none of the primary metrics is above the predefined acceptance interval and any secondary metric is above a respective acceptance interval, a new judicially reduced permissible encoding rate (process  4130 ) is determined based on the secondary metrics.   (iii) If each primary metric is below a respective acceptance interval and each secondary metric is below a respective acceptance interval, a new higher permissible flow-rate (process  4140 ) may be judicially determined based on the primary and secondary metrics.   (iv) If none of the conditions in (i), (ii), or (iii) above applies, the current flow rate (encoding rate) remains unchanged ( 4110 ).       
 
         [0700]      FIG. 42  illustrates a method of determining a preferred encoding rate of a signal based on the criteria of  FIG. 41 . The method details process  4050  of  FIG. 40 . The method applies within a same video-signal content selection (view-region selection), i.e., when the universal streaming server determines that a current video-signal content is to remain unchanged until a request for video-signal content change is received. 
         [0701]    A controller of a universal streaming server determines primary metrics based on performance data relevant to a client&#39;s receiver (process  4210 ). If any primary metric is above a respective acceptance interval, a judicially reduced permissible flow rate is determined based on the primary metrics (processes  4220  and  4225 ) and communicated (process  4280 ) to a respective encoder. Otherwise, with none of the primary metrics being above its respective acceptance interval, the controller of the universal streaming server determines secondary metrics based on performance data relevant to conditions of a network path from the universal streaming server to a client&#39;s device (processes  4220  and  4230 ). 
         [0702]    If any secondary metric is above its predefined acceptance interval, a judicially reduced permissible flow rate is determined based on the secondary metrics (processes  4240  and  4245 ) and communicated (process  4280 ) to a respective encoder. Otherwise, if each primary metric is below its predefined acceptance interval and each secondary metric is below its predefined acceptance interval, a new encoding rate based on the primary and secondary metrics is determined (processes  4250  and  4260 ) and communicated to a respective encoder (process  4280 ). If any primary metric or any secondary metric is within its respective acceptance interval, the current encoding rate is maintained (process  4255 ). 
         [0703]    Thus, the invention provides a method of signal streaming in a streaming system under flow-rate regulation. The method comprises acquiring at a server  120  comprising at least one hardware processor a source video signal  900  from which a pure video signal  420  is derived, sending a derivative of the pure video signal to a client device  180 , and receiving at a controller  3610  of the server  120  content selection parameters  3612  from the client device defining preferred partial coverage of the full-coverage video signal. A content filter  1120  of the server extracts a partial-coverage video signal  3650  from the pure video signal  420  according to the content selection parameters  3612 . 
         [0704]    The server transmits the partial-coverage video signal to the client device  180 . Upon receiving performance measurements  3616  pertinent to the partial-coverage video signal, the controller  3610  determines an updated permissible flow rate of the partial-coverage video signal based on the performance measurements. An encoder  3640  encodes the partial-coverage video signal according to the updated permissible flow rate. The encoder  3640  transcodes the partial-coverage video signal to generate a transcoded signal compatible with characteristics of the client device and compresses the transcoding signal. 
         [0705]    The controller  3610  may instruct the encoder  3640  to encode the partial-coverage video signal under the constraint of a current permissible flow rate. Alternatively, the controller may communicate with a network controller (not illustrated) to acquire a downstream network path compatible with the updated permissible flow rate between the server  120  to the client device  180 . 
         [0706]    The derivative of the pure video signal may be generated as a frame-sampled video signal  1322  ( FIG. 13 ,  FIG. 15 ) of a constant flow rate not exceeding a predefined nominal flow rate. Alternatively, the derivative may be generated as a compressed video signal  1342  ( FIG. 13 ), within the predefined nominal flow rate, derived from the pure video signal  420 . The derivative of the pure video signal may also be generated as a succession  1364  ( FIG. 13 ) of compressed content-filtered video signals occupying successive time windows, and derived from the pure video signal. 
         [0707]    The performance measurements pertain to conditions at a receiver of the client device and conditions of a downstream network path from the server to the client device. The controller  3610  determines primary metrics based on performance measurements pertinent to the conditions of the receiver. Where at least one primary metric is above a respective acceptance interval, the controller  3610  judicially reduces a current permissible flow rate based on the primary metrics ( FIG. 41 ). Otherwise, where none of the primary metrics is above a respective acceptance interval, the controller  3610  determines secondary metrics based on performance measurements pertinent to the downstream network path. Where at least one secondary metric is above a respective acceptance interval, the controller judicially reduces the current flow rate of the signal based on values of the secondary metrics ( FIG. 41 ). 
         [0708]    Where each primary metric is below a respective acceptance interval and each secondary metric is below a respective acceptance interval, the controller judicially increases the current permissible flow rate based on the primary and secondary metrics ( FIG. 41 ). 
         [0709]      FIG. 43  illustrates a method of eliminating redundant processing of content selection in a universal streaming server  120  serving numerous clients. Upon receiving a full-coverage signal (process  4310 ) at the universal streaming server  120 , a controller of the universal streaming server creates (process  4320 ) a register for holding parameters of produced partial-coverage signals (content-filtered signals). Initially, the register would be empty. A compressed full-coverage signal is decompressed at the server and de-warped if not de-warped at source. The controller receives (process  4330 ), from a specific client device, parameters defining a preferred view region. The controller inspects (process  4340 ) the register to ascertain presence or otherwise of a previously generated partial-coverage signal. 
         [0710]    If the register content indicates that a matching partial-coverage signal has already been generated, the controller provides access to the matching partial-coverage signal (processes  4350  and  4360 ). A partial-coverage signal is directed to an encoder for further processing (process  4390 ). A partial-coverage signal may be directed to multiple encoders operating under different permissible flow rates to produce encoded signals of different flow rates with all encoded signals corresponding to a same view region. An encoder comprises a transcoding module and a server compression module. Alternatively, the partial-coverage signal may be presented to one encoder to sequentially produce encoded signals of different flow rates with all encoded signals corresponding to a same view region. 
         [0711]    If no matching partial-coverage signal is found, the controller directs the full-coverage signal to a content filter  1120  ( FIG. 36 ) to extract (process  4370 ) a new partial-coverage signal according to the new content-definition parameters defining the preferred view region. The new content-definition parameters are added (process  4380 ) to the register for future use and the new partial-coverage signal is directed to an encoder for further processing. 
         [0712]    Thus, the invention provides a method of signal streaming comprising receiving at a server a full-coverage signal and at a controller comprising a hardware processor:
       forming a register for holding identifiers of partial-coverage signals derived from the full-coverage signal;   receiving from a client device coupled to the server new content-definition parameters defining a view region; and   examining the register to ascertain presence of a matching partial-coverage signal corresponding to the new content-definition parameters.       
 
         [0716]    If the matching partial-coverage signal is found, the matching partial-coverage signal is transmitted to the client device. Otherwise the full-coverage signal is directed to a content filter for extracting a new partial-coverage signal according to the new content-definition parameters. The new partial-coverage video signal is encoded to generate an encoded video signal and a bit rate of the encoded video signal is determined. The new content-definition parameters are added to the register. 
         [0717]    The process of encoding comprises transcoding the new partial-coverage video signal to generate a transcoded video signal then compressing the transcoded video signal under constraint of a predefined nominal flow rate. 
         [0718]    The server receives from the client device performance measurements pertinent to conditions at a receiver of the client device and conditions of a network path from the server to the receiver. The controller determines performance metrics based on the performance measurements and a permissible flow rate. The permissible flow rate is determined as a function of deviation of the performance metrics from corresponding predefined thresholds and the bit rate of the encoded video signal. 
         [0719]    The process of encoding may further direct the new partial-coverage signal to multiple encoders operating under different permissible flow rates to produce encoded signals of different flow rates corresponding to the view region. 
       Seamless Content Change 
       [0720]    A universal streaming server  120  may access multiple panoramic multimedia sources  110  ( FIG. 2 ) and may concurrently acquire multimedia signals to be processed and communicated to various client devices  180 . Each multimedia signal may include a source video signal  900  ( FIGS. 9, 17, 23, and 28 ) which may be a raw signal  312 , a corrected signal  322 , a compressed signal  342 , or a compact signal  343  ( FIG. 3 ). A source video signal is a full-coverage video signal which may be content filtered according to different sets of content-definition parameters to generate partial-coverage video signals corresponding to different view regions. The source video signal  900  may be decompressed and/or de-warped at the server to generate a pure video signal  420  which corresponds to a respective scene captured at source. The server  120  may employ multiple content filters  1120  as illustrated in  FIGS. 17, 19, 28, and 29 . 
         [0721]    Server  120  provides a content-filtered video signal specific to each active client device using a signal-editing module  460  comprising a content filter  1120 , a transcoding module  1140 , and a compression module  1160  ( FIG. 11 ). The server may receive an upstream control signal from a specific client device  180  containing new content-definition parameters corresponding to a new view region. In order to provide seamless transition from one view region to another, the server may provide a number of spare signal-editing modules  460  so that while a particular signal-editing module  460 -A is engaged in processing a current video-signal content, a free signal-editing module  460 -B may process the video-signal content specified in a new content-definition parameters then replace the particular signal-editing module  460 -A which then becomes a free signal-editing module. 
         [0722]      FIG. 44  illustrates transient concurrent content-filtering of a video signal to enable seamless transition from one view region to another. A pure video signal  420  is presented to eight signal-editing modules  460 , individually identified as  460 ( 0 ) to  460 ( 7 ). Six different content-filtered signals are generated from the pure-video signal to be distributed to at least six client devices  180 . Signal-editing modules  460  of indices  0 ,  1 ,  2 ,  3 ,  5 , and  7  are concurrently generating respective content-filtered video signals. Data blocks generated at the aforementioned signal-editing modules are respectively directed to buffers  4420  of indices  2 ,  0 ,  4 ,  1 ,  3 , and  5 . A multiplexer  4450  combines data blocks read from the buffers and the resulting multiple content-filtered streams  4460  are distributed to respective client devices through a network. 
         [0723]    In the example of  FIG. 44 , a client device  180  receiving a content-filtered video signal processed at signal-editing module  460 ( 2 ) provides new content-definition parameters. A controller (not illustrated) comprising a hardware processor instructs signal-editing module  460 ( 6 ), which is currently free, to generate a new content-filtered video signal according to the new content-definition parameters. After a transient period, signal-editing module  460 ( 6 ) would direct data blocks of the new content-filtered video signal to buffer  4420 ( 4 ) and signal-editing module  460 ( 2 ) would disconnect and become a spare signal-editing module. 
         [0724]      FIG. 45  illustrates coupling the universal streaming server  120  to a network. The universal streaming server  120  may be implemented in its entirety within a cloud computing network and communication with the client devices  180  may also take place within the cloud computing network. Alternatively, the generated client bound streams  940  ( FIG. 9 ) may be routed to the client devices through a router/switch  4540  of another network. Router-switch  4540  may connect to numerous other servers or other router-switches through input ports  4541  and output ports  4542 . 
         [0725]    Thus, the server comprises network access ports to communicate with a plurality of video sources and a plurality of client devices through a shared network. The server may be partially or entirely installed within a shared cloud-computing network where the physical processors and associated memory devices are dynamically allocated on demand. 
         [0726]    Summing up, the disclosed universal streaming server is devised to interact with multiple panoramic multimedia sources of different types and with client devices of different capabilities. The server may exchange control signals with a panoramic multimedia source to enable acquisition of multimedia signals together with descriptors of the multimedia signals and data indicating signal processes performed at source. The server may exchange control signals with a client device to coordinate delivery of a signal sample of a full-coverage (attainable-coverage) panoramic video signal and acquire identifiers of a preferred view region from a viewer at the client device. 
         [0727]    The server is devised to implement several methods of capturing a client&#39;s viewing preference. According to one method, a signal sample corresponding to attainable spatial coverage is sent to client device and a viewer at a client device may send an identifier of a preferred view region to the server. The server then sends a corresponding content-filtered video signal. The server distributes software module to subtending client devices to enable this process. According to another method, the server may multicast to client devices a number of content-filtered video signals corresponding to different view regions. The content-filtered video signals are derived from a full-coverage (attainable-coverage) panoramic video signal. Viewers at the client devices may individually signal their respective selection. The server may use a streaming-control table ( FIG. 32 ) to eliminate redundant processing. 
         [0728]    A panoramic video signal is acquired and transcoded to produce a transcoded signal compatible with a client device. A signal sample of the transcoded signal is then transmitted to the client device. Upon receiving from the client device descriptors of a preferred view region, the content of the transcoded signal is edited to produce a content-filtered signal corresponding to the preferred view region. The content-filtered signal, or a compressed form of the content-filtered signal, is sent to the client device instead of the signal sample. 
         [0729]    Acquiring the panoramic video signal comprises processes of establishing a connection from the server to a panoramic multimedia source, requesting and receiving a multimedia signal that includes the panoramic video signal together with indications of any signal processing applied to the panoramic video signal at source. The acquired panoramic video signal may be decompressed and/or de-warped at the server according to the indications of processes performed at source. The signal sample may be a frame-sampled signal comprising distant frames of the transcoded signal. Alternatively, the signal sample may be a compressed form of the transcoded signal. 
         [0730]    Arrangements for efficient video-signal content selection in a universal streaming system serving numerous clients have been described and illustrated in  FIGS. 19, 28, 29, and 43 . The method of signal streaming of  FIG. 43  comprises receiving (process  4310 ) at a server  120  a full-coverage signal and at a controller comprising a hardware processor:
       forming (process  4320 ) a register for holding identifiers of partial-coverage signals derived from the full-coverage signal;   receiving (process  4330 ) from a client device  180  coupled to the server  120  new content-definition parameters defining a view region; and   examining (process  4340 ) the register to ascertain presence of a matching partial-coverage signal corresponding to the new content-definition parameters.       
 
         [0734]    If a matching partial-coverage signal is found (processes  4350  and  4360 ) the controller directs (process  4390 ) the matching partial-coverage signal to an encoder prior to transmission to the client device. If a matching partial-coverage signal is not found, the controller directs (process  4350 ) the full-coverage signal to a content filter to extract (process  4370 ) a new partial-coverage signal according to the new content-definition parameters. 
         [0735]    The new partial-coverage video signal may need to be transcoded to generate a transcoded video signal compatible with characteristics of the client device. The transcoded video signal may be further compressed under a predefined nominal flow rate. The controller determines a bit rate of the encoded video signal and inserts (process  4380 ) the new content-definition parameters in the register. 
         [0736]    The method further comprises receiving from the client device performance measurements pertinent to conditions at a receiver of the client device and conditions of a network path from the server to the receiver. The controller determines performance metrics based on the performance measurements. The controller determines a permissible flow rate as a function of deviation of the performance metrics from corresponding predefined thresholds ( FIG. 41 ) and the bit rate of the encoded video signal. 
         [0737]    The new partial-coverage signal may be directed to multiple encoders operating under different permissible flow rates to produce encoded signals corresponding to the same view region but of different flow rates and/or different formats to be transmitted to different client devices. 
         [0738]    Processor-executable instructions causing respective hardware processors to implement the processes described above may be stored in processor-readable media such as floppy disks, hard disks, optical disks, Flash ROMS, non-volatile ROM, and RAM. A variety of processors, such as microprocessors, digital signal processors, and gate arrays, may be employed. 
         [0739]      FIG. 46  illustrates a conventional system  4600  for selective content broadcasting. A plurality of signal sources  4610  is positioned for live coverage of an event. Each signal source  4610  comprises a camera  4614  operated by a person  4612  and coupled to a transmitter  4616 . The signals from the signal sources  4610  are communicated through a transmission medium  4620  to a broadcasting station. A receiver  4630  at the broadcasting station acquires the baseband signals  4640 . The receiver  4630  has multiple output channels each for carrying a baseband signal  4640  generated at a respective signal source  4610 . Each acquired baseband signal is fed to a respective display device  4650  of a plurality of display devices. A manually operated view-selection unit  4660  selects one of baseband signals fed to the display devices  4650 . A viewer  4662  observes all displays and uses a selector (a “switcher”)  4664  to direct a preferred baseband signal  4640  to a transmitter  4680 . The transmitter  4680  is coupled to a transmission medium through an antenna or a cable  4690 . Components such as encoders and decoders, well known in the art, used for performing baseband signal compression and decompression, are omitted in  FIG. 46 . 
         [0740]      FIG. 47  illustrates an arrangement for broadcasting operator-defined content of multimedia signals. A panoramic signal source  4710  generates a modulated carrier source signal  4712  containing a panoramic multimedia signal. The panoramic multimedia signal includes a 4π video signal component from a 4π camera as well as other components, such as audio and text components, which may be produced by camera circuitry and/or other devices (not illustrated). A raw video signal  312  ( FIG. 3 ) provided by the camera may be inherently warped. A source-processing unit  4714  may perform processes including:
       de-warping the raw signal to produce a corrected signal  322  ( FIG. 3 );   compressing the raw signal without de-warping to produce a compressed signal  342  which would be decompressed and de-warped at destination;   de-warping and compressing the raw signal to produce a compact signal  343  which would be decompressed at destination.       
 
         [0744]    The source-processing unit  4714  may further insert signal description data indicating whether any signal process (de-warping/compression) has been performed 
         [0745]    The source-processing unit  4714  may also include a module  4715  for providing cyclic video-frame numbers where the sequential order of the frames may be indicated. For example, using a single byte of 8 bits to mark the sequential order, the frames would be cyclically indexed as 0 to 255. This indexing facilitates content filtering. 
         [0746]    A broadband transmitter  4716  transmits the processed multimedia signals along a transmission medium  4718  to a content selector  4740  for content filtering before communicating the signal to a broadcasting facility. 
         [0747]    An acquisition module  4720  generates from the modulated carrier source signal  4712  a pure multimedia signal  4730  as well as a signal descriptor  4732 . The pure multimedia signal  4730  includes a pure video signal that represents images captured by the camera. The signal descriptor  4732  identifies processes performed at the panoramic signal source  4710 . The pure multimedia signal is presented to a content selector  4740 , to be described below with reference to  FIG. 50 , to produce a content-filtered signal  4764 . The content selector  4740  comprises a virtual-reality (VR) headset  4750  and a content filter  4760 . An operator  4725  uses the VR headset to select content considered suitable for target viewers. The operator may rely on an internal display of the VR headset and/or an external display  4770 . 
         [0748]      FIG. 48  illustrates a first combined broadcasting and streaming system  4800  configured to receive a modulated carrier source signal  4712  and generate an operator-defined content filtered multimedia signal as well as multiple viewer-defined content-filtered multimedia signals. 
         [0749]    A 4π multimedia baseband signal is generated at a multimedia signal source  4710  ( FIG. 47 ) which modulates a carrier signal to produce the modulated carrier source signal  4712 . The received modulated carrier source signal  4712  is directed concurrently to a broadcasting subsystem  4804  and a streaming subsection  4808 . 
         [0750]    A repeater  4810  may enhance the modulated carrier source signal  4712  and direct the enhanced carrier signal to a streaming apparatus  4820  through a transmission medium  4812 . The streaming apparatus  4820  comprises an acquisition module  4720 -B and a Universal Streaming Server  120 . The Universal Streaming Server  120  receives viewing-preference indications from a plurality of client devices  180  through network  150  and provides client-specific multimedia signals as described earlier with reference to  FIGS. 10, 28, and 29 . 
         [0751]    An acquisition module  4720 -A generates a pure multimedia signal  4730 , which corresponds to the content captured at a field of an event, from the modulated carrier source signal  4712 . The pure multimedia signal  4730  is directed to content selector  4740  which continually extracts broadcast multimedia signals  4764  to be communicated to a broadcasting facility. The broadcast multimedia signal  4764  may be compressed at compression module  4862  to produce compressed content-filtered signal  4864  which is supplied to transmitter  4870  for transmitting a respective modulated carrier through a channel  4880  to a broadcasting station and/or to the Universal Streaming Server  120  through a channel  4890  and network  150 . The Universal Streaming Server  120  may offer the broadcast multimedia signal as a default for a client  180  that does not specify a viewing region preference. 
         [0752]      FIG. 49  illustrates an acquisition module  4720  for reconstructing a pure multimedia signal from a modulated carrier source signal  4712  received from a panoramic multimedia signal source. The pure multimedia signal contains a pure video signal and other multimedia components. As illustrated in  FIG. 3 , the baseband signal transmitted from a multimedia source may be a raw signal  312 , a corrected (de-warped) signal  322  which is a pure multimedia signal, a compressed raw signal  342 , or a compact signal (de-warped and compressed)  343 . Thus, the received modulated carrier source signal  4712  may carry one of the four baseband signals  312 ,  322 ,  342 , and  343 . 
         [0753]    A receiver  4940  demodulates the modulated carrier source signal  4712  and produces a source multimedia signal  4943  and a signal descriptor  4732  which identifies processes performed at source. Input selector  4946  directs the source multimedia signal  4943  to different paths to output of the acquisition module. Output selector  4947  is synchronized with, and complements, input selector  4946 . 
         [0754]    Receiver  4940  produces:
       (a) a replica of a raw signal  312  which is supplied to pure signal generator  4950 -A comprising a de-warping module  320  to produce a pure multimedia signal  4730 ;   (b) a corrected signal  322  (de-warped) which is a pure multimedia signal  4730 ;   (c) a compressed signal  342  which is supplied to pure signal generator  4950 -B comprising a decompression module  350  and a de-warping module  320  to produce a pure multimedia signal  4730 ; or   (d) a compact signal  343  (de-warped and compressed) which is supplied to pure-signal generator  4950 -C comprising a decompression module  350  to produce a pure multimedia signal  4730 .       
 
         [0759]      FIG. 50  illustrates an arrangement for content selection for broadcasting comprising a virtual-reality headset (VR headset)  4750  and a content filter  4760 . The VR headset comprises at least one processor, storage media, and a gaze-tracking mechanism. 
         [0760]    In a first implementation of the content selector ( 4740 -A), a content-filter  4760 A is a separate hardware entity and a pure multimedia signal  4730  is supplied to both the VR headset  4750  and the content filter  4760 A. The content filter  4760 A comprises a respective processor and a memory device storing processor-readable instructions constituting a module for extracting from the pure multimedia signal a filtered multimedia signal with adaptive spatial coverage which closely corresponds to head or eye movement of an operator using a low-latency VR headset  4750 . A control signal  4752  communicates parameters defining the spatial coverage from the VR-headset  4750  to the content filter  4760 A. The content filter  4760 A generates content-filtered signal  4764  intended for broadcasting. The content-filtered signal  4764  may be displayed using an external display  5090 . 
         [0761]    In a second implementation of the content selector ( 4740 -B), a content-filter  4760 B is embedded in the VR headset  4750  where processor-readable instructions for extracting a filtered multimedia signal reside in a memory device of the VR headset. Thus, the content-filtered signal is provided at an outlet of the VR headset  4750 . 
         [0762]      FIG. 51  illustrates a first broadcasting subsystem  5100  for selective content broadcasting employing a panoramic camera and a VR headset. Instead of deploying multiple signal sources  4610  ( FIG. 46 ), a single, possibly unattended, panoramic signal source  4710  may be used to cover an event. A 4π camera  310  captures a view and produces a raw signal  312  which may be directly fed to a broadband transmitter  4716 . Alternatively, the raw signal may be fed to a source-processing unit  4714  which selectively produces a corrected (de-warped) signal  322 , a compressed raw signal  342 , or a compact signal (de-warped and compressed)  343  as illustrated in  FIG. 3 . The output of the source-processing unit  4714  is supplied to broadband transmitter  4716 . 
         [0763]    The broadband transmitter  4716  sends a modulated carrier source signal  4712  through transmission medium  4718  to an acquisition module  4720  which is a hardware entity comprising a receiver  4940 , a processor residing in a monitoring facility  5120 , and memory devices storing processor-readable instructions which cause the processor to perform functions of de-warping and/or decompression as illustrated in  FIG. 3 . The acquisition module produces a pure multimedia signal  4730  which is fed to a VR headset  4750  and a content filter  4760  ( FIG. 50 ). The pure multimedia signal  4730  is also fed to a panoramic-display device  4770  if the VR headset does not have an internal display unit or to provide a preferred display. As described above, the view-selection unit  4740  comprises a VR headset  4750  which an operator  4725  wears to track views of the panoramic display considered to be of interest to television viewers of an event. 
         [0764]    A low-latency VR headset  4750  interacting with a content filter  4760  generates a content-filtered multimedia signal  4764  corresponding to the operator&#39;s changing angle of viewing. The content-filtered multimedia signal may be supplied to an auxiliary display device  5090  and to a compression module  4862 . The output signal  4864  of the compression module is fed to a transmitter  4870  to modulate a carrier signal to be sent along a channel  4880  to a broadcasting station and—optionally—along a channel  4890  to a Universal Streaming Server  120 . 
         [0765]    In the broadcasting subsystem of  FIG. 51 , the content selector  4740  residing in a monitoring facility  5120 , which is preferably situated at a short distance from the panoramic signal source  4710 , comprises a VR headset and a content filter  4760 . The VR headset, together with the operator, constitutes a “content controller”. The content filter  4760  is either directly coupled to the VR headset  4750  or embedded in the VR headset. The control data  4752  generated at the VR headset corresponds to a pure signal  4730  supplied to the VR headset. 
         [0766]      FIG. 52  illustrates a second broadcasting subsystem for selective content broadcasting for a case where the content controller and the content filter  4760  are not collocated so that a signal-transfer delay from one to the other is significant. Due to the signal-transfer delay, a content-filtered signal produced at the content filter based on control data sent from the VR headset would result in a view region that differs from what the operator of the VR headset selected. To circumvent this discrepancy, the pure signal  4730  provided to the VR headset and the content filter is buffered at the content filter to permit applying control data to corresponding portions of the pure signal  4730 . 
         [0767]    The content filter  4760  is upgraded to an augmented content selector  5210  which comprises: a content buffer  5230  preceding the content filter  4760 ; and a content-filter controller  5220  coupled to the memory controller of the content buffer and to the content filter  4760 . 
         [0768]    Data blocks of a pure signal  4730  derived at an acquisition module  4720  collocated with the augmented content selector  5210  are simultaneously directed to the content buffer  5230  and to a communication channel to the VR headset. The content buffer stores data blocks, each data block corresponding to a display image, i.e., pure signal data during a frame period (for example, 20 milliseconds at a frame rate of 50 frames per second). Each data block is stored at a buffer address corresponding to a cyclic frame number. For example, the content buffer may be organized into L segments, L&gt;1, each for holding a data block of one frame. The L segments would be indexed as 0 to (L−1). The frames are assigned cyclical numbers between 0 and (L−1), so that a frame of absolute number M would have a cyclical number m=M modulo L  and a data block corresponding to frame M would be stored in memory segment m in content buffer  5230 . Thus, content buffer  5230  is operated as a circular buffer of L buffer segments. For example, with L=128, a data block of frame 12000 would be stored at address 96 (12000 modulo 128 ). 
         [0769]    At a frame rate of 50 frames per second, a period of 128 frames is 2.56 seconds which is much larger than any round trip signal transfer delay between the augmented content selector and the distant content selector  5240 . Thus, each data block would be held in the content buffer for a sufficient period of time to be presented together with corresponding control data to the content filter  4760 . This requires that each control signal resulting from an operator action be associated with a respective cyclic frame number. 
         [0770]    As illustrated in  FIG. 47 , a module  4715  provides cyclic video-frame numbers which would be needed to facilitate relating control data (messages)  5270  ( FIG. 52 ,  FIG. 58 ), received at augmented content selector  5210  from distant content selector  5240 , to corresponding video frames. The cyclic period, denoted Γ, of the cyclic video-frame numbers is at least equal to L and may be much larger. With Γ=4096 and L=128, for example, a frame of an absolute frame number 12000 would have a cyclic number of 12000|modulo 4096, which is 3808, with respect to cyclic period Γ and a cyclic number 12000|modulo 128, which is 96, with respect to cyclic period L. Content-filter controller  5220  would then determine the address of a frame data block corresponding to frame cyclic number 3808 as 3808|modulo 128, which is 96. 
       Regulating View-Region Updates 
       [0771]      FIG. 53  illustrates control data  5270  sent from the distant content selector  5240  to the augmented content selector  5210  of the broadcasting subsystem of  FIG. 52 . The control data comprises view-region definition data such as the conventional parameters “Tilt-Pan-Zoom” defining a “gaze position” and other parameters which enable precise definition of a view region corresponding to the operators gaze orientation. In order to relate the parameters to an appropriate portion of the pure signal  4730 , an identifier of a corresponding frame need be associated with the control data  5270 . It suffices to use cyclic frame number with a sufficient cyclic limit Γ; Γ=4096 for example. As illustrated in  FIG. 53 , a cyclic frame number is associated with each gaze position. With Γ=4096, a frame cyclic number 0 follows a frame cyclic number 4095. Notably, cyclic limit Γ may assume any value equal to or exceeding the number L of buffer segments of the content buffer  5230 . 
         [0772]    In order to avoid unnecessary redefinition of the view region for minor displacements of the gaze position, herein referenced as gaze-position jitter, a displacement Δ of a current gaze position from a reference gaze position defining a last view region is determined. The displacement may be determined as a Euclidean distance between a current gaze position and a reference gaze position. If the displacement exceeds a predefined displacement threshold Δ*, a new view region is determined and the current gaze position becomes the reference gaze position. The control data from the distant content selector  5240  to the augmented content selector  5210  indicates the gaze position and other associated parameters with a “refresh” flag. Otherwise, if the displacement is less than, or equal, to the predefined threshold Δ*, control data from the distant content selector  5240  indicates a null position to the augmented content selector  5210  so that the last reference gaze position remains in effect. 
         [0773]    Thus, the present invention provides a method of communication comprising employing a virtual-reality headset,  4750 ,  FIG. 47 , to produce a virtual-reality display of a pure signal  4730  comprising multimedia signals and generate geometric data  4752  defining a selected view-region definition data of the display. The virtual-reality display may be produced from the pure signal using an internal display device of the virtual-reality headset  4750  and/or an external display device  4770 . 
         [0774]    A content filter  4760  extracts a content-filtered signal  4764  from the pure signal according to the geometric data. The content-filtered signal is directed to a broadcasting apparatus. The virtual-reality headset comprises a processor and memory devices to perform the process of generating the geometric data and tracking of changing gaze orientation of an operator  4752  wearing the virtual-reality headset  4750 . 
         [0775]    A sensor within the virtual-reality headset provides parameters defining a current gaze orientation of the operator  4725 . A content filter is devised to determine the selected view region according to the current gaze orientation and a predefined shape of the view region. 
         [0776]    The pure signal  4730  is produced from a source signal  4712  received from a panoramic signal source  4710 . The source signal  4712  includes multimedia signal components  4943  and a signal descriptor  4732  identifying the multimedia signal. The signal descriptor identifies content of the source signal as one of:
       the pure signal  322  ( FIG. 3 );   a raw signal  312 ;   a warped compressed signal  342 ; and   a de-warped compressed signal  343 .       
 
         [0781]    If the content of the source signal is not the pure signal, the source signal is supplied to a matching pure-signal generator  4950  ( FIG. 49 ) to produce the pure signal. 
         [0782]    The process of generating the geometric data comprises steps of determining a gaze position  5320  of a viewer of the virtual-reality display ( FIG. 53 ), and determining spatial coordinates of a contour of a predefined form surrounding the gaze position  5320 . 
         [0783]    The content-filtered signal  4764  is extracted from the pure signal according to the geometric data. The content-filtered signal  4764  comprises samples of the pure signal corresponding to content within the contour. The function of the content filter  4760  may be performed within the virtual-reality headset so that extracting the content-filtered signal may be performed using processor executable instructions stored in a memory device of the virtual-reality headset. Alternatively, extracting the content-filtered signal may be performed at an independent content filter  4760  coupled to the virtual-reality headset and comprising a respective processor and a memory device. 
         [0784]    The content-filtered signal  4764  may be compressed to produce a compressed filtered signal  4864  ( FIG. 48 ). The compressed filtered signal may then be transmitted to a broadcasting station, through channel  4880 , and/or a Universal Streaming Server, through channel  4890  and network  150 . 
         [0785]    The source signal  4712  received from the panoramic signal source  4710  may be relayed, using repeater  4810  ( FIG. 48 ), to a streaming apparatus  4820  that comprises an acquisition module  4720 -B and a Universal Streaming Server  120 . The acquisition module generates a replica of the pure signal  4730  which is supplied to the Universal Streaming Server. The Universal Streaming Server is configured to provide viewer content control to a plurality of viewers  180  ( FIG. 48 ). 
         [0786]    As described above, the present invention provides a communication system configured to receive a modulated carrier source signal  4712  and extract a content-filtered multi-media signal  4764  for broadcasting. The system comprises a virtual-reality headset  4750 , a content filter  4760 , and a transmitter. 
         [0787]    The virtual-reality headset is configured to present a virtual-reality display of a pure signal  4730  derived from the received modulated carrier source signal  4712 . The content filter is configured to generate a content-filtered signal  4764  from the pure signal according to the geometric data. The transmitter sends the content-filtered signal along a channel to a broadcasting station. 
         [0788]    The virtual-reality headset comprises a sensor of gaze orientation of an operator  4752  wearing the virtual-reality headset and a memory device storing processor executable instructions causing a processor to generate geometric data  4752  defining a view region of the display according to the gaze orientation. The content filter comprises a respective processor and a memory device. 
         [0789]    The communication system further comprises an acquisition module  4720  ( FIG. 47 ,  FIG. 49 ) for deriving the pure signal  4730  from the received panoramic multimedia signal  4712 . The acquisition module comprises a receiver  4942 , a set of pure-signal generators  4950  for generation the pure signal, and a selector  4946 . Receiver  4942  generates from a modulated carrier source signal a source multimedia signal and a corresponding signal descriptor. Selector  4946  directs the source multimedia signal to a matching pure-signal generator  4950  according to the corresponding signal descriptor. 
         [0790]    The virtual-reality headset is further configured to determine a gaze position of the operator  4752  and the geometric data  4752  as representative spatial coordinates of a contour of a predefined form surrounding the gaze position. The content-filtered signal  4764  comprises samples of the pure signal  4730  corresponding to content within the contour. 
         [0791]    Optionally, the communication system may comprise a repeater  4810  ( FIG. 48 ) for relaying the modulated carrier source signal  4712  sent from a panoramic signal source  4710  to a streaming apparatus  4820 . The streaming apparatus comprises an acquisition module  4720  for generating a replica of the pure signal  4730  and a Universal Streaming Server  120  receiving the pure signal  4730  and providing content-filtered signals based on individual viewer selection. 
       Accounting for Control-Data Delay 
       [0792]      FIG. 54  illustrates data exchange  5400  between the augmented content selector  5210  and the distant content selector  5240  of the broadcasting subsystem of  FIG. 52 . The cyclic frame identifiers of frame data blocks  5410  of a pure signal  4730  supplied to the content buffer  5230  and the distant content selector are denoted f 0 , f 1 , . . . , f Γ−1 ; only f 0  to f 17  are illustrated. Each frame data blocks  5410  sent from an acquisition module  4720  collocated with the augmented content selector to the distant content selector  5240  is subject to a transfer delay  5440 . A displayed image corresponding to the frame data block may result in a response from the operator  4725  causing the tracking mechanism of the VR headset to generate a new gaze position with latency  5450 . A message  5420  indicating a gaze-position displacement (which may be zero or a negligible value) is inserted in the content control data  5270  which is sent to the augmented content selector  5210  with a transfer delay of  5460 . A message  5420  also includes a frame identifier and other control parameters defining a view region. The total round-trip and tracking delay ( 5440 ,  5450 , and  5460 ) may be significantly larger than the frame period  5430  depending on the relative locations of the augmented content selector  5210  and the distant content selector. The frame identifiers indicated in the messages  5420  are denoted φ 0 , φ 1 , . . . , φ Γ−1 ; only φ 0  to φ 12  are illustrated. As indicated, there is a delay of five frame periods between the instant of sending a frame data block  5410  from an acquisition module coupled to the augmented content selector  5210  and receiving a respective control message from the distant content selector  5240 . During a frame period  5 , frame data block f 5  is supplied to the content buffer  5230  while control data relevant to a frame data block f 0  sent earlier during frame period  0  is received at content-filter controller  5220  of the augmented content selector  5210 . 
         [0793]      FIG. 55  illustrates frame-data flow through the content buffer  5230  of the augmented content selector  5210  of the system of  FIG. 52  indicating occupancy of the content buffer during successive frame periods. As described above, content buffer  5230  is a circular buffer that stores a maximum of L frame data blocks  5410 , each frame-data block occupying one buffer segment. The number L may be selected so that the duration of L frames exceeds the round-trip data transfer delay between the augmented content selector  5210  and the distant content selector  5240 . Frame data blocks are written sequentially in consecutive buffer segments of indices  0  to (L−1). The buffer segment in which a frame-data block is written during a frame period j is denoted W(j) and the buffer segment from which a frame-data block is read during a frame period j is denoted R(j), j≧0. In the illustrated case, L is selected to equal 8. 
         [0794]    Consecutive frame data blocks of the pure signal  4730  at output of the acquisition module collocated with the augmented content selector  5210  are denoted A 0 , A 1 , . . . , A 0  being the first frame-data block of the pure signal  4730 . The buffer segments are referenced as segment- 0 , segment- 1 , . . . , and segment- 7 . During the first frame period, frame-data block A 0  is written in segment- 0 . During the second frame period, frame-data block A 1  is written in segment- 1 , and so on. During an eighth frame period, frame-data block A 7  is written in segment- 0  (8 modulo L =1), during a ninth frame period, frame-data block A 7  is written in segment- 1  (9 modulo L =1), and so on. With a round-trip transfer delay of five frame periods ( FIG. 54 ), during the first five frame periods, five frame-data blocks A 0 , A 1 , A 2 , A 3 , and A 4  are written in the content buffer but no data is read. During the sixth frame period, frame-data block A 5  is written in segment- 5  and frame-data block A 0  is read from segment- 0  and segment- 0  becomes available for storing a new frame-data block (i.e., A 0  may be overwritten as indicated with the underline). 
         [0795]      FIG. 56  illustrates a second system for combined selective content broadcasting and streaming employing a panoramic camera and a VR headset, the system comprising a routing facility  5620  and a remote content controller  5640  which comprises an acquisition module  4720  and a distant content selector  5240 . The routing facility  5620  communicates with the remote content controller  5640  through a network  5630 .  FIG. 57  details the routing facility  5620  of  FIG. 56 . 
         [0796]    As in the configuration of  FIG. 51 , the 4π camera produces a broadband signal which may be de-warped and/or compressed in source processing unit  4714  then supplied to transmitter  5416  to produce modulated carrier source signal  4712  sent to routing facility through transmission channel  5622 . The routing facility receives the modulated carrier source signal  4712  at input (a) and supplies the signal to a repeater  5710  ( FIG. 57 ) which produces:
       an amplified modulated carrier  5651  directed from output (c) to remote content controller  5640  through a channel  5624 , network  5630 , and channel  5644  from network  5630  to produce an operator-defined content filtered signal; and   an amplified modulated carrier  5652  directed from output (b) to a Universal Streaming Server  120  embedded in a cloud computing network  5670  to produce viewers-defined content-filtered signals.       
 
         [0799]    Control data is sent to the routing facility  5620  through channel  5646 , network  5630 , and channel  5626 . The routing facility  5620  captures the control data at input (d) and a receiver  5770  detects control data from control signals  5270  sent from remote content controller  5640  through network  5630  and channel  5626 . The detected control data is supplied to augmented content selector  5210  which produces an operator-defined content-filtered signal  4764 . The content-filtered signal  4764  is compressed in compression module  4862  and supplied to transmitter  4870  to produce a modulated carrier signal to be directed from output (e) through channel  5628  to broadcasting station  5680  and through channel  5629  to Universal Streaming Server through channel  5629  and network  5630 . 
         [0800]      FIG. 58  details the remote content controller  5640  which comprises an acquisition module  4720  and distant content selector  5240  which includes a virtual-reality headset  4750  used by operator  4725 . A frame-number extraction module  5810  extracts a cyclical frame number from a pure multimedia signal  4730  detected at the acquisition module  4720 . A frame-number insertion module  5812  inserts the extracted cyclical frame number into control data  5270  which define the operator&#39;s preferred view region of the display. A refresh module  5820  collocated with distant content selector  5240  further modifies the control data  5270  as illustrated in  FIG. 53 . 
         [0801]    Alternatively, the process of relating control data (individual control messages)  5270  to video frames identified at module  4715  ( FIG. 56 ) may rely on using “time-stamps” and measuring the round-trip transfer delay between the augmented content selector  5210  ( FIG. 52 ,  FIG. 57 ) and the distant content selector  5240  ( FIG. 52 ,  FIG. 58 ). However, the use of cyclical frame numbers as described above is preferable 
         [0802]      FIG. 59  illustrates a hybrid system for selective content broadcasting of multimedia signals using a panoramic camera, a bank of content filters, and a conventional switcher. The multimedia signals are generated at signal source  4710  which comprises a 4π camera  310  coupled to a source-processing unit  4714  and a broadband transmitter  4716 . The camera captures a panoramic view and produces a raw signal  312  which may be directly fed to broadband transmitter  4716  or supplied to source-processing unit  4714  which processes the raw signal  312  to produce a corrected (de-warped) signal  322 , a compressed raw signal  342 , or a compact signal (de-warped and compressed)  343  as illustrated in  FIG. 3  in addition to inserting other control data. The output of the source-processing unit  4714  is supplied to broadband transmitter  4716 . 
         [0803]    The broadband transmitter  4716  sends a modulated carrier source signal  4712  through the transmission medium  4718  to an acquisition module  4720  which is a hardware entity comprising a receiver  4940 , a processor, and memory devices storing processor-readable instructions which cause the processor to perform functions of de-warping and/or decompression as illustrated in  FIG. 49 . The acquisition module produces a pure multimedia signal  4730  which is fed to a bank  5925  of content filters  5932  configured to provide filtered signals collectively covering the entire view captured by the panoramic camera  310 . The output signal  5940  of each content filter  5932  is fed to a respective display device  4650 . 
         [0804]    A manually operated view-selection unit  4660 , similar to that of  FIG. 46 , selects one of baseband signals fed to the display devices  4650 . An operator  4662  observes all displays and uses a selector (also called a “switcher”)  4664  to direct a preferred output signal  5140  to a transmitter  4680 . The transmitter  4680  is coupled to a transmission medium through an antenna or a cable  4690 . 
         [0805]      FIG. 60  depicts a method  6000  of selective content broadcasting implemented in the system of  FIG. 51 . A panoramic signal source including a stationary 4π camera  310 , source-processing unit  4714 , and a broadband transmitter  4716  is appropriately positioned in the field of events to be covered. A pure multimedia signal  4730  is acquired (process  6010 , acquisition module  4720 ) at a location close to the panoramic signal source through a transmission medium  4718  which can be a broadband wireless channel or a fiber-optic link. The panoramic signal is displayed (process  6020 , internal display of a VR headset and/or display device  4770 ). An operator  4725  inspects the display using a VR headset  4750  (process  6030 ). A content-filtered signal corresponding to the operator&#39;s gaze direction is acquired from said VR head set. The content-filtered signal is compressed (process  6040 , compression module  4862 ) to produce a compressed signal which is transmitted to a broadcasting station (process  6050 , transmitter  4870 ). 
         [0806]      FIG. 61  depicts a method  6100  of selective content broadcasting implemented in the system of  FIG. 59 . As in the method of  FIG. 60 , a panoramic signal source including a 4π camera  310 , a source processing unit  4714 , and a broadband transmitter  4716  is appropriately positioned in the field of events to be covered. A pure multimedia signal  4730  is acquired (process  6110 , acquisition module  4720 ) at a location close the panoramic signal source through a transmission medium  4718 . 
         [0807]    A bank  5925  of content filters  5932  is provided and the pure multimedia signal  4730  is supplied to each content filter  5932 . Each content filters  5932  is configured to extract (process  6120 ) from the panoramic signal a respective filtered signal corresponding to a respective viewing angle. Collectively, the filtered signals cover the entire field of events. Naturally, the viewed portions of the field corresponding to the filtered signals are bound to overlap. The filtered signals are displayed (process  6130 ) on separate display devices. An operator  4662  ( FIG. 59 ) activates a selector (switcher)  4664  to direct a preferred filtered signal to a transmitter  4680  (process  6140 ). The modulated carrier at output of the transmitter is sent to a broadcasting station (process  6150 ). 
         [0808]      FIG. 62  is a flowchart depicting basic processes of the system of  FIG. 48  and  FIG. 51 . In process  6210 , a modulated carrier source signal  4712  is received at a monitoring facility  5120 . In process  6230 , source signal  4712  may be relayed (repeater  4810 ) to a streaming subsystem  4808 . In process  6212 , an acquisition module  4720  acquires a pure multimedia signal  4730  from source signal  4712 . In process  6214 , a content selector  4740  generates an operator-defined content-filtered multimedia signal  4764  intended for broadcasting. The signal may be compressed before transmitting to a broadcasting facility as well as to Universal Streaming Server  120  to be used for a default viewing selection (process  6220 ). 
         [0809]    At the streaming subsystem  4808 , an acquisition module  4720  acquires a replica of pure multimedia signal  4730  which is supplied to the Universal Streaming Server  120  (process  6240 ). The Universal Streaming Server sends a full content signal, preferably at a reduced flow rate as illustrated in  FIGS. 13, 14, and 15 , to client devices  180  communicatively coupled to the Universal Streaming Server  120  (process  6242 ). The Universal Streaming Server  120  may receive a viewing preference from a client  180  (process  6244 ) and produce a respective content-filtered signal (process  6246 ). In the absence of a client&#39;s preference indication, content based on the default viewing selection may be sent to the client. The Universal Streaming Server  120  retains content based on viewers&#39; selections as illustrated in  FIG. 32  in addition to the default viewing selection (process  6248 ). 
         [0810]      FIG. 63  illustrates a method of content-filtering of a panoramic multimedia signal to produce an operator-defined content for broadcasting. The method comprises generating at an acquisition module  4720  ( FIG. 47 ,  FIG. 51 ) a pure signal from a multimedia signal  4712 , ( FIGS. 47, 48, 49, 51 ) received from a panoramic multimedia source  4710  ( FIG. 47 ,  FIG. 51 ) and employing a content selector  4740  configured to extract from the pure signal content-filtered signals corresponding to varying view-regions of a displayed pure signal. 
         [0811]    The content selector  4740  performs processes of employing a virtual-reality headset  4750  ( FIG. 47 ,  FIG. 50 ) to view a display (process  6340 ,  FIG. 63 ) of the pure signal  4730  and determining a current gaze position (process  6344 ) from the virtual-reality headset. 
         [0812]    A displacement  5330  ( FIG. 53 ) of the current gaze position from the reference gaze position is then determined (process  6346 ), the reference gaze position being initialized as a Null value (process  6342 ,  FIG. 63 ). The reference gaze position is updated to equal the current gaze position subject to a determination that the displacement  5330  exceeds a predefined threshold (processes  6348  and  6350 ,  FIG. 63 ). 
         [0813]    View-region definition data are then generated (process  6360 ) using the reference gaze position and a predefined contour shape (such as a rectangle). A content-filtered signal  4764  ( FIGS. 47, 48, 50, 51 ) is extracted from the pure signal  4730  (process  6370 ) according to the view-region definition data and transmitted to a broadcasting facility (process  6374 ,  FIG. 63 ). The content-filtered signal  4764  may be compressed (process  6374 ) before transmission. 
         [0814]    The gaze position is represented as a set of parameters or a vector of multiple dimensions and the displacement is determined as Euclidean distance between a first vector (a first set of parameters) representing the reference gaze position and a second vector (a second set of parameters) representing the current gaze position ( FIG. 53 ). A set of parameters defining a gaze position may be selected as the conventional “tilt, pan, and zoom” parameters acquired from a sensor of the virtual-reality headset. The view-region definition data  6360  may be retained for reuse for cases where the displacement is less than or equal to the predefined threshold (processes  6348 ,  6370 ). 
         [0815]      FIG. 64  and  FIG. 65  illustrate a method of content-filtering of a panoramic multimedia signal implemented in the system of  FIG. 56  where a routing facility  5620 , which may be mobile, is located in the vicinity of the panoramic signal source  4710  and communicates with a remote content controller  5640  which houses a distant content selector  5240  with an operator  4725  wearing a virtual-reality headset  4750 . 
         [0816]      FIG. 64  illustrates processes performed at the remote content controller  5640 . A source signal (a modulated carrier signal)  4712  is received at distant content selector  5240  (process  6410 ). A reference gaze position is initialized as a null position (process  6420 ) so that a first observed gaze position would force computation of a view-region definition. A pure multimedia signal  4730  is acquired from the source signal  4712  at distant content selector  5240  (process  6430 ). 
         [0817]    The acquired pure multimedia signal at distant content selector  5240  is displayed (process  6440 ). A Refresh module  5820  collocated with distant content selector  5240  ( FIG. 58 ) performs processes  6450  affecting the rate of updating view regions. A frame-number extraction module  5810  extracts (process  6452 ) a frame identifier from a pure multimedia signal detected at the acquisition module  4720  of the remote content controller  5640  ( FIG. 58 ). A frame-number insertion module  5812  inserts frame numbers into control data  5270  directed to the augmented content selector  5210 . A preferred frame identifier is a cyclic frame number which is the preferred identifier considered herein. A current gaze position  5320  ( FIG. 53 ) is determined from an output of a virtual-reality headset of the distant content selector  5240  (process  6454 ). 
         [0818]    Process  6456  determines a displacement of the current gaze position  5320  from the reference gaze position. Process  6458  determines whether the displacement exceeds a predefined displacement threshold Δ*. If so, the current gaze position becomes the reference gaze position (process  6470 ) and a control message containing the new reference gaze position together with the corresponding frame identifier is formed (process  6472 ). Otherwise, if the displacement is insignificant, being less than—or equal to—Δ*, process  6474  generates a message containing the corresponding frame identifier and a null gaze position indicating that a frame data block stored in the content buffer  5230  may be displayed according to a previous view-region definition. The control message formed in process  6472  or process  6474  is transmitted (process  6478 ) to augmented content selector  5210 . Due to tracking latency of the virtual-reality headset, a minor shift of the cyclic frame number may be needed. 
         [0819]      FIG. 65  illustrates processes  6500  performed at augmented content selector  5210  residing in the routing facility  5620 . A new gaze position  5320  and a corresponding cyclic frame number  5310  ( FIG. 53 ) are received (process  6510 ) from refresh module  5820  of the remote content controller  5640  ( FIG. 56 ,  FIG. 58 ). Process  6540  selects process  6560  if the new gaze position is a null position. Otherwise, process  6550  is activated to generate and retain a new view-region definition which would overwrite a current view-region definition. The new view-region definition would be based on the new gaze position and a predefined region shape (contour). 
         [0820]    The frame identifier (cyclic frame number) is directed to process  6520  to determine the address of a frame data block  5232  in content buffer  5230  according to the received cyclic frame number  6512 . The frame data block  5232  is read from the content buffer (process  6530 ) and directed to process  6560  to generate a content-filtered signal based on the last view-region definition. A content-filtered signal  4764  is generated in process  6560  based on the latest view-region definition which would be the one generated in process  6550  or a previous view-region definition when a control message includes a null gaze position indicating no change, or an insignificant change, of the gaze position. 
         [0821]    The content-filtered signal may be compressed (process  6562 ) at routing facility  5620  ( FIG. 57 ) supporting the augmented content selector  5210 . The compressed content-filtered signal is transmitted from the routing facility (process  6564 ). New content-selection data (new gaze position and frame identifier) is received from refresh module  5820  (process  6580 ) and the above processes of generating content-filtered signals each frame period are continually executed, possibly at equidistant instants of time. 
         [0822]    It is noted that content filter  4760  ( FIGS. 47, 50 and 52 ), as well as the content filters  5932  ( FIG. 59 ) employ hardware processors and memory devices storing processor-executable instructions which cause the hardware processors to implement respective processes of the present invention. 
         [0823]    Methods of the embodiment of the invention are performed using one or more hardware processors, executing processor-executable instructions causing the hardware processors to implement the processes described above. Computer executable instructions may be stored in processor-readable storage media such as floppy disks, hard disks, optical disks, Flash ROMS, non-volatile ROM, and RAM. A variety of processors, such as microprocessors, digital signal processors, and gate arrays, may be employed. 
         [0824]    In a modification to the embodiments of the invention, the universal streaming server comprise a software, comprising executable instructions stored in a memory device for performing the methods of the embodiments described above, including acquiring multimedia signals, such as panoramic multimedia signals, and generating client-specific content-filtered multimedia signals under flow control. 
         [0825]    Systems of the embodiments of the invention may be implemented as any of a variety of suitable circuitry, such as one or more microprocessors, digital signal processors (DSPs), application-specific integrated circuits (ASICs), field programmable gate arrays (FPGAs), discrete logic, software, hardware, firmware or any combinations thereof. When modules of the systems of the embodiments of the invention are implemented partially or entirely in software, the modules contain a memory device for storing software instructions in a suitable, non-transitory computer-readable storage medium, and software instructions are executed in hardware using one or more processors to perform the techniques of this disclosure. 
         [0826]    It should be noted that methods and systems of the embodiments of the invention and data streams described above are not, in any sense, abstract or intangible. Instead, the data is necessarily presented in a digital form and stored in a physical data-storage computer-readable medium, such as an electronic memory, mass-storage device, or other physical, tangible, data-storage device and medium. It should also be noted that the currently described data-processing and data-storage methods cannot be carried out manually by a human analyst, because of the complexity and vast numbers of intermediate results generated for processing and analysis of even quite modest amounts of data. Instead, the methods described herein are necessarily carried out by electronic computing systems having processors on electronically or magnetically stored data, with the results of the data processing and data analysis digitally stored in one or more tangible, physical, data-storage devices and media. 
         [0827]    Although specific embodiments of the invention have been described in detail, it should be understood that the described embodiments are intended to be illustrative and not restrictive. Various changes and modifications of the embodiments shown in the drawings and described in the specification may be made within the scope of the following claims without departing from the scope of the invention in its broader aspect.