Patent Description:
Media content may include secondary content which enables a viewer to perform a trick mode operation on the media content. However, not all media content includes the secondary content that enables trick mode. When the media content does not include secondary content, a viewer is unable to execute a trick mode operation when viewing media content.

<CIT> discloses systems and methods for obtaining key frames of video content items being viewed by first users and publishing the key frames of the video content items to second users. In general, either prior to playback of a video content item by a first user or during playback of the video content item by the first user, key frame information providing, referencing, or identifying key frames of the video content item is obtained. Each key frame is representative of a segment of the video content item. The key frame information for the video content item is then published such that each key frame is presented to one or more second users while the first user views the corresponding segment of the video content item.

<CIT> discloses systems and methods for performing smooth visual search of media encoded for adaptive bitrate streaming using trick play streams. One example includes transcoding a selected portion of the source video into a portion of trick play stream video for inclusion in a trick play stream using the source encoder, where the portion of trick play stream video is encoded at a lower frame rate and a lower resolution than the source video, writing the trick play stream to a separate container file using the source encoder, and adding an entry to an index that identifies the location of each frame in the portion of trick play stream video within the container file containing the trick play stream.

According to a first aspect of the present invention there is provided a method as specified in claim <NUM>. The method may optionally be as specified in any one of claims <NUM> to <NUM>.

According to a second aspect of the present invention there is provided a system as specified in claim <NUM>. The system may optionally be as specified in any one of claims <NUM> to <NUM>.

Further features and advantages of embodiments, as well as the structure and operation of various embodiments, are described in detail below with reference to the accompanying drawings. It is noted that the embodiments are not limited to the specific embodiments described herein. Such embodiments are presented herein for illustrative purposes only. Additional embodiments will be apparent to persons skilled in the relevant art(s) based on the teachings contained herein.

Provided herein are system, method and/or computer program product embodiments, and/or combinations and sub-combinations thereof, for dynamically generating trick mode data while streaming media content on a media device. A media device uses trick mode data to perform trick mode operations. The trick mode operations include at least fast forward and rewind operations at one or more speeds.

<FIG> is a block diagram of a system <NUM> where example embodiments may be implemented. System <NUM> allows a viewer to perform trick mode operations on the streaming media content that is not enabled for trick mode operations. In an embodiment, the streaming media content is content which is transmitted or streamed over a network, such as the Internet. The streaming media content is also viewed on a streaming enabled electronic device at the same time as the streaming media content is streamed over the network. In an embodiment, the streaming media content may also be stored and viewed later.

In an embodiment, system <NUM> includes a media device <NUM>. Example media device <NUM> may be a portable or non-portable electronic device, such as, a desktop, a laptop, a smartphone, a tablet, a data streaming device, such as, but not limited to, a streaming stick or a streaming player, a television set, a set-top box, or a media player to name a few non limiting examples. Media device <NUM> may also be a portable device that may be transported to different locations and be connected to a television set or another device that receives media content via media device <NUM> and displays the media content at one of these different locations.

In another example, media device <NUM> may be a data streaming device. A data streaming device receives, processes, and provides media content, including streaming media content, over a network for display on a television set or another media enabled display device that has, or is coupled to, a display screen. In yet another embodiment, media device <NUM> may be part of, or integrated with a television or another viewing device.

In an embodiment, media device <NUM> may include computer hardware, including a memory, a processor and a communication interface, as well as combinations and/or sub-combinations thereof, that are described, for example, in detail in <FIG>.

In an embodiment, media device <NUM> receives and/or displays media content <NUM>. Media content <NUM> may be one or more of text, audio, still images, video, etc. In a further embodiment, media content <NUM> may be streaming content. Example streaming content includes multimedia content, such as, movies, television episodes, advertisements, commercials, news, streaming channels, video clips, video games, on-demand video content, music, and photos organized into a video enhanced photo album. Example streaming content also includes audio and Internet content, to name a few examples.

In an embodiment, media device <NUM> utilizes one or more networks, collectively referred to as network <NUM>. In an embodiment, media device <NUM> obtains media content <NUM> using network <NUM>. There may be multiple media devices <NUM> connected to network <NUM>. In an embodiment, network <NUM> may be a wired and/or wireless network, including a network having interconnected computer networks, referred collectively as the Internet. In an embodiment, network <NUM> may include private, public, academic, business, and government networks that includes access to extensive amounts of information and resources. Network <NUM> may also include cellular and/or other communication mediums.

In an embodiment, content server <NUM> is also connected to network <NUM>. Content server <NUM> stores, accesses, processes, and/or distributes media content <NUM> over network <NUM> to, for example, media devices <NUM>. To store media content <NUM>, content server <NUM> may interface with database storage <NUM>. Database storage <NUM> includes non-volatile storage discussed in <FIG>, that is conducive to storing large amounts of information, including, media content <NUM>.

In an embodiment, content sources <NUM> provide media content <NUM> to content server <NUM>. Content sources <NUM> generate, distribute, process, and/or otherwise provide media content <NUM> to content server <NUM> for eventual distribution and viewing using media devices <NUM>. For example, content sources <NUM> may transmit media content <NUM> via network <NUM> to content server <NUM> and database storage <NUM>. Media content <NUM> may then be distributed to media devices <NUM>. In an embodiment, media device <NUM> may request media content <NUM> from content server <NUM>. When content server <NUM> receives a request for media content <NUM>, content server <NUM> may retrieve media content <NUM> and provide media content <NUM> to media device <NUM>. For example, content server <NUM> may request media content <NUM> from database storage <NUM> or content source <NUM>. Once content server <NUM> receives the requested media content <NUM> from database storage <NUM> or content source <NUM>, content server <NUM> transmits media content <NUM> to media device <NUM>.

In an embodiment, media content <NUM> may or may not be trick mode enabled. A trick mode is an ability to fast forward, rewind, pause, or otherwise manipulate media content <NUM> during viewing at one or more speeds. Content source <NUM> may determine whether media content <NUM> is trick mode enabled. For example, content source <NUM> may generate a trick mode file that stores trick mode data before media content <NUM> is distributed to content server <NUM> and streamed using media device <NUM>. A non-limiting example of trick mode data is a chronological timeline made up of image frames that correspond to distinct frames in media content <NUM>. The timeline may be at predefined or variable time intervals. These image frames are reduced in size from a corresponding frame included in media content <NUM>. Content source <NUM> may then store the trick mode data in a trick mode file, or as part of, or together with, media content <NUM> at a location accessible to content server <NUM>.

When media device <NUM> requests media content <NUM>, content server <NUM> transmits the requested media content <NUM> as well as the associated trick mode data to media device <NUM>. The transmission of trick mode data may be out-of-band from media content <NUM>, so that the transmission does not affect streaming or download of media content <NUM>. Example out-of-band transmission may be transmission before media content <NUM> is streamed to media device <NUM> or when media content <NUM> is paused as it is streamed, etc. When media device <NUM> receives a trick mode request (such as a request from a viewer to rewind or fast forward), media device <NUM> accesses the trick mode data and uses the trick mode data to perform trick mode operations (i.e., the requested rewind or fast forward, for example) on media content <NUM>.

In an embodiment where media content <NUM> is not trick-mode enabled, conventional media devices cannot perform trick mode operations on media content <NUM>. In an embodiment, media device <NUM> is able to dynamically generate trick mode data from media content <NUM> as media content <NUM> is being streamed from content server <NUM> to media device <NUM>. Once media device <NUM> dynamically generates trick mode data, media device <NUM> uses the generated trick mode data to perform trick mode operations on media content <NUM>.

<FIG> is a block diagram <NUM> of a media device generating trick mode data from streaming media content, according to an embodiment. Block diagram <NUM> includes media device <NUM>. In an embodiment, media device <NUM> includes a network interface <NUM>. Network interface <NUM> includes a receiver and a transmitter which allow media device <NUM> to communicate with network <NUM>. For example, a transmitter may transmit a request for media content <NUM> to content server <NUM> and a receiver may receive media content <NUM> from content server <NUM>. In another example, network interface <NUM> may include an application interface or an API that formats requests for media content <NUM> and receives media content <NUM>.

In an embodiment, media device <NUM> may include a media content processor <NUM>. Media content processor <NUM> dynamically generates trick mode data as media device <NUM> receives and/or streams media content <NUM>. In one embodiment, to generate trick mode data, media content processor <NUM> retrieves key frames <NUM> from media content <NUM> when, for example, media device <NUM> streams media content <NUM>. Key frames <NUM> are used to generate trick mode data and may be derived from any information in media content <NUM>, including but not limited to, the frames in the encoded video data.

Media content processor <NUM> identifies, selects and/or retrieves key frames <NUM> at predefined time intervals and/or variable time intervals and stores key frames <NUM> as trick mode data in the trick mode data storage <NUM>. Trick mode data storage <NUM> may be a volatile or non-volatile storage on or coupled to media device <NUM>, and may be one of the storages described in <FIG>. Media content processor <NUM> may use network interface <NUM> to upload key frames <NUM> to content server <NUM>. Content server <NUM> then stores key frames <NUM> as trick mode data in database storage <NUM>, and transmits the trick mode data to one or more media devices <NUM> upon request. In an alternative embodiment, the foregoing operations may be performed on a previously streamed media content that is stored in media device <NUM>.

As discussed above, media content processor <NUM> retrieves key frames <NUM> at predetermined time intervals. Example time intervals may be <NUM> or <NUM> seconds. Each key frame may be tagged, or otherwise correspond, to an actual location of a frame in media content <NUM> or the time from the beginning of media content <NUM>.

Media content processor <NUM> uses key frames <NUM> to generate trick mode data. For example, media content processor <NUM> may select all or a subset of key frames <NUM> and store them in a chronological order in a trick mode file or volatile memory storage that exists as long as media content <NUM> is streamed to media device <NUM> and/or for a predefined period thereafter. Media content processor <NUM> may also append the trick mode data with more key frames <NUM> as media device <NUM> continues to stream media content <NUM>. In a further embodiment, media content processor <NUM> may also convert key frames <NUM> to a different format, if needed. For example, media content processor <NUM> may compress key frames <NUM> from the format of media content <NUM> which is used to display media content <NUM> to another less memory intensive format. In another example, media device <NUM> may receive portions of media content <NUM>, where each portion is in a different format. Media content processor <NUM> retrieves key frames <NUM> from the portions of media content that media device <NUM> received in different formats, and converts key frames <NUM> to a common format.

As media content <NUM> streams to media device <NUM>, a user may activate trick mode. For example, a user may use a remote control, a smartphone acting as a remote control, or one or more selections or buttons on media device <NUM> to activate pause, rewind, or fast forward functions at one or more speeds. Such operations are called trick mode operations since they involve trick mode data. When a viewer activates a trick mode on media device <NUM>, media content processor <NUM> may identify a key frame in the trick mode data storage <NUM> or a trick mode data file that is located approximately at the location where the viewer was viewing media content <NUM> when the trick mode was activated. Media device <NUM> then uses trick mode data to perform the trick mode operation.

In another embodiment, as media content <NUM> streams to media device <NUM>, media content processor <NUM> may identify key frames <NUM> based on characteristics of frames in media content <NUM>. For example, media content <NUM> may be encoded using key frames and non-key frames, as illustrated using <FIG>, below.

<FIG> is a block diagram of a media stream <NUM> according to an embodiment. Media stream <NUM> can be media content <NUM> that is streamed to media device <NUM>. In an embodiment, media stream <NUM> is divided into key frames 302a-c and non-key frames 304a-z. Key frames 302a-c and non-key frames 304a-z differ in encoding. For example, key frames 302a-c in media content <NUM> may be encoded without reference to other frames, such as non-key frames 304a-z, and represent a complete frame or an image without relying on preceding or subsequent frames. Non-key frames 304a-z, on the other hand, do not represent a complete image. Instead, non-key frames 304a-z may represent changes or deltas between non-key frames 304a-z and key frames 302a-c. For example, non-key frame 304a is combined with a corresponding key frame 302a to generate a complete image that is shown using media device <NUM>. As shown in <FIG>, there may be multiple non-key frames, such as, non-key frames 304b-d between key frames, such as key frames 302a and 302b.

Key frames 302a-c include an identifier or a descriptor which identifies the frames as key frames 302a-c, and non-key frames 304a-z include an identifier or a descriptor which identifies the frames as non-key frames 304a-z.

Going back to <FIG>, media content <NUM> may be encoded using different compression/decompression or CODEC techniques. Example CODEC techniques include H. <NUM>, MPEG2, H. <NUM>, etc., and all are well-known in the art. In a further embodiment, media content <NUM> may also be streamed from content server <NUM> to media device <NUM> using HTTP Live Streaming, etc. Also, in some embodiments, different portions of media content <NUM> may be physically stored on different content servers <NUM> and also may be encoded using different CODEC techniques when the portions of the media content <NUM> are delivered to media device <NUM>.

In an embodiment, media content <NUM> or a portion of a media content <NUM> encoded and/or delivered using different CODEC and delivery techniques is media stream <NUM> described in <FIG>. In an embodiment, when media content processor <NUM> receives and/or displays media content <NUM>, media content processor <NUM> extracts key frames 302a-c from media content <NUM>. Media content processor <NUM> then stores some or all key frames 302a-c in trick mode data storage <NUM>. In a further embodiment, media content processor <NUM> may select key frames 302a and 302c when media content processor <NUM> determines that the time interval between key frame 302a and 302c is greater than a predetermined time interval, but the time interval between key frames 302a and 302b is less than the predefined time interval. Generally, media content processor <NUM> selects key frames for inclusion into trick mode data such that the selected key frames form trick mode data that is sufficient to perform trick mode operations. Media content processor <NUM> then stores the selected key frames, such as, key frames 302a and 302c in, for example, trick mode file and/or trick mode storage <NUM>.

Going back to <FIG>, media content processor <NUM> reformats key frames <NUM>. In particular, media content processor <NUM> transcodes key frames <NUM> into a different format that is efficient for storing trick mode data and takes up less memory space than the frames in media content <NUM>. Example transcoding may include scaling, changing encoding format, or adding visual enhancements to key frames <NUM>. In a further embodiment, key frames <NUM> may also be selected and saved in a way that optimizes the spacing between key frames <NUM>, such that the spacing between the frames is consistent throughout media content <NUM>.

In a further embodiment, multiple media devices <NUM> may identify key frames <NUM> for the same media content <NUM>. For example, when media content <NUM> is streamed to multiple media devices <NUM>, each media device identifies key frames <NUM> from in media content <NUM>. In this way, multiple media devices <NUM> generate trick mode data for the same media content <NUM>. The generated trick mode data may then be combined using content server <NUM>, another server, or media device <NUM>, in a crowd-sourcing type embodiment.

<FIG> is a block diagram of a system <NUM> including multiple media devices generating trick mode data from the same media content, according to an embodiment. For example, multiple media devices 402a-c receive the same media content <NUM> from content server <NUM>. Content server <NUM> delivers media content <NUM> at the same or different times to media devices 402a-c, or delivers different portions of media content <NUM> to media devices 402a-c. For example, media device 402a may receive media content 404a, media device 402b may receive media content 404b, and media device 402c may receive media content 404c. Media content processors 410a-c process the respective media content 404a-c on media devices 402a-c as media content 404a-c is streamed from content server <NUM>. For example, media content processor 410a retrieves key frames 412a-c, media content processor 410b retrieves key frames 412d-f, and media content processor 410c retrieves key frames <NUM>-j. Notably, key frames 412a-c, 412d-f, and <NUM>-j (even when corresponding to the same content) may be the same or different key frames, as they are generated on different media devices 402a-c.

In an embodiment, media content 404a-c may be transmitted to each of media devices 402a-c in a different format, such that media device 402a receives media content 404a in format 405a, media device 402b receives media content 404b in format 405b, and media device 402c receives media content 404c in format 405c.

In an embodiment, media devices 402a-c may store key frames 412a-c, 412d-f, and <NUM>-j in the respective trick mode data storages 414a-c of the respective media device 402a-c. In another embodiment, media devices 402a-c may transmit key frames 412a-c, 412d-f, and <NUM>-j to content server <NUM> or another crowd sourcing server.

In an embodiment, content server <NUM> also includes a frame processor <NUM>. Frame processor <NUM> receives key frames 412a-c, 412d-f, and <NUM>-j from media devices 402a-c, and selects some or all key frames 412a-c, 412d-f, and <NUM>-j for inclusion into trick mode data. For example, frame processor <NUM> may identify a location of each one of key frames 412a-c, 412d-f, and <NUM>-j in media content <NUM> and selects some or all key frames 412a-c, 412d-f, and <NUM>-j as trick mode data. Frame processor <NUM> may select key frames 412a-c, 412d-f, and <NUM>-j based on the key frames' 412a-c, 412d-f, and <NUM>-j locations in media content <NUM> as well as key frames' location from each other. For example, frame processor <NUM> may select key frames for inclusion into trick mode data, such that key frames 412a-c, 412d-f, and <NUM>-j are located at predefined time intervals from each other.

For example, suppose key frame 412a-c, 412d-f, and <NUM>-j occur in media content <NUM> at a time as shown in a table below:.

In an embodiment where frame processor <NUM> selects a key frame every <NUM> seconds, frame processor <NUM> may select key frames 412a, 412d, 412e, 412f, 412c and <NUM>-j. In another embodiment where frame processor <NUM> selects a key frame every <NUM> seconds, frame processor <NUM> may select key frames 412a, 412e, 412c, <NUM>, and 412j. Frame processor <NUM> stores the selected key frames, such as key frames 412a, 412e, <NUM>, and 412j in chronological order as trick mode data <NUM>, using, for example, trick mode data file or another form of storage. In an embodiment, content server <NUM> may store trick mode data <NUM> in a memory included or coupled to content server <NUM>.

In a further embodiment, media content processors 410a-c may also select some or all key frames from the respective key frames 412a-c, 412d-f, and <NUM>-j, as described above, before transmitting the selected key frames to content server <NUM>.

In an embodiment, either media content processors 410a-c or frame processor <NUM> may also modify the format of key frames 412a-c, 412d-f, and <NUM>-j as discussed above, such that key frames included in trick mode data <NUM> are in the same format.

In an embodiment, when media device 402a receives a trick mode request from a viewer, media device 402a may transmit the trick mode request (or a request for trick mode data relating to the rick mode request) to content server <NUM>. In response to the request, content server <NUM> may transmit trick mode data <NUM> to media device 402a. Once received, media device 402a implements the trick mode operation using the received trick mode data <NUM>.

<FIG> is a block diagram of a system <NUM>, where a media device performs a trick mode operation using trick mode data, according to an embodiment. In system <NUM>, a trick mode operation may be performed using trick mode data obtained on a media device <NUM> and/or content server <NUM> via network <NUM>.

For example, trick mode data 510a may be obtained as described in <FIG> and stored in memory included or coupled to content server <NUM>. Media device <NUM> may stream media content <NUM> and dynamically generate trick mode data 510b. In another embodiment, trick mode data 510b may also be downloaded to media device <NUM> out-of-band from media content <NUM>, and stored in the memory included in media device <NUM>.

When a viewer initiates a trick mode operation, media device <NUM> may use a combination of trick mode data 510a and 510b to perform the trick mode operation. For example, media device <NUM> may use trick mode data 510b to perform a rewind operation. And, media device <NUM> may use trick mode data 510a to perform a fast forward operation when trick mode data 510a includes portions of media content <NUM> that has not yet been streamed to media device <NUM> and are not available using trick mode data 510b. In this embodiment, when media device <NUM> receives a fast forward request, media device <NUM> determines whether trick mode data 510b includes key frames that are beyond the point in time where media content <NUM> has been streamed to media device <NUM>, and requests trick mode data 510a from content server <NUM>. Once media device <NUM> receives trick mode data 510a, which may be out-of-band with media content <NUM>, media content processor <NUM> identifies the location in trick mode data 510a from where to begin the fast forward operation, and performs the fast forward operation using trick mode data 510a. In a non-limiting embodiment, media content processor <NUM> may identify the location in trick mode data from where to perform the fast forward operation by comparing the identifier of a key or non-key frame in media content <NUM> when trick mode operation was requested to an identifier of a frame in trick mode data 510a.

In yet another embodiment, media device <NUM> may receive a pause request from a viewer. In response, media device <NUM> may pause the viewing of media content <NUM>. To pause media content <NUM>, media device <NUM> may continue to stream media content <NUM> but also temporarily store media content <NUM> received after the pause request in the memory (such as volatile cache memory) of media device <NUM>. In this way, the pause functionality may be transparent to content server <NUM>.

In an embodiment, media device <NUM> may continue to generate trick mode data during the pause. For example, while media device <NUM> pauses media content <NUM>, media content processor <NUM> may continue to retrieve key frames from media content <NUM> and store these key frames as trick mode data 510b. In this way, when media device <NUM> receives a fast forward trick mode command, media device <NUM> may use trick mode data 510b, or a combination of trick mode data 510a and 510b to perform a fast forward operation. In yet, another embodiment, media device <NUM> may use trick mode data 510b to perform a rewind operation.

<FIG> is a flowchart of a method <NUM> for dynamically generating trick mode data, according to an embodiment.

At operation <NUM>, a media device receives media content. For example, network interface <NUM> receives media content <NUM> from content server <NUM>. As discussed above, media content <NUM> can be streaming video content which media device <NUM> streams and displays in real-time.

At operation <NUM>, key frames are identified. For example, as media device <NUM> streams media content <NUM>, media content processor <NUM> identifies key frames <NUM>. As discussed above, media content processor <NUM> may identify key frames <NUM> based on predetermined or variable time intervals. As also discussed above, media content processor <NUM> may identify key frames <NUM> as frames in media content <NUM> that generate an image independent of other frames.

At operation <NUM>, key frames are converted into trick mode data. For example, media content processor <NUM> converts key frames <NUM> from the format associated with media content <NUM> into a trick mode format. To convert key frames <NUM>, media content processor <NUM> may convert a key frame into a different format and/or select a subset of key frames <NUM> such that trick mode data includes key frames in chronological order and at predefined or variable time intervals.

At operation <NUM>, trick mode data is stored. Media content processor <NUM> uploads the trick mode data to content server <NUM>.

At operation <NUM>, multiple media devices receive the same media content. For example, media devices 402a-c receive media content 404a-c from content server <NUM>, where media content 404a-c is the same media content <NUM>.

At operation <NUM>, each media device identifies key frames. For example, media device 402a identifies key frames 412a-c, media device 402b identifies key frames 412d-f, and media device 402c identifies key frames <NUM>-j, which may be the same or different key frames.

At operation <NUM>, each media device transmits its respective key frames to a content server or another crowd server. For example, media device 402a transmits key frames 412a-c to content server <NUM>, media device 402b transmits key frames 412d-f to content server <NUM>, and media device 402c transmits key frames <NUM>-j to content server <NUM>. Prior to transmission, media devices 402a-c may also convert the respective key frames 412a-c, 412d-f, and <NUM>-j to a different format, as described above.

At operation <NUM>, the content server converts the key frames into trick mode data. For example, frame processor <NUM> selects a subset of key frames from key frames 412a-c, 412d-f, and <NUM>-j as trick mode data <NUM>. Frame processor <NUM> may also change the key frames selected as trick mode data <NUM> into a common format and store trick mode data <NUM>.

<FIG> is a flowchart of a method <NUM> for performing a trick mode operation, according to an embodiment.

At operation <NUM>, a trick mode is activated. For example, media device receives a request from a user to perform a trick mode operation.

At operation <NUM>, media device accesses or retrieves trick mode data. For example, media device <NUM> may retrieve trick mode data 510b stored within media device <NUM>, or retrieve trick mode data 510a from content server <NUM>. In an embodiment, media device <NUM> may retrieve trick mode data 510a when media content processor <NUM> determines that the requested trick mode operation cannot be performed using trick mode data 510b.

At operation <NUM>, a trick mode operation is performed. For example, media device <NUM> performs the trick mode operation using the trick mode data 510a, 510b, or 510a-b.

Various embodiments can be implemented, for example, using one or more well-known computer systems or one or more components included in computer system <NUM> shown in <FIG>. Computer system <NUM> can be any well-known computer capable of performing the functions described herein.

One or more processors <NUM> may each be a graphics processing unit (GPU). In an embodiment, a GPU is a processor that is a specialized electronic circuit designed to process mathematically intensive applications. The GPU may have a parallel structure that is efficient for parallel processing of large blocks of data, such as mathematically intensive data common to computer graphics applications, images, videos, etc..

Computer system <NUM> also includes a main or primary memory <NUM>, such as random access memory (RAM). Main memory <NUM> may include one or more levels of cache. Main memory <NUM> has stored therein control logic (i.e., computer software) and/or data.

Removable storage unit <NUM> may be a floppy disk, magnetic tape, compact disk, DVD, optical storage disk, and/or any other computer data storage device.

According to an exemplary embodiment, secondary memory <NUM> may include other means, instrumentalities or other approaches for allowing computer programs and/or other instructions and/or data to be accessed by computer system <NUM>. Such means, instrumentalities or other approaches may include, for example, a removable storage unit <NUM> and an interface <NUM>. Examples of the removable storage unit <NUM> and the interface <NUM> may include a program cartridge and cartridge interface (such as that found in video game devices), a removable memory chip (such as an EPROM or PROM) and associated socket, a memory stick and USB port, a memory card and associated memory card slot, and/or any other removable storage unit and associated interface.

In an embodiment, a tangible apparatus or article of manufacture comprising a tangible computer useable or readable medium having control logic (software) stored thereon is also referred to herein as a computer program product or program storage device. This includes, but is not limited to, computer system <NUM>, main memory <NUM>, secondary memory <NUM>, and removable storage units <NUM> and <NUM>, as well as tangible articles of manufacture embodying any combination of the foregoing. Such control logic, when executed by one or more data processing devices (such as computer system <NUM>), causes such data processing devices to operate as described herein.

Based on the teachings contained in this disclosure, it will be apparent to persons skilled in the relevant art(s) how to make and use embodiments of the invention using data processing devices, computer systems and/or computer architectures other than that shown in <FIG>. In particular, embodiments may operate with software, hardware, and/or operating system implementations other than those described herein.

It is to be appreciated that the Detailed Description section, and not the Summary and Abstract sections (if any), is intended to be used to interpret the claims. The Summary and Abstract sections (if any) may set forth one or more but not all exemplary embodiments of the invention as contemplated by the inventor(s), and thus, are not intended to limit the invention or the appended claims in any way.

While the invention has been described herein with reference to exemplary embodiments for exemplary fields and applications, it should be understood that the invention is not limited thereto. Other embodiments and modifications thereto are possible, within the scope of the appended claims. For example, and without limiting the generality of this paragraph, embodiments are not limited to the software, hardware, firmware, and/or entities illustrated in the figures and/or described herein. Further, embodiments (whether or not explicitly described herein) have significant utility to fields and applications beyond the examples described herein.

Also, alternative embodiments may perform functional blocks, steps, operations, methods, etc. using orderings different than those described herein.

References herein to "one embodiment," "an embodiment," "an example embodiment," or similar phrases, indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic.

Claim 1:
A method, comprising:
receiving media content (<NUM>, <NUM>, <NUM>) on a media device (<NUM>, <NUM>, <NUM>) from a content server (<NUM>, <NUM>, <NUM>), wherein the media content (<NUM>, <NUM>, <NUM>) includes key frames (<NUM>) that include a descriptor that identifies the frames as key frames (<NUM>), and non-key frames (<NUM>) that include a descriptor that identifies the frames as non-key frames (<NUM>);
identifying, by the media device (<NUM>, <NUM>, <NUM>), a plurality of key frames (<NUM>, <NUM>) from the key frames (<NUM>) included in the media content (<NUM>, <NUM>, <NUM>) as the media content is streamed using the media device (<NUM>, <NUM>, <NUM>);
converting, by the media device (<NUM>, <NUM>, <NUM>), the plurality of key frames (<NUM>, <NUM>) into trick mode data during the streaming, wherein the trick mode data enable a trick mode operation to be performed on the media content (<NUM>, <NUM>, <NUM>), wherein the trick mode operation includes a fast forward operation, a rewind operation, or a pause operation, and wherein converting the plurality of key frames into the trick mode data includes transcoding at least one key frame of the plurality of key frames (<NUM>, <NUM>) into a format different from a format for the at least one key frame; and
uploading, by the media device (<NUM>, <NUM>, <NUM>), the trick mode data including the at least one transcoded key frame to the content server (<NUM>, <NUM>, <NUM>), wherein the content server (<NUM>, <NUM>, <NUM>) is configured to provide at least some of the trick mode data to a second media device,
wherein the identifying the plurality of key frames (<NUM>, <NUM>) comprises selecting the plurality of key frames (<NUM>, <NUM>) from the key frames (<NUM>) included in the media content (<NUM>, <NUM>, <NUM>) at predetermined time intervals, and
wherein the converting further comprises reducing a size of the plurality of key frames (<NUM>, <NUM>).