Abstract:
A method and apparatus are disclosed to permit real time, distributed acoustic performance by multiple musicians at remote locations. The latency of the communication channel is reflected in the audio monitor used by the performer. This allows a natural accommodation to be made by the musician. Simultaneous remote acoustic performances are played together at each location, though not necessarily simultaneously at all locations. This allows locations having low latency connections to retain some of their advantage. The amount of induced latency can be overridden by each musician. The method preferably employs a CODEC able to aesthetically synthesize packets missing from the audio stream in real time.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]     This non-provisional patent application claims the benefit under 35 USC 119(e) of the like-named provisional application No. 60/725197 filed with the USPTO on Oct. 11, 2005. 
     
    
     FIELD OF THE INVENTION  
       [0002]     The present invention relates generally to a system for acoustical music performance. More particular still, the invention relates to a system for permitting participants to collaborate in the performance of music, i.e. to jam, where any performer may be remote from any others, using acoustic instruments and vocals.  
       STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT  
       [0003]     Not Applicable  
       REFERENCE TO COMPUTER PROGRAM LISTING APPENDICES  
       [0004]     Not Applicable  
       BACKGROUND OF THE INVENTION  
       [0005]     In U.S. Pat. No. 6,653,545, (&#39;545) Redmann et al. teach a mechanism enabling remotely situated musicians to collaborate using electronic instruments, for instance, commonly available MIDI devices.  
         [0006]     The &#39;545 system operates by intercepting the musical events generated by the locally performing musician, e.g. his MIDI controller&#39;s output stream. These musical events are sent to each of two places: First, and immediately, to all of the remote musicians via a communication channel. Second, to a local delay where the musical event is held for substantially the same amount of time as is required for the communication channel to transport the events to the others. Upon arrival at the remote location(s), and upon expiration of the local delay, the musical event is played at each of the stations; e.g., the MIDI stream is sent to a MIDI sound generator at each location.  
         [0007]     The use of MIDI or similar event-driven representation of a musician&#39;s performance has the strong advantage of representing a compact data format. A dataset produced by such a system is considerably smaller than essentially all other representations of musical performance, including MP3 files.  
         [0008]     However, the &#39;545 system suffers from two significant drawbacks:  
         [0009]     First, there are significantly more musicians for whom the instrument-of-choice is an acoustic instrument and for which they own no acoustic-performance-to-MIDI converter. This is not to say such converters do not exist, for instance MIDI controllers that generate musical events from a musician&#39;s guitar performance are available, such as the G-50 manufactured by Roland Corporation U.S. of Los Angeles, Calif. and the GI-20 manufactured by Yamaha Corporation of America of Buena Park, Calif. MIDI events generated by these devices are best rendered on their companion instrument synthesizers 180, Roland&#39;s XV 2020 and Yamaha&#39;s MU 90R, respectively. Additionally, devices that are played like wind or valve instruments, but generate MIDI controller signals, are also available. However, though the “converter boxes” are easily obtained, they do not represent a significant portion of the guitar and other traditional acoustic instrument population. Moreover, even for musicians who do use MIDI devices, it is frequently the case that their remote jam partners do not have the same MIDI sound generators or software synthesizers. As a result, the remote musicians do not hear the same instrumentation that the originating musician hears and intends.  
         [0010]     Second, while the &#39;545 patent teaches a Voice over Internet Protocol (VoIP) approach to providing an intercom with which participants can talk to each other, this technology is completely unsuitable for vocal performances. The buffering typical of the receiving end of a streaming media implementation adds a relatively large amount of latency—generally in excess of 50 mS and often amounting to several seconds, to allow late packets to take their place in the stream and to provide time for the re-send of a dropped packet to be requested and performed.  
         [0011]     Nonetheless, individuals have attempted long distance jams using VoIP services such as Skype, by Skype Technologies, S.A. of Luxembourg. The results, however, have been reported as musically unsatisfying, primarily because of the latencies encountered.  
         [0012]     A lower latency approach is to use “plain old telephone services” (POTS), which provides a low latency, high reliability transport for audio. Two musicians, each with a speakerphone can jam. Such a solution suffers two primary drawbacks: First, the bandwidth of POTS is limited to a little less than 4,000 Hz. This represents a serious impact to perceived audio quality of music. The second drawback is that, although the latency is typically small, each performer hears the other play ‘behind’ the beat, that is, each hears the other performing late. The result is that in an otherwise unregulated jam, both players will ‘slow down’ to accommodate the other&#39;s tardiness, and the result is an ever-slower tempo. Even if one or the other players has a metronome to govern the beat, the remote player will sound to the metronome-owning musician as if he is playing late by twice the communications channel latency.  
         [0013]     Though today, VoIP services do not typically achieve latencies as low as POTS, that is not expected to remain the case. A number of improvements to Internet packet handling have been defined, and over the coming years will be pervasively fielded. Among these include prioritization for VoIP data packets, so that VoIP data are provided low latency routes, and priority handling by intermediate routers so that packets are not-queued behind, say, file transfers, including music downloads. Such improvements to the Internet protocols will result in VoIP transport latencies approaching that of the POTS systems.  
         [0014]     Currently, because of bandwidth limitations common over network connections such as the Internet, it is desirable for a VoIP connection that the audio to be compressed, or coded. Upon receipt at a remote station, the coded audio signal requires decompression, or decoding. The matched pair of algorithms that COmpresses (or COdes) and DECompresses (or DECodes) a signal in this way is known collectively as a CODEC, and there are many well known CODEC algorithms. CODECs may be implemented in hardware, or software, or a combination of the two.  
         [0015]     Presently, the most popular CODEC for audio is MP3. MP3 achieves a high degree of compression by disregarding information corresponding to attributes of the audio that human beings don&#39;t notice. MP3 is readily able to compress digitized audio to less than a tenth its uncompressed size, and to restore the audio signal to a good facsimile of the original, at least as far as most human listeners are concerned.  
         [0016]     However, many CODECs such as MP3 require all of the original compressed audio stream to be received for reconstruction of a continuous audio signal. There is little the MP3 CODEC can do during an interval for which no representative packet is received: the reconstructed audio will cut out. The Internet is an environment prone to packet loss. To overcome this, when audio is streamed over the Internet (compressed or not), consecutive packets are buffered at the receiving end for a relatively long period of time, such as ten seconds. By requiring that this much audio be accumulated in a buffer before it is played, there is an opportunity for the receiving station to request retransmission of a missing packet, and to still have time for its retransmission and receipt before it is needed.  
         [0017]     However, while a deep receive buffer works well for one-way communication, is not a good solution for acoustic performers collaborating in real time. The additional delay required by the receive buffer will reduce or destroy any real time effect. In order to jam effectively, musicians will require a very short receive buffer and there is not typically time for retransmission of a missing packet.  
         [0018]     In addition to inherent unreliability of packet delivery, networks such as the Internet also have communication latencies that can vary by packet. Packets can even be delivered out of order.  
         [0019]     To resolve these issues, selection criteria for a CODEC should emphasize an ability to continue the real time musical or vocal performance with an aesthetically tolerable handling of dropped or late packets.  
         [0020]     In their article “A Survey of Packet-Loss Recovery Techniques,” IEEE Network Magazine, September/October 1998, author Perkins, et al. describe a variety of methods by which packet loss of an audio stream may be handled. In the context of wireless telephony, they discuss compensation techniques for packet loss in a voice stream as a hierarchy of increasingly sophisticated schemes:  
         [0021]     The simplest scheme when a packet is lost, is just to play silence. If the transmission was significantly silent before when the packet is lost, this may represent a good substitute. This is implemented exclusively by the receiving portion of the CODEC.  
         [0022]     During a vocal or instrumental performance, however, a significant portion of the time a note is being held and undergoing a prolonged decay, or is being sustained. A sudden transition to silence and back again can produce a very unaesthetic pop.  
         [0023]     Perkins, et al. point out that the physiology of human hearing actually reacts better to an interval of white noise, instead of silence, replacing a missing packet. Preferably, the noise has an amplitude similar to that of the prior packet.  
         [0024]     Another crude-but-sometimes-effective scheme sometimes used in telephony is to replay the previous packet. Again, during a relatively quiet portion of the transmission, this will work well. During an unformed, noisy interval, it also works well. This technique is also implemented exclusively by the receiving portion of the CODEC.  
         [0025]     For a vocal performance or an instrumental performance having a slow or moderate tempo, repeating the prior packet may sometimes work well, but audio elements representing a fast attack like a drum beat or a guitar string pluck may sound like the performer has played a second note, which may be more disruptive than noise of a similar amplitude.  
         [0026]     If repetition is employed, and then needed to compensate for multiple consecutive lost packets, then the amplitude used should fade with each repetition. In the case where performance by a musical instrument such as a guitar or piano is used, the rate at which repeated packets are faded preferably resembles the observed decay rate of the instrument&#39;s performance.  
         [0027]     In Perkins&#39; review, they talk about the transmission portion of the CODEC helping compensate for missing packets, too.  
         [0028]     Interleaving is a technique in which data representative of N consecutive intervals is spread over time: Their transmission is interleaved with additional groups of N consecutive intervals. If a single packet is lost, exactly one of the intervals from each group of N consecutive intervals is lost. This can be of value if disguising or overcoming a frequent loss of a single short interval produces a better result than an occasionally loss of N consecutive intervals. Interleaving has the detrimental effect of introducing a receive buffer delay corresponding to (N*N) intervals, but even when N=2, the intervals would need to be very short for this to be tolerable.  
         [0029]     Forward Error Correction (FEC) is another technique the sending portion of the CODEC can use to improve handling of lost or delayed packets. All FEC techniques introduce some redundant data in each packet that can aid in the reconstruction of previously sent but subsequently lost packets. In its simplest version, each packet contains not only its own new data representative of an interval, but fully repeats the data representing the prior packet&#39;s interval. While this introduces a 100% increase the data that must be transmitted, it adds a receive buffer delay of only one interval.  
         [0030]     A number of CODECs intended for VoIP use are commercially available. Each has various parameters, such as sample rate, bandwidth limitations, data rates, strategies for overcoming packet loss, etc. One key parameter is frame size. Frame size is the number of data samples times the sample rate, and is commonly expressed in milliseconds. Large frame sizes provide more opportunity for a CODEC to achieve data compression, but unfortunately result in longer buffering times both at the transmitting and receiving ends of the connection. For real time musical performance, short frame sizes (e.g., 10 mS) are preferred, and known. Some commercially available, short frame size CODECs even support an audio bandwidth exceeding that of an ordinary telephone connection (e.g., &gt;8 k samples/sec). An example is iPCM-wb™ by Global IP Sound of Stockholm, Sweden which can operate with a 10 mS frame size and 16K samples/sec. Between this improvement in bandwidth over a POTS call, and anticipated improvements in transport latencies for VoIP, such a connection would be preferable to a simple POTS connection. However, it still suffers from the musicians&#39; mutual perception of always being late with respect to the beat.  
         [0031]     There remains a need for a way to permit multiple remote acoustic performers to collaborate in real time and over useful distances, such as across neighborhoods, cities, states, continents, and even across the globe.  
         [0032]     There is a further need to enable them to record those collaborations.  
         [0033]     Because of the delays inherent in communication over significant distances, a technique is needed which does not compound that delay.  
         [0034]     Further, there needs to be a way of limiting the adverse effects of excessive delay, and to allow each station to achieve an acceptable level of responsiveness.  
         [0035]     The present invention satisfies these and other needs and provides further related advantages.  
       OBJECTS AND SUMMARY OF THE INVENTION  
       [0036]     The present invention relates to a system and method for acoustic performance, typically with one or more other musicians, that is, jamming, where some of the other musicians are at remote locations.  
         [0037]     Each musician has a station, including an acoustic input, and access to a communication channel. The communication channel might be a POTS or ISDN connection to the telephone network, or a digital connection via DSL or cable modem to the Internet or other local or wide area network.  
         [0038]     When musicians desire a jam session, their respective stations contact each other and determine the communication delays to and from each other station in the jam.  
         [0039]     Subsequently, each musician&#39;s performance is immediately transmitted to every other musician&#39;s station. However, each musician&#39;s own performance is delayed before being played locally.  
         [0040]     Upon receipt, remote performances are also delayed, with the exception of the performance coming from the station having the greatest associated communication channel delay, which can be played immediately.  
         [0041]     The local performance is played locally after undergoing a delay equal to that of the greatest associated network delay.  
         [0042]     By this method, each musician&#39;s local performance is kept in time with every other musician&#39;s performance. The added delay between the musician&#39;s performance and the time it is played, becomes an artifact of the performance environment, much as a musician on a stage hears his own playing from a monitor speaker located some distance away. In live, on-stage performance, the performance is electrically transmitted from a microphone or other pickup to the monitors with negligible delay, however the in-air time-of-flight to the musician&#39;s ears is about 1 mS per foot. Just as a musician standing on-stage some distance from the monitor speaker compensates for the delay imposed, so does a musician “play ahead” or “on top of” the jam beat to compensate for the communication channel delay as presented by the present invention.  
         [0043]     Sometimes, two of the stations may have a low (good) communication delay between them, while others may have a high (bad) delay. In such a case, each musician can choose to have his station disregard high delay stations during live jamming, and to allow performance with only low delays.  
         [0044]     It is the object of this invention to make it possible for a plurality of musicians to perform and collaborate in real time, even at remote locations.  
         [0045]     In addition to the above, it is an object of this invention to limit delay to the minimum necessary.  
         [0046]     It is an object of this invention to incorporate the artifacts of communication delay into the local performance in a manner which can be intuitively compensated for by the local musician.  
         [0047]     It is a further object to permit each musician to further limit delay artifacts, to taste.  
         [0048]     Another object of this invention is to permit the performances to be recorded, without the effects of any bandwidth limitations or dropouts imposed by the nature of the communication channel or CODECs selected.  
         [0049]     These and other features and advantages of the invention will be more readily apparent upon reading the following description of a preferred exemplified embodiment of the invention and upon reference to the accompanying drawings wherein: 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0050]     The aspects of the present invention will be apparent upon consideration of the following detailed description taken in conjunction with the accompanying drawings, in which like referenced characters refer to like parts throughout, and in which:  
         [0051]      FIG. 1  is a detailed block diagram of multiple acoustic performance stations configured to jam over a communications channel;  
         [0052]      FIG. 2  is a detailed block diagram of an audio processor  108  suitable for use with two telephone lines;  
         [0053]      FIG. 3  is a preferred control panel for audio processor  108 ;  
         [0054]      FIG. 4  is a detailed block diagram of an audio processor  108  suitable for use with an Internet connection;  
         [0055]      FIG. 5  is a flowchart for an improved CODEC decoder  428  well suited to real time musical signals; and,  
         [0056]      FIG. 6  is a diagram illustrating the operation of the improved CODEC coder  422  and decoding section  426  for handling musical events. 
     
    
       [0057]     While the invention will be described and disclosed in connection with certain preferred embodiments and procedures, it is not intended to limit the invention to those specific embodiments. Rather it is intended to cover all such alternative embodiments and modifications as fall within the spirit and scope of the invention.  
       DETAILED DESCRIPTION OF THE INVENTION  
       [0058]     Referring to  FIG. 1 , a plurality of acoustic performance stations represented by stations  100 ,  100 ′, and  100 ″ are interconnected by the communication channel  150 . The invention is operable with as few as two, or a large number of stations. This allows collaborations as modest as a duet played by a song writing team, up to complete orchestras, or larger. Because of the difficult logistics of managing large numbers of remote players and commonplace limitations of bandwidth, this invention will be used most frequently by small bands of two to five musicians.  
         [0059]     Note that while the term “musician” is used throughout, what is meant is simply the user of the invention, though it may be that the user is a skilled musical artist, a talented amateur, or musical student.  
         [0060]     Presently, communications channel  150  is preferably a telephone network, though that places substantial limitations on interconnectivity (i.e. station-to-station, or requiring the arrangement of a two-way or conference call) and a limit on audio quality and bandwidth. Alternative embodiments include a local or wide area Ethernet, the Internet, or any other communications medium. However, the bandwidth limitations and uncertain timing of delivery provided by packet switched networks, such as Ethernet or Internet, will have an adverse effect on the quality of the real time performance. As known, present day improvements to the infrastructure of the Internet achieve widespread implementation, the preferred communication channel  150  will become the Internet. For this reason, both telephone and Internet based implementations are disclosed in detail herein.  
         [0061]     In  FIG. 1 , each of remote acoustic performance stations  100 ′ and  100 ″ mirror the elements of local acoustic performance station  10 . Each of acoustic performance stations  100 ,  100 ′, and  100 ″ have performer  102 ,  102 ′, and  102 ″, audio input transducer  104 ,  104 ′,  104 ″, audio output transducer  106 ,  106 ′, and  106 ″, and audio processor  108 ,  108 ′, and  108 ″, respectively. Each of the acoustic performance stations  100 ,  100 ′, and  100 ″ is connected to the communication channel  150 , through which the stations can interconnect.  
         [0062]     Performer  102  is, by way of example, a vocalist or singer whose performance is captured by audio input transducer  104 , a microphone. Vocalist  102  monitors the aggregate performance on audio output transducer  106 , headphones.  
         [0063]     Performer  102 ′is, again by way of example, a performer who uses an acoustic instrument  103 ′, in this case, a saxophonist. The performance by saxophonist  102 ′ is captured by audio input transducer  104 ′, also a microphone. The saxophonist&#39;s audio output transducer  106 ′ is headphones, too.  
         [0064]     Performer  102 ″, a guitarist, uses an electric guitar  103 ″ with audio input transducer  104 ″ comprising an electronic pickup on the guitar. A preamp (not shown) may be needed for such a hookup, which may also include various effects boxes (not shown), all well known to the industry. An instrument such as that of guitarist  102 ″ doesn&#39;t produce a substantially loud performance on its own, unlike the vocalist  102  or saxophonist  102 ′. Thus, guitarist  102 ″ doesn&#39;t require the isolation from the live acoustic performance provided by headphones  106  and  106 ′, and can instead monitor the aggregate performance from audio processor  108 ″ over speaker  106 ″.  
         [0065]     These specific examples of performers are not meant to be limiting, merely illustrative. For example, a performer could sing and play simultaneously, or the performer might be a group, i.e. a choir or several members of a band. A plurality of microphones and/or pickups may be used at a single station, the individual feeds mixed together by additional equipment (not shown) to form a composite feed into audio in  110 .  
         [0066]     Audio processors  108  and  108 ′ comprise audio input  110  and  110 ′, communication channel interface  120  and  120 ′, a timing control  130  and  130 ′, local delay  132  and  132 ′, remote delay  134  and  134 ′, mixer  140  and  140 ′, and audio output  142  and  142 ′, all respectively. Outbound delay  136  is used apply information from timing control  130  to audio sent stations  100 ′ and  100 ″, described in more detail below in conjunction with  FIGS. 2 and 4 . Outbound delay  136 ′ provides a similar service, if needed.  
         [0067]     In reference to audio processor  108 , audio input  110  conditions and feeds the signal from the audio input transducer  104  to both the communication channel interface  120  through outbound delay  136 , and the local delay  132 . The timing control  130  detects the latency conditions to each other station  100 ′ and  100 ″ over the communication channel  150  and sets local delay  132  and remote delay  134  accordingly. The outputs of the two local delay  132  and remote delay  134  are combined by mixer  140 , preferably providing performer  102  with a means to control the level of the audio signals independently. The resulting combined audio signal is provided to audio out  142 , which preferably conditions the signal and provides amplification, as needed.  
         [0068]     Remote delay  134  preferably acts distinctly upon each remote audio signal being received at station  100  from of remote acoustic performance stations  100 ′ and  100 ″.  
         [0069]     A variety of embodiments for an audio processor  108 ,  108 ′, and  108 ″ are contemplated. Embodiments of the audio processor can vary, for example, depending upon the nature of the communication channel  150  or the number of stations  100 ,  100 ′, and  100 ″ participating.  
         [0070]     One embodiment of audio processor  108 , for instance, considers communication channel  150  being a switched telephone network, where the connection from channel interface  120  to the communication channel  150  is made through a telephone jack.  
         [0071]     Channel interface  120  preferably comprises a latching line switch and telephone dial pad to enable audio processor  108  to connect to a like station  108 ′ by allowing the musician  102  to dial the telephone number where the other station  108 ′ is located. Receipt by station  108 ′ of such an incoming call would be initiated by activating a like latching line switch on channel interface  120 ′.  
         [0072]     Once a connection is initiated and accepted, timing controls  130  and  130 ′ interact to determine the round trip latency between the two stations. The timing control  130  of calling station  100  emits a first signal. Coincident with the emission, a first timing measurement is begun. When the first signal is detected by the timing control  130 ′ of receiving station  100 ′, timing control  130 ′ would respond by transmitting in response a second signal back to station  100  and preferably initiating a second timing measurement of its own. Upon receipt of the second signal, timing control  130  concludes the first timing measurement, and thereby estimates round trip time (RTT).  
         [0073]     To enable timing control  130 ′ to estimate RTT, control  130  may acknowledge the response signal from  130 ′ with a third signal. Upon receipt by timing control  130 ′ of this third signal, the second timing measurement is concluded and thereby a measure of RTT by the remote station  100 ′ is obtained.  
         [0074]     In an alternative embodiment, timing controls  130  and  130 ′ are aware of any inherent delay in the process of detecting signals such as the first, second, and third signals. This inherent detection delay is subtracted twice from the RTT measurement.  
         [0075]     Further, station  130 ′ may deliberately introduce a predetermined delay between the time the first signal is detected and the time the second signal is sent. This predetermined delay is subtracted from the RTT measurement and would be used, if needed, to separate the first from the second signal, and the second from the third, as needed to facilitate accurate or reliable measurement.  
         [0076]     Alternatively, timing control  130  would emit no third signal. Once timing control  130  has an acceptable estimate of round trip time, it can cease emitting the periodic first signals. Upon detecting the cessation of the first signals, timing controller  130 ′ begins to emit the periodic first signals and initiates its own second timing measurement, to which timing control  130  responds with its version of the second signals. When received by timing controller  130 ′, the second timing measurement is concluded and the RTT obtained.  
         [0077]     Multiple first and second timing measurements can be made and averaged to obtain a better estimate of RTT by each station.  
         [0078]     Preferably, each of the first, second and third signals provides a well defined mark, such as an abrupt phase shift or change in the width of a stream of pulses, which can be clearly detected and resolved sharply as to its timing.  
         [0079]     Each station  100  and  100 ′ can divide their respective RTT measurements by two to obtain the communication latency.  
         [0080]     With the communication latency established in this manner, timing control  130  preferably sets local delay  132  to value of the communication latency, and the value of the remote delay  134  to zero. Alternatively, performer  102  may specify a preferred delay to timing control  130  that is at least equal to the communication latency. This specified delay is applied to local delay  130 , and the amount by which the specified delay exceeds the actual communication latency is applied to remote delay  134 . This embodiment allows the performer  102  to experience the same performance delay locally, regardless of the actual communication latency, allowing him to practice with the behavior of the system remaining constant. Note that the setting of communication latency  132  has no direct effect on the experience of performer  102 ′ and audio processor  108 .  
         [0081]     In another alternative embodiment, the process of setting local delay  132  and remote delay  134  can be performed manually. The manual procedure would work like this: Local delay  132  is manually set (this control not shown) to a value presumed to be higher than the RTT. A jumper (not shown) is installed to connect the audio OUT  142 ′ to audio IN  110 ′, on remote audio processor  108 ′. The monitor level for the local performance is set to zero for mixer  140 ′, a step necessary to prevent feedback at station  100 ′. With this configuration, performer  102  produces a sound, such as a clap. This sound enters local delay  132  and is held for a ‘long’ time. The sound is simultaneously transmitted to station  100 ′, where it is received, produced at audio OUT  142 ′, and because of the jumper (not shown), routed back to audio IN  110 ′, resulting the sound being returned to station  100 . Upon receipt, the sound is played by audio OUT  142 , and heard on headphones  106 . Some time thereafter, local delay  132  has lapsed, and the locally delayed copy of the sound is played through audio OUT  142  and is also heard on headphones  106 .  
         [0082]     By adjusting the manual setting for local delay  132 , the locally delayed copy of the sound can be moved earlier or later relative to the copy returned from station  100 ′. Manual adjustments are made and the sound is repeated by performer  102 , until the local delay  132  substantially matches the RTT, and the two copies of the sound play essentially simultaneously from audio OUT  142 . At this point, a reading off the manually set local delay control (not shown) would represent the RTT. Performer  106  can divide this reading by two, and report the result to performer  102 ′. Both performers  102  and  102 ′ would then use that halved value as the manually entered setting for local delay  132 .  
         [0083]     In an alternative embodiment, also using the switched telephone network as communication channel  150 , channel interface  120  of station  100  can employ a two-line telephone connection. A more detailed block diagram of audio processor  108  appropriate to this embodiment is shown in  FIG. 2  and the controls provided to performer  102  are shown in  FIG. 3 , both addressed in the following description:  
         [0084]     In the two-line telephone-based embodiment, control box  300  implements audio processor  108 . Input jack  302  comprises a standard socket into which microphone  104  may be plugged to connect with audio IN  110 . Output jack  304  comprises a standard socket into which headphones  106  may be plugged to connect with audio OUT  142 . Two-line phone jack  306  accepts a standard two-line telephone cable  307  to two-line telephone wall jack  308 . Jack  306  and cable  307  implement a connection between channel interface  120  and communication channel  150 , in this case comprising the two-line telephone wall jack  308  and the balance of the telephone network.  
         [0085]     Well known in the art relative to two-line telephony equipment are line select buttons  312  and  314 , for lines one and two, respectively, and hold button  316 . Touch-tone dial pad  310  controls touch-tone generator  226 .  
         [0086]     Preset delay dial  330  accepts the delay preference setting of performer  102 , and overage indicator  332  can illuminate to indicate if the selected preference has been exceeded by the measured latency (half RTT).  
         [0087]     Level controls  320 ,  322 , and  324  are used by performer  102  to adjust mixer  140  to set the volumes of the local performance, and the remote performances of stations  100 ′ and  100 ″, respectively.  
         [0088]     In  FIG. 2 , outbound delay  136  comprises outbound delay for line one  236   a  and outbound delay for line two  236   b,  remote delay  134  comprises remote delay for line one  234   a  and remote delay for line two  234   b,  channel interface  120  comprises both outbound mixers  222   a  and  222   b  and telephone interfaces  224   a  and  224   b,  for lines one and two, respectively throughout.  
         [0089]     Delays such as  132 ,  234   a,    234   b,    236   a,  and  236   b  for use with audio are well known in the art. A common implementation with bucket-brigade analog shift registers, such as represented by the SAD1024 manufactured by EG&amp;G Reticon of Sunnyvale, Calif. circa 1977, however that part is now obsolete. Alternatively, a circuit could be derived from the one suggested by Jim Walker in his article “Low-Cost Audio Delay Line Uses 1-Bit ADC,” Electronic Design, Jun. 7, 2004, Penton Media, Inc., Cleveland, Ohio. In each case, a controllable delay is achieved by varying either the clock rate or shift register length. While such circuits do not provide a high fidelity handling of the audio signal, they are low cost and certainly have adequate performance in conjunction with the bandwidth limitations and noise levels inherent in POTS communications.  
         [0090]     Preferably, however, the variable delays are implemented in software, wherein audio IN  110  digitizes signals it receives, and all subsequent processing by audio processor  108  is carried out substantially in the digital domain. Once audio has been digitized, subsequent processing can either be carried out with specifically arranged hardware gates and registers, or preferably, in software running on a general purpose microprocessor, or digital signal processor. Audio OUT  142  would convert the resulting digital signals from mixer  140  into an analog signal. Communication channel interface  120  may be required to convert signals to and from communication channel  150  to the appropriate domain (analog or digital), as appropriate. Practitioners will recognize that ordinary skill in the art is sufficient for any of these implementations.  
         [0091]     In the two-line implementation of  FIG. 2 , outbound delay  136  is preferably comprised of two separate delays, outbound delay for line one  236   a  and outbound delay for line two  236   b.  Each provides its delayed signal to mixer  222   a  and  222   b  respectively, through which the corresponding signal is send out through interfaces  224   a  and  224   b,  via communications channel  150 , to two remote stations. The inbound signal from the first remote station is received at interface  224   a,  and sent both to remote delay A  234   a,  and also into the mixer  222   b,  so as to be relayed to the second remote station. Likewise, inbound signal from the second remote station is received at interface  224   b,  and sent both to remote delay B  234   b,  and also into the mixer  222   a,  so as to be relayed to the first remote station.  
         [0092]     Use of controls in control box  300  in the two-line telephone embodiment is as follows:  
         [0093]     At station  100 , performer  102  presses first line button  312 . Communication interface  224   a  causes a connection to be made to line one of jack  308 , and a dial tone is heard. Performer  102  dials the telephone number for station  100 ′, using keypad  310 , which produces tones from generator  226 , which are routed through mixer  222   a,  to channel interface  224   a,  resulting in the first call being dialed to the first remote station  100 ′ (see  FIG. 1 ).  
         [0094]     Performer  102 ′ at station  100 ′ answers the call. In the manner described above, station  100  initiates the test to determine communication latency to station  100 ′. Timing control  130  causes the first signal to be automatically generated by tone generator  226 . The first signal proceeds through mixer  222   a  to channel interface  224   a  to station  100 ′, and subsequent detects the arrival of the second signal from station  100 ′ through channel interface  224   a  at tone detector  228 , which notifies timing  130 . The third signal is commanded by timing control  130  to be generated by tone generator  226 , and sent to station  100 ′ immediately upon receipt of the second signal from station  100 ′. The RTT between stations  100  and  100 ′ is established. Dividing the RTT by two to produces the communication latency, X, for those stations.  
         [0095]     As noted above, if there is a known detection latency in tone detector  228 , twice that amount is subtracted from the RTT before dividing to determine X.  
         [0096]     Similarly, if timing controls  130  and  130 ′ incorporate a predetermined hold-off to allow settling time between measurements to mitigate detection error, then that predetermined time is likewise subtracted. Such a hold-off is improves cross-talk immunity in the case where interface  224   a  imperfectly isolates outbound signals from inbound signals.  
         [0097]     Once connected with station  100 ′, performer  102  places the first call on hold by pressing hold button  316 . Channel interface  224   a  switches to an on-hold status.  
         [0098]     A second call is placed by performer  102  by pushing line button  314  to select line  2 . Now, channel interface  224   b  is used, when the musician dials with touchpad  310  and touch-tone signals are generated by tone generator  226  and sent through mixer  222   b  and channel interface  224   b  to cause the connection to be made to station  100 ″. Again, timing control  130  commands signal generator  226  to produce the first signal which is sent now through mixer  222   b  to channel interface  224   b  to station  100 ″. When the second signal is received from station  100 ″, tone detector  228  signals timing control  130 , which recognizes the true measurement of the RTT between station  100  and station  100 ″ and divides by two to get the communication latency, Y, between those stations. However, an additional delay of twice X is introduced before the third signal is sent back to station  100 ″. In this manner, station  100 ″ will measure a RTT of (2*Y)+(2*X), or 2*(X+Y). When station  100 ″ divides its RTT measurements by two, it therefor calculates a communication latency of (X+Y).  
         [0099]     Once the actual latency to both stations  100 ′ and  100 ″ have been established by timing control  130 , timing control  130  preferably takes over management of both calls. Timing control  130  causes line two to be placed on hold, and removes the hold from line one. Now, timing control  130  re-initiates the RTT calculation sequence with station  100 ′, but with the following modification: Upon receiving the second signal from station  100 ′, timing control  130  introduces an additional delay of twice Y before the third signal is sent back to station  100 ′. In this manner, station  100 ′ will measure a new RTT of (2*X)+(2*Y), or 2*(X+Y). When station  100 ′ divides this new RTT measurement by two, it calculates the same communication latency as did station  100 ″, (X+Y).  
         [0100]     Now, timing control  130  has caused remote audio processors  108 ′ and  108 ″ to become configured for this call. Timing control  130  configures outbound delay  136  so that the outbound delay for line one  236   a  introduces an outbound delay of Y, and sets the outbound delay for line two  236   b  to X. Further, remote delay  234   a  is set to Y, or if delay preset control  330  indicates a value higher than (X+Y), then that value less X. Remote delay  234   b  is set to X, except if the delay preset control  330  indicates a value higher than (X+Y), and then that value less Y. Local delay  132  is set to the greater of (X+Y) and the value indicated by delay preset control  330 . If (X+Y) is greater than the value indicated by preset control  330 , then indicator  332  is lit to indicate that the value preset is inadequate.  
         [0101]     A similar setting of the corresponding delays in processors  108 ′ and  108 ″ are made relative to their own controls, except that their baseline outbound delays are zero.  
         [0102]     Alternatively, to rely on a manual setting, local delay  132  may be set to the value indicated by delay preset control  330 , and the user may manually adjust the control  330  to the setting where indicator  332  just extinguishes.  
         [0103]     In this way, the three stations  100 ,  100 ′, and  100 ″ are configured so that all stations not warning with indicator  332  experience a local delay of at least (X+Y), and provides that audio received from any remote station has that same aggregate delay imposed.  
         [0104]     Audio captured from performer  102  by microphone  104  is subjected to an outbound delay for line one of Y at  236   a,  before being sent to station  100 ′ through mixer  222   a  and channel interface  224   a  and experiencing actual communication latency of X, whereupon it arrives with total delay of (X+Y). Similarly, that same audio captured is subjected to an outbound delay for line two of X at  236   b  before being sent to station  100 ″ through mixer  222   b  and channel interface  224   b  and experiencing actual communication latency of Y, whereupon it arrives with the same total delay of (X+Y).  
         [0105]     Audio captured from performer  102 ′ by audio processor  108 ′ is sent without any outbound delay to station  100 . Upon receipt by interface  224   a,  it has thus far suffered an actual communication latency of X. This audio from station  100 ′ is immediately directed through mixer  222   b  and out interface  224   b,  whereupon it experiences the additional communication latency of Y, before arriving at audio processor  108 ″ of station  100 ″. Where upon it is rendered on audio output transducer  106 ″, for performer  102 ″ with an aggregate latency of (X+Y), unless performer  102 ″ has set a higher latency, which would be achieved by audio processor  108 ″ adding a remote delay value (not shown).  
         [0106]     The audio from station  100 ′, received at interface  224   a  having accumulated an actual communication latency of X, is also directed to remote delay  234   a  which provides an additional delay of at least Y, as discussed above. Where upon the audio from station  100 ′ is mixed with the audio produced locally and from station  100 ″ according to the levels set using controls  322 ,  320 , and  324 , respectively, and provided to performer  102  through audio OUT  142  and headphones  106 .  
         [0107]     For the remaining station, audio captured from performer  102 ″ by audio processor  108 ″ is sent without any outbound delay to station  100 . Upon receipt by interface  224   b,  it has thus far suffered an actual communication latency of Y. This audio from station  100 ″ is immediately directed through mixer  222   a  and out interface  224   a,  whereupon it experiences the additional communication latency of X, before arriving at audio processor  108 ′ of station  100 ′. Where upon it is rendered on audio output transducer  106 ′ for performer  102 ′ with an aggregate latency of (X+Y), unless performer  102 ′ has set a higher latency, which would be achieved by audio processor  108 ′ adding a remote delay value at  134 ′.  
         [0108]     The audio from station  100 ″, received at interface  224   b  having accumulated an actual communication latency of Y, is also directed to remote delay  234   b  which provides an additional delay of at least X, as discussed above. Where upon the audio from station  100 ″ is mixed with the audio produced locally and from station  100 ′ according to the levels set using controls  324 ,  320 , and  322 , respectively, and provided to performer  102  through audio OUT  142  and headphones  106 .  
         [0109]     Thus, audio produced by any of performers  102 ,  102 ′, and  102 ″ is provided to the audio output of all of stations  100 ,  100 ′, and  100 ″ with a delay of (X+Y), or more if desired by the corresponding performer.  
         [0110]     In an alternative embodiment, the local delay  132  can impose a delay of less that (X+Y). For a station having non-zero values for the outbound delay  136 , such as station  100  in the scenario described above having values of Y for outbound delay for line one  236   a  and X for line two  236   b,  a local delay of  132  can be reduced from (X+Y) to as little as the greater of X and Y. The amount of this reduction is subtracted from the values of both outbound delays  236   a  and  236   b.  In this way, performer  102  can operate with the advantage of having a lower local delay (equaling the greater of X and Y), but performers  102 ′ and  102 ″ have a longer local delay of (X+Y).  
         [0111]     In still another embodiment, the minimum value for local delay  132  or  132 ′ described above can be overridden by the performer and be reduced below that prescribed by the above description. However, in so doing, the corresponding performer will hear the local performance earlier with respect to the other performances than the other performers hear it. Consequently, their perception may be that he is playing too late, even though his perception is that he is playing in time with the others. This is only tolerable for small values before it has an adverse effect on the collaboration.  
         [0112]     In still another embodiment, communication channel  150  is a switched packet network, such as the Internet, and audio processors  108 ,  108 ′, and  108 ″ comprise computers wherein communication channel interfaces, such as  120  and  120 ′ (the one corresponding to audio processor  108 ″ is not shown), each comprise a broadband connection, such as that provided by a DSL or cable modem.  
         [0113]      FIG. 4  shows such a switched packet network embodiment. Here, rather than entering a phone number for each remote musician, the remote station is designated by an address, in the case of the Internet, as an IP address. Well known in the art, an application implementing station  100  using the Internet would engage an online lobby, common in multi-player computer games, to make it easy for musician  102  to contact and connect with remote musicians  102 ′ and  102 ″. Not shown, but similarly well known, is the lobby server, which would be connected to communication channel  150 . In lieu of the line select buttons  312  and  314  and touchpad  310 , a graphical user interface (GUI, not shown) presents the lobby to each of the community of musicians interested in a collaborative performance. The lobby allows musician  102  to find musicians  102 ′ and  102 ″ with similar interests or appropriate or complementary skills. Lobbies such as these provide an easy forum for initiating a connection, and are strongly preferred over the awkward and error-prone manual entry of the IP address of a participating musician&#39;s remote station. An exemplary library of routines making implementation of lobbies considerably easier is the well known and respected GameSpy SDK by IGN Entertainment, Inc. of Brisbane, Calif.  
         [0114]     Once connected through the lobby, timing control  130  can interact with its counterparts, e.g. timing control  130 ′, on remote stations  100 ′ and  100 ″ through network protocol stack  424 . In a direct analogy to the timing signals of the two-line telephone embodiment, the timing control  130  of station  100  can send a first signal packet directly to the timing control  130 ′ of station  100 ′, and receive a second signal packet in return. This is similar to the well known PING message, but has the advantage of testing the timing of more protocol and application layers. Also, some routers block the popular PING message, and so an alternative is preferred. However, unlike the two-line POTS implementation, communication between stations  100 ′ and  100 ″ are not required to pass through station  100 . For this reason, the worst-case delay for a station is it&#39;s own measurements of X and Y (half the RTT between its first and second remote stations, respectively).  
         [0115]     Further, timing control  130  and its counterparts, such as timing control  130 ′, in remote stations  100 ′ and  100 ″ can initiate a clock synchronization among themselves, so as to provide mutually synchronized timestamps. Such synchronization can be achieved by algorithms well known, such as the network time protocol (NTP). Though not strictly required, since streamed data carries an inherent timing implied by the sample rate, a synchronized timestamp does provide a convenient reference for audio stream synchronization, and is used in the description below:  
         [0116]     The audio performance of performer  102 , captured by microphone  104 , is accepted by audio IN  110  where it is digitized. The resulting digital audio stream is passed to local delay  132 , and outbound delay  136  implemented as buffer  436 , where individual digitized samples, representing for instance 10 mS of the audio stream, are collected into packets. This frame size of 10 mS is a preferred balance point between having a short delay imposed by the packetizing process of buffer  436  which corresponds to an imposed outbound delay, and packet overhead, since each packet requires a certain amount of data to represent routing, handling flags, checksums, and other protocol-mandated required when the Internet (or other network) is used for communication channel  150 . A longer frame size, say 20-30 mS, results in less protocol overhead (50% to 33%, respectively) and therefore lower aggregate bandwidth, but that greater outbound delay is imposed at buffer  436 . Conversely, a shorter frame size, say 5 mS, would lower the outbound delay, but increase the protocol overhead (200%).  
         [0117]     For comparison, the protocol overhead of a UDP/IP packet is 28 bytes, while a 10 mS frame of uncompressed 16 KHz 16-bit audio samples with no dropped packet protection would be 320 bytes, or an overhead of about 8%.  
         [0118]     The packets for each frame may be marked with a timestamp from timing control  130  in buffer  436  as they are packetized. Such a timestamp preferably indicates the current time plus the local delay setting of delay  132 . Thus each packet is marked for when it is intended to be played.  
         [0119]     Preferably, to minimize the bandwidth and/or to improve the resiliency of the transmission versus packet loss, the packet is passed from buffer  436  to coder  422  for encoding. Coder  422  and decoder  428  together comprise a CODEC selected to operate with the frame size imposed by buffer  436  and outbound delay  136 .  
         [0120]     Once processed by coder  422 , the encoded packets are sent to all remote stations  100 ′ and  100 ″.  
         [0121]     Packets are also recorded, preferably unencoded, in outbound packet store  430 . As recorded in store  430 , these packets represent a high fidelity, loss-less record of the performance of performer  102 . When a performance is complete, the files in store  430  and the corresponding stores of remote stations  100 ′ and  100 ″ can be exchanged so that each station is left with a high quality recording of the entire collaborative performance. The timestamps of each packet allow the files corresponding to each station to be synchronized by appropriately aligning the timestamps. Such an exchange of files can be accomplished using well known protocols such as FTP. The manual synchronization of multiple audio tracks is well known from commercially available multi-track audio editing tools.  
         [0122]     However, in the preferred embodiment, an automatic process (connection to network protocol stack  424  not shown) would exchange the files recorded in store  430  and the remote stations, and upon receipt combine them into a single, synchronized, multi-track audio file format, such as Audio Interchange File Format (AIFF) or the WAVE file format, both well known ways to storing multi-track digital audio waveform data.  
         [0123]     Packets received by network protocol stack  424  from remote stations  100 ′ and  100 ″ are provided to decoding section  426 . If necessary, packets from each remote station are separated by demux  427  so that the decoding of a packet from one remote station is influenced only by packets previously received from that same remote station, and so that packet only influences packets subsequently received (or lost) from that same remote station.  
         [0124]     Each packet is processed by decoder  428 , which implements the conjugate process imposed by coder  422 . In case a packet is missing by the time it is required, decoder  428  preferably interacts with synthesizer  429  to create a patch. The patch is a replacement packet that represents a best-guess of an appropriate audio signal to fill-in for the missing packet. The synthesizer  429  preferably operates to minimize the impact of a lost packet. While an existing example of the synthesizer  429  is a burst of noise having an amplitude similar to that of the previous packet, a more musically competent process is described below in conjunction with  FIGS. 5 and 6 .  
         [0125]     After being decoded, packets are provided to remote delay  134 , implemented as a separate remote delay buffer for each remote station  434   a  and  434   b,  for remote stations  100 ′ and  100 ″, respectively. If synthesizer  429  generates a replacement packet in case one is not received, the synthesized packet is placed in the appropriate remote delay buffer  434   a  or  434   b.  If a corresponding packet is subsequently (and timely) received, it is inserted into the appropriate delay buffer  434   a  or  434   b,  overwriting any replacement packets. If a packet is received by a delay  134  after one or more replacement packets have been used, or after its own replacement packet has started to play, a fixup is preferably provided which minimizes the discontinuity as actual data is resumed and replacement, synthesized data is discontinued.  
         [0126]     As audio data in remote delay buffer  134  comes due, it is sent to the mixer  140  and converted into an analog signal by the audio OUT  142 .  
         [0127]     In such an embodiment, controls such as level controls  320 ,  322 ,  324 , delay preset  330 , and indicator  332  can be implemented with by the GUI (not shown), as is well known in the art.  
         [0128]     Preferably, the dwell time of actual audio data in remote delay buffer  134  is minimized. With a perfect network, packets traversing communications channel  150  would have a precise, constant transport time. Data arriving from the remote station having the greatest latency would be decoded and immediately passed through remote delay buffer  134  to mixer  140 . Only the packets coming from a remote station having a lesser associated latency would remain in the remote delay buffer  134  for any significant time.  
         [0129]     However, the present-day Internet is not perfect in that way and packets are subject to varying delays. To minimize the impact of such delays, remote delay buffer  134  will hold packets for an additional amount of time so that a higher percentage of packets arrive in time and a lower percentage of replacement packets are needed.  
         [0130]     While most personal computers come equipped with microphone and earphone jacks and supporting electronics sufficient to implement audio IN  110  and audio OUT  142 , more sophisticated hardware is available, such as the FIREBOX™ manufactured by Presonus Audio Electronics, Inc. of Baton Rouge, La. The advantage of such devices is a higher quality digitization, less conversion noise, the ability to readily support multiple microphones and/or pickups as previously discussed and providing comparably high quality of audio output, plus the availability of software support, for example by the Core Audio APIs provided in the Macintosh operating system by Apple Computer, Inc. of Cuppertino, Calif.  
         [0131]      FIG. 5  is a flowchart showing a preferred process implemented by decoding section  426 .  
         [0132]     Synthesizer  429  implements a mathematical model intended to provide a best-guess prediction of the vocal or instrumental performance by a remote performer when subsequent packets are lost. Thus, if a packet is not lost, a high quality reconstruction from CODEC decoder  428  is used, but if the packet is lost, then the packet is substituted with a synthesized prediction of what the missing packet(s) might have sounded like. Upon resumption of timely received packets, the playback stream is quickly crossfaded from the prediction back to the actual decoded stream. Fidelity drops momentarily, but the packet loss is overcome with a minimum of aesthetic impact.  
         [0133]     Decoder  428  implements decoding process  500 , which is initiated by the receipt of an audio packet from demux  427 . Such a packet will be designated as belonging to a particular audio stream corresponding to a particular one of the remote stations, and the balance of process  500  will take place in reference to that stream.  
         [0134]     If in step  504  the packet is determined to be so aged as to correspond to an interval (frame) which has already passed, or substantially so, then it is discarded in step  506 —the audio playback for the corresponding interval has already been managed by other means. In step  506 , the packet is discarded for playback purposes, however it may inform an extended synthesis process, described below.  
         [0135]     In step  508 , a determination is made whether a previously played packet was synthesized or not. If not, then the currently decoded packet is completely compatible with the prior packet, and processing continues at step  512 .  
         [0136]     However, if the previous packet was synthesized, then it is likely that the synthesis does not precisely agree in phase and amplitude of the corresponding signals. To merely follow a synthesized packet with an actual packet would probably result in an audible click or pop. Instead a fixup is made in step  510 , which blends an additional synthesized packet with the actual packet, to allow a quick, but aesthetically acceptable transition. The resulting ‘crossfaded’ packet is used instead of the unadulterated actual packet.  
         [0137]     In step  512 , the packet is sent to the appropriate remote delay  134 , for example, remote delay buffer  434   a  for packets corresponding to remote station  100 ′.  
         [0138]     If synthesizer  429  is in the process of generating a replacement for the current, or later packet, this is detected in step  514  and in step  516 , the synthesizer is halted and restarted using the current packet as its basis.  
         [0139]     In step  518 , the processing for the received packet concludes.  
         [0140]     Synthesizer  429  executes process  550 . The synthesis process  550  is initiated when synthesizer  429  is provided with an actual packet in step  552 . A separate synthesis process may be active for the stream associated with each remote station.  
         [0141]     The following description also refers to  FIG. 6 . The audio signal as digitized by a remote station and gathered into packets is shown as packets  602 ,  604 ,  606 , and  608 . Only two of these are received at network protocol stack  424  as packets  602 ′ and  608 ′. Gaps  604 ′ and  606 ′ correspond to packets that were never received, or were too late to matter. Upon receipt, the packet is added to the history of the channel in step  554 . This history is used to construct synthetic packets representing a best guess of what the actual packet would have contained (psychoacoustically speaking).  
         [0142]     If the packets are unaugmented by coder  422  with any analysis, in step  556  the data from the decoded packet is transformed using a Short-Time Fourier Transform (STFT), to determine the amplitudes and phases of the frequency components represented in the packet. The STFT is a well known mathematical technique, most commonly seen in voice prints and used in speech recognition processes. The signal in received packet  602 ′ is multiplied by windowing function  610  (in this example, a windowing function having a constant overlap-add for ⅓ of a frame step size), and the Fourier transform of the result is taken to provide real part  620  and imaginary part  630 . Real part  620  represents the amplitudes of the signal&#39;s frequency components, while imaginary part  630  represents the component phases.  
         [0143]     An alternative implementation, appropriate when bandwidth is less expensive than processing power, the STFT is preferably performed by coder  422  and embedded in the packet before sending. In such an embodiment, step  556  merely needs to extract the results of the STFT, rather than actually carry out the STFT function for each remote station.  
         [0144]     Common choices for windowing functions  610  are a Hamming window, with step size  622  of ½ or ¼ of a frame, and a Barlett window, with a ½ frame step size.  
         [0145]     In order to accommodate the fading of the window and to minimize the discontinuities in constructing a prediction of a missing waveform, the synthesizer produces a series of estimates of future packets, and adds those together as follows.  
         [0146]     In step  558 , the imaginary part  630  is incremented by a step size  622 , representing an advance in time of dT. At each distinct frequency in the STFT analysis, a time shift of dT corresponds to a phase shift in the imaginary part  630 . This phase shift is illustrated as new imaginary part  631  (and in subsequent iterations as  632 ,  633 ,  634 ,  635 ,  636 ,  637 , and  638 ). In  FIG. 6 , these phase shifts are illustrations, and do not represent actual calculations.  
         [0147]     In step  560 , using the original real part  620  and the next phase shifted imaginary part  631 , an Inverse Short Time Fourier Transform (ISTFT) is calculated.  
         [0148]     In step  562 , the resulting waveform is added with the appropriate time shift  622  and scale factor to the original packet waveform, contributing to result  640 . The scale factor is a sample-wise reduction that is applied beginning with the sample corresponding to the first sample of (lost) packet  604 . The result is a gradual fade-out. Overlapping window functions  611 ,  612 ,  613 ,  614 ,  615 ,  616 ,  617 , and  618  each shifted by an additional incremental step size  622 , illustrate the effects of this scaling, which produces a mild exponential decay which may be chosen to emulate a typical decay provided in the performance by the chosen instrumentation. The scaling effect provides a gradual fade-out when data is missing, as if whatever instruments were playing at the point where the packet was lost were merely allowed to sound, undamped. This choice will work well for short gaps of missing audio, but, for instance, will not work well to replace rhythms or drum performances.  
         [0149]     In step  564 , as the simulated waveform  642  is accumulated, the current buffer  640  is transferred to the appropriate remote delay buffer with remote delay  134 . If Actual data  602 ′ is available (which it is, in this example) then simulated data  640  will be needed when packet  604  is late. The leading edge of synthesized signal mask  650  is multiplied against synthesized data  640  to get masked synthesized signal  652 , likewise, the trailing edge of received signal mask  660  is multiplied by received signal mask  660  so that received packet  602 ′ becomes the first packet of masked received signal  662 . Before remote delay  134  is more than halfway complete in sending packet  602 ′ to mixer  140 , the decision is made that packet  604  is considered lost, and the transition is begun to synthesized data  642 . The sum of masked received signal  662  and masked synthesized signal  652  provides patched signal  670 , of which the first packet replaces  602 ′ as the source for the next sample to be sent to mixer  140 .  
         [0150]     Meanwhile, lacking a more recent packet being received in step  566 , synthesis process  550  iterates to step  558 . In this iteration, phase shifted imaginary part  632  is calculated in step  558 , a corresponding portion of synthesized signal  642  is computed in step  560 , and each sample of the result is reduced by the appropriate scaling factor in step  562 .  
         [0151]     The scaling factor starts as a value very near to, but less than one, for instance, 0.9992. This factor is applied to all contributions to the first sample of synthesized signal  642  following packet  640 . Each sample thereafter is scaled by a compounding of this value, i.e. 0.9992ˆ2, 0.9992ˆ3, etc., which will produce a gradual, exponential decay. In the case of a coded having a frame size of 10 mS and a sample rate of 16 KHz, the synthesized signal will be 96% faded out in ¼ of a second. Faster or slower fade rates can be selected.  
         [0152]     With each revisit to step  564 , the oldest frame currently updated is re-written to the corresponding buffer in remote delay  134 . In the case of the second iteration involving imaginary part  632 , this is still the first frame of patched signal  670 . Not until the next iteration is the next frame (not outlined) of patched signal  670  sent to remote delay  134 .  
         [0153]     When packet  608 ′ is received, if synthesis process  550  has concluded operations on shifted imaginary part  638 , this will be detected in step  566  and synthesis processing will halt in step  568 .  
         [0154]     The handling of packet  608 ′ is preferably to crossfade back to actual data, rather than simply to insert packet  608 ′ into remote delay  134  an begin playing. The reason is that the synthesized signal will likely not match the actual signal, and the discontinuity would be audible. To overcome this, patched signal  670  is extended throughout the interval allocated to the frame of packet  608 ′. The synthesized signal mask  650  is reduced to zero, a seen on the trailing edge, and the received signal mask  660  is restored to unity, as seen on its leading edge. This allows the synthesized signal to be faded out as the actual signal from packet  608 ′ fades in. Before the end of the frame corresponding to packet  608 ′, the mixer is receiving 100% actual packet data as received and decoded by decoding section  426 .  
         [0155]     As mentioned above in conjunction with step  506 , there is an alternative process for handling packets arrived too late to actually be played.  
         [0156]     In this case, the too-late packet is used as the basis for a parallel synthesized signal. Iterations are performed using this most recent, but too-late packet, and a cross-fade is made as soon as possible giving preference to the synthesis derived from the more recent (but too-late) packet data. Whereas the processes  500  and  550  produce a predictor for missing packets, this parallel synthesis technique with preference given to the most recent, even if late, packet results in a predictor-corrector algorithm which, while not accurately reproducing the envelope of musical notes played, will significantly follow the tonal structure of a musical performance, even with sustained, critically late packets.  
         [0157]     To the extent that a performer specifies excess remote delay  134 , this is an advantage for extended buffering which provides more opportunity for actual data to arrive timely and reduce the need for synthesized data.  
         [0158]     More elaborate recovery techniques can be employed, too, such as those suggested by Lonce Wyse et al. in “Application Of A Content-Based Percussive Sound Synthesizer To Packet Loss Recovery In Music Streaming,” published in the Proceedings of the Eleventh ACM International Conference on Multimedia, 2003, Association for Computing Machinery, Berkeley, Calif. and Iddo Drori et al. in “Spectral Sound Gap Filling,” published in the 17th International Conference on Pattern Recognition (ICPR&#39;04)—Volume 2, pp. 871-874 by the IEEE Computer Society, Washington, D.C. Such techniques as these use much longer histories to estimate the structure of rhythmic contributions and can provide reasonable guesses as to where the next drum beat or note will be struck. As a result, a synthesized packet that corresponds to missing actual packet containing the onset of a drum beat may be more convincingly synthesized.  
         [0159]     Various additional modifications of the described embodiments of the invention specifically illustrated and described herein will be apparent to those skilled in the art, particularly in light of the teachings of this invention. It is intended that the invention cover all modifications and embodiments which fall within the spirit and scope of the invention. Thus, while preferred embodiments of the present invention have been disclosed, it will be appreciated that it is not limited thereto but may be otherwise embodied within the scope of the following claims.