JP3946251B2 - Compressed digital data interactive program system. - Google Patents

Description

Background of the Invention
1.Field of Invention
The present invention relates generally to interactive response systems, and in particular using compressed digital data having two or more video signals on a broadcast channel, multiplexed signals in a digital format, or both. The present invention relates to an interactive television system that provides interactive programming. The present invention also provides a video signal while viewing the first video signal even though the switched video signal may be on a different broadcast channel or on the same channel multiplexed with the currently viewed video signal. Related to seamlessly switching between.
2.Description of prior art
Interactive systems are well known in the art. It has been found that interactive activity can be simulated by synchronizing parallel tracks of information storage media and correlating the contents of the various tracks. For example, US Pat. US Pat. No. 3,947,972 discloses the use of time-synchronized multitrack audio tapes for storing educational conversations. One track is employed to relay educational queries to the user, and the remaining tracks are selectable by a switching mechanism and used to send a response message.
These systems have evolved into interactive television where multiple broadcast or cable channels are switched in response to user selection to provide interactive operation. U.S. Pat. US Pat. No. 4,847,700 discloses an interactive television system in which a common video signal is synchronized to multiple audio channels to provide content related to user selectable responses. U.S. Pat. 4,264,925 discloses the use of a conventional cable television system to develop an interactive system. Standard television channels with time-synchronized content are broadcast to multiple users. Each user switches between channels in response to a query to provide interactivity.
These systems are tailored to include memory capabilities, so they can be more interactive and individually responsive, and customized messages can be sent to various categories of users in response to notification queries. Can be given against. Freeman's US Inquiry No. US Pat. No. 4,602,279 discloses using a memory to store a demographic profile of a television viewer. This information is stored for later recall, for example, to provide a specific promotion of the target. Prior art interactive television systems generally provide only one signal per channel (ie, one video signal) regardless of whether the channel is on cable television, broadcast television, or a VCR. It was about. As cable channels are increasingly used for normal programming, cable and broadcast television channel capacity will be limited, and interactive systems of the type described require multiple channels. Thus, it is desirable to reduce the channel capacity required for such a system while still providing at least the same level of interactivity. The disadvantages of the prior art are overcome by the present invention which provides an interactive television system that employs multiple time-synchronized and content-related video signals on one or more broadcast channels.
Summary of the present invention
The present invention is an interactive cable television system that utilizes a digital video signal to provide a customized program (in accordance with individual preferences) in response to a user selection. Standard cables or direct broadcast satellite television distribution networks are utilized to transmit interactive and other programming to the user. The present invention allows multiple viewers to simultaneously provide a plurality of different program information message signals related to each other in time and content. The interactive program includes a plurality of video signals that are related to each other in time and content.
The video signal is converted to a digital format for transmission. In digital format, it is possible to transmit more than one video signal per cable television channel. Furthermore, it is possible to transmit the video signal via a normal telephone line. If desired, various digital video signals can be compressed prior to transmission. With compression, a larger number of video signals can be transmitted over the channel of the transmission medium. The multiplexer combines the various video signals into a reduced number of transmission data streams for transmission. Various NTSC television channels can be assigned in a predetermined manner to maximize the number of signals that can be transmitted simultaneously. The multiplexer, in conjunction with the television transmission system, multiplexes the desired data stream onto the desired channel and transmits these signals over the NTSC channel. The number of video signals that can be multiplexed onto a data stream on a single transmission channel will vary depending on the video signal to be transmitted. A television channel containing a multiplexed video signal data stream may be transmitted via a standard cable television distribution network or a direct broadcast satellite transmission system. The receiver receives one or more television channels, some or all of which include a multiplexed data stream of video signals or a plurality of unmultiplexed digital video signals. The receiver, in conjunction with the signal selector, selects a specific data channel / data stream for playback and then selects a specific video signal from the multiplexed signal of that data stream. Finally, the video signal is decompressed if necessary for playback to a television monitor. The multiple selection controller operates to control the receiver and the signal controller and selects a particular video signal for playback. If more than one channel is received, the multiple selection controller can be programmed to map different channels and multiple signals thereon over a series of numeric channel displays to simplify use by the user. The signal selector includes the necessary decompression device that matches the compression scheme used.
In fact, the user selects the desired interactive program to view. Using the multiple selection controller, the user responds selectably to an information display or inquiry message, and the signal selector selects a particular multiplexed video signal and demultiplexes the selected video signal. , Stretch and display. Alternatively, the signal selector may select a video signal based on personal profile information stored in memory.
When more signals are needed for an interactive program than could be mapped to a data stream on a single channel, the signal selector is associated with the receiver in the multiplexed data stream. Are programmed to switch between the various video signals as well as between the data streams between the various broadcast channels to provide the required level of interactivity.
The various information segments in the various video signals are preferably related to real time and content so that as the video signal is played, an interactive conversation can occur and the user responds to various queries on the video signal. Using multiple signals per channel is what many types have been disclosed in the previously mentioned U.S. patents, including many synchronized camera angles of fields from sports events, or interactive game shows. Can be used for interactive programs. However, the present invention also covers the use of various video signals not related to real time and content.
In a bidirectional embodiment, various signals including interactive programs can be switched at the headend rather than at the receiver. This embodiment may be used in cable television systems, direct broadcast satellite systems, conventional telephone systems modified to receive digital video signals, or any other suitable transmission capable of sending digital video signals. Can be used in the system. The multiple selection control unit, rather than a handheld multiple selection controller, relays the user's multiple selection selection via a relay box back to a remotely located switching station, preferably a cable television source, Select the desired video signal. Multiple selection selection can be relayed to the switching station in any conventional means such as bi-directional cable television, telephone, FM transmission. If interactive programming is sent over the telephone line, the multiple selection selection is relayed back over the same telephone line. The switching station receives the user's multiple selection selection and routes the correct signal down the appropriate cable channel, telephone line, or other transmission medium for the particular user. In such a configuration, only a single link is required between the subscriber or receiver and the headend, so using a single channel link to relay from the receiver to the video switch at the headend. Depending on the interactive selection made, a plurality of different channel selections can be received.
If desired, to send the user demographic data back to the programming source for commercial reasons, or for example, to allow an interactive game show player to win prizes Bidirectional links can be used for other purposes.
The system of the present invention allows for improved performance during switching and makes channel switching transparent. When channel changes are required by user response to the interlude of the dialogue, a slightly perceptible delay is programmed to provide an opportunity for the decompression algorithm to coordinate rapid changes from one video signal to another. The
During the delay, the previously obtained video information is displayed, while the interactive system places, receives, demultiplexes, decompresses, decodes and processes new video signals. This allows the interactive system to switch to the new video signal without flicker or distortion appearing on the TV screen, i.e. without seams.
Various methods have been disclosed to achieve this seamless switching. One includes an analog video frame buffer. Another uses two tuners. Other alternatives are (a) using two digital video buffers, (b) using a large memory, (c) using a large buffer in an embodiment similar to that of (b), and (D) including switching at the cable headend.
[Brief description of the drawings]
FIG. 1 is a block diagram of the interactive television system of the present invention.
FIG. 2 is a block diagram of the system of the present invention in a bidirectional transmission configuration.
FIG. 3 is a block diagram of one embodiment for achieving seamless switching between video signals.
FIG. 4 is a block diagram of an alternative embodiment for achieving seamless switching between video signals.
FIG. 5 is a block diagram of another embodiment for achieving seamless switching between video signals.
FIG. 6 is an alternative method of achieving seamless switching by using the memory shown in FIG. 5 as a buffer.
FIG. 7 is an alternative embodiment that achieves seamless switching by switching channels at the cable headend.
DESCRIPTION OF PREFERRED EMBODIMENTS
The present invention is an interactive television system in which multiple viewers are simultaneously provided with multiple different program information message signals. A plurality of video signals 1 are provided. The video signal 1 can be, for example, various fields of a sporting event and / or a synchronized camera angle of audio, or a game show with content and host that is responsive to user selections. As an alternative, video signal 1 is disclosed in US Pat. 4,847,700, no. 3,947,972, no. 4,602,279, no. 4,264,925, no. It can be any video signal suitable for interactive conversation, such as the video signal described in US Pat. There are various types of video signals associated with time and content that are suitable for interactive operation. In previous systems, these various signals will be transmitted to the receiver on separate broadcast or cable channels. Each of the channels requires a separate 6 Mhz NTSC channel. In accordance with the present invention, video signal 1 is routed to an analog / digital ("A / D") converter 2, which converts the various video signals to digital format for transmission. The A / D converter 2 may be any ordinary type for converting an analog signal into a digital signal. An A / D converter may not be required for each video signal 1, but a smaller number of converters can be used, or even a single converter can digitize various video signals 1. is there. Interactive video programs can also be supplied in a pre-digitized and / or pre-compressed format on a cable or other distribution network.
Digital conversion produces very large amounts of data. Therefore, it is desirable to reduce the amount of data to be sent so that more signals can be sent over a single transmission channel. For example, a single frame of digitized NTSC video represents more than 350 kilobytes of data. Thus, a two hour standard video is about 80 gigabytes. Since such video is 30 frames / second, the data rate is 22 megabytes / second. This large amount of data is preferably reduced by digital compression.
In order to reduce data transfer requirements, the various digital video signals are preferably compressed before transmission. The video can be compressed by any conventional compression algorithm. The two most common types are the “processor emphasized type” and the “memory emphasized type”.
The processor-enhanced method eliminates the non-changing aspect of a picture from processing in frame-to-frame transfer of information, and a given motion in a picture to the human eye Compression is performed through other manipulations of picture information, including mathematical calculations that determine the perceptible degree. This method depends on the high speed processing capability at the transmission point. The memory method includes dividing a picture frame into hundreds of lowercase blocks of pixels, where each block is given a code representing a set of color and intensity changes. The code is an information that is much smaller increments than all the information that would describe a picture of a given block, but is sent to the receiver. This code then calls the same coded block from a library of blocks stored in the receiver's memory.
Thus, the bit stream represents a much smaller portion of picture information in this way. This system is generally limited by the type of picture block that can be stored in the receiver, which type is directly related to memory size and microprocessor capability.
Examples of commonly known compression techniques that can be used with the present invention are JPEG, MPEG1 and MPEG2.
A data compressor 3 is provided to reduce the data for each video signal that must be transmitted. Data compressor 3 may be any conventional type commonly known in the art for compressing video images, such as those described above. The compression of the various video signals can be done by a data compressor 3 which is fewer than one compressor per video signal. In a typical analog NTSC system, it is common to transmit one video signal per 6 MHz, for example. By digitizing a video signal, it is possible to send a data stream containing two or more video signals per channel. Compressing the digitized signal allows more video signals to be transmitted over a single transmission channel. The number of signals that can be sent over a single channel is typically, for example, a) the type of video being sent, b) the video compression scheme used, c) the processor and memory capabilities used, and d) the transmission channel. Related to bandwidth. Compression techniques take advantage of very little change from frame-to-frame in moving images. By editing the redundancy between frames and coding the exact change, a very high compression rate is possible. Thus, the type of video that usually includes very high speed movement, such as occurs in a live sports event, has the lowest compression rate. On the other hand, movies that usually have lower frame rates and fewer frame-to-frame changes than live sports events will achieve higher compression rates. Currently known compression schemes are compressions that vary from 2: 1 to 10: 1 for satellites and 2: 1 to 5: 1 for cable television systems, depending on the degree of motion. Have a rate.
Once the various video signals 1 are digitized and compressed, the multiplexer 4 combines the various digital signals for transmission into a reduced number of transmitted data streams. For example, 68 NTSC channels are available and each channel is digitized and compressed with four slowly moving video signals (eg movies) or two digitized and compressed high speed video signals (eg sports ), The various NTSC channels should be assigned in a predetermined manner to maximize the number of signals that can be transmitted simultaneously.
As an example, the broadcast frequency corresponding to the first NTSC channel may include a separate digitally compressed non-interactive movie data stream. At this frequency, the data stream will contain a video signal representing the number of movies. However, the video signal is similar to the video signal of an interactive program and is not related to time and content. The frequency corresponding to the second channel may comprise a digital data stream of an interactive sports program consisting of two compressed high speed video signals, preferably related to time and content. The frequency corresponding to the third channel may include an interactive movie digital data stream consisting of four multiplexed and compressed video signals related to time and content. The frequency corresponding to the fourth channel may include an analog NTSC signal associated with local programming. Thus, using the present invention, the four NTSC channels may include one channel for multiplexed movies, interactive sports programs, interactive movies, and local programming.
Multiplexer 4 receives the incoming compressed and digitized video signals, and in a predetermined normal manner, in connection with transmitter 5, multiplexes the desired video signals onto the desired channels and Transmit via NTSC channel. Some NTSC channels may contain only one video or other signal in analog or digital form.
As indicated previously, the number of video signals that can be multiplexed onto a data stream on a single transmission channel will vary. Also, the number of channels that use the data stream can vary. The transmission data stream is transmitted by the transmitter 5 via the transmission medium 6 to the receiving station 7. The transmitter 5, the transmission medium 6 and the receiving station 7 may be any one for transmitting digital video signals, including broadcast television, cable television, direct broadcast satellite, optical fiber, or any other transmission means. It can be a normal means. Alternatively, the present invention can be incorporated into a stand-alone system as described below.
The transmitting means may also be a telephone system that transmits a digital video data stream. Thus, a multiplexed data stream containing interactive programs with several broadcast channels or associated video signals can be sent directly to the user via a single telephone line. The aforementioned digital transmitter should preferably include means for transmitting an analog signal. In one preferred embodiment, the digital transmission signal is transmitted using a cable television system. Receiver 7 receives various NTSC channels, some or all of which contain multiplexed or non-multiplexed digital video signals. Usually two or more channels will be transmitted by the transmitter 5 and received by the receiver 7 as in a normal cable television system. However, each of the different channels may have a data stream that includes several digitized video signals on it. Accordingly, the receiver 7 operates in conjunction with the signal selector 8 to select a specific NTSC channel for playback, then select a specific video signal from the multiplexed signal of the data stream, and finally If necessary, the compressed video signal is decompressed or decompressed for playback on the monitor 10.
Multiple selection controller 9 operates to control receiver 7 and signal selector 8 to select a particular video signal for playback. In fact, the user does not need to know that multiple signals per channel are in use. For example, if 68 channels with 4 signals per channel were in use, the multiple selection controller 9 would associate these channels to the user with the channel 12 in conjunction with the receiver 7 and the signal selector 8. Can be programmed to represent as -72. For example, the monitor 10 can be a normal television. The signal selector 8 preferably includes a conventional demultiplexer for selecting a particular video signal from the data stream on the channel currently being received by the receiver 7. The signal selector 8 preferably further comprises the necessary decompression or decompression device that matches the compression scheme used by the data compressor 3.
In fact, interactive sports event programs can be transmitted over 6 MHz cable television using a compression and multiplexing scheme. The compression and multiplexing scheme allows two sports video signals (eg A and B) to be transmitted over a single NTSC channel (eg channel 34). It is desirable to have four video signals (eg, A-D) for a specific interactive sporting event. The first video signal (signal A) may include a standard broadcast signal for the game. The second video signal (signal B) may include a close-up view of the game action. The third video signal (signal C) may include a continuously updated replay of game highlights. The fourth video signal (signal D) may include statistical information. For example, these four video signals (A-D) can be multiplexed as follows. That is, video signals A and B are multiplexed onto the data stream transmitted over cable channel 34, and video signals C and D are multiplexed onto the data stream transmitted over cable channel 35. . Alternatively, all four video signals (A-D) may be multiplexed into one data stream carried on one frequency channel. However, these four signals can be mapped by multiple selection controller 9 or signal selector 8 and play as separate channel displays for the user. Thus, when the viewer selects with the multiple selection controller, seamless switching occurs between their separate channel displays. Each video signal of this interactive program may include, for example, a label that reads "Full Screen Action--Press A: Close-up Action--Press B: Replay--Press C: Statistics--Press D". .
As shown, the signal selector 8 is associated with the receiver 7 when more signals are needed for the interactive program that can be mapped to a data stream on a single channel. Thus, it can be programmed to switch between different video signals 1 as well as between different broadcast channels, giving the required level of interactivity. However, it is preferred that all the various video signals associated with a particular interactive program are multiplexed onto a single channel. In addition, the signal selector 8 can store information associated with current and previous user responses. For example, the viewer's personal profile or the viewer's previous response pattern may be stored in memory. This information can be found in US Pat. 4,6502,279, which can be used in connection with commands transmitted within a video signal. The stored personal profile information and received commands can be used to interactively switch between the data stream and the video signal without any additional response from the user.
Multiplexed interactive programs can be transmitted over a single telephone line if desired. In this embodiment, the multiple selection controller 9 is programmed to switch between various video signals on a single telephone line. If additional channels are desired, the bidirectional configuration can be used as described below.
The system of the present invention may be utilized in educational embodiments. In this embodiment, information is stored on each data stream in multiple reproducible information segments. Each information segment includes a complete message that can be played by a receiver that responds directly to the selection of the video signal by the signal selector 8 in response to a user selection at the multiple selection controller 9. Each information segment of the various data streams includes an inquiry message having an associated multiple selection response, response message, information message, or a combination thereof.
The various information segments of the various data streams are preferably related to real time and content so that when the video signal is displayed, an interactive conversation can occur and the user responds to various queries contained in the video signal. . When a user answers a specific inquiry with a multiple selection response, information in the video signal associated with the specific selection is displayed by the signal selector 8. Various inquiries, response messages, and information messages may generally be included in any one or more or all of the various video signals. The use of a data stream containing multiple video signals per broadcast channel can be used for many types of interactive programs, such as those disclosed in the aforementioned US patents. Other interactive programs can be developed that are within the scope of the present invention.
The present invention can also be used as a stand-alone system that does not necessarily have a transmission means. In this embodiment, the digitized video signal forming the interactive program is stored in a local storage means such as a video tape, video disk, memory (eg RAM, ROM, EPPROM, etc.) or in a computer. Remembered. The digital video signal is preferably multiplexed onto a standard NTSC signal. Specific storage means may be connected to any of the interactive boxes disclosed in FIGS. 3-5 and described below. The interactive box will then be connected to the television set. Alternatively, the circuitry in FIGS. 3-5 below can be implemented on a board and inserted into a standard personal computer (PC). A separate microprocessor on the interactive board is not necessary for this configuration because a standard PC processor performs the functions of the processor 108 shown in FIGS.
As shown in FIG. 2, the system of the present invention can operate in a bidirectional configuration. In this mode, the various video signals 1 are processed as described above, digitized by the A / D converter 2 and compressed by the data compressor 3. The signal is then routed to the central switching station 14. In this embodiment, switching between the various video signals is done at the headend rather than at the receiver. The multiple selection control unit 9 relays the user's multiple selection selection back to the central switching station 14 located remotely via the relay box 17. Multiple selection selection can be relayed by relay box 17 to the switching station by any conventional means such as bi-directional cable television, telephone, FM transmission. The central switching station 14 receives the user's multiple selection selection and routes the desired signal to the transmitter 5, which transmits the desired video signal to the appropriate cable channel for the particular user. So send as normal. If desired, the transmitter 5 may also transfer normal programming over cable television channels that are not used for interactive programming. Alternatively, the central switching station 14 includes a multiplexing device as described above, thus allowing multiple interactive or non-interactive programs to operate over a single television channel. For example, if it is desired to implement an interactive football game program as described above, a single NTSC cable channel may be allocated for the program. In this case, however, the video signal will be present at the transmitting side. In response to the signal from the wireless controller 9, the signal is sent by the relay box 17 to the cable TV switching station. The cable TV switching station routes the desired video signal to the requesting viewer. Such a system requires a very fast switching device, but can be realized using digital images.
As an alternative, it may be desirable to send interactive sports events over a single telephone line. When the user inputs the selection to the controller 9, a signal is sent over the telephone line to the central switching station. The central switching station routes the desired signal of the interactive program over the user's telephone line so that a single link can be made from the interactive selection made at the receiver, from the headend and from multiple selections. It handles both the transmission of the selection. There, the actual switch occurs in response to an interactive selection made at the receiver.
The bi-directional link between the user and the switching station can be used for other purposes. For commercial purposes such as sending targeted numbers to game show winners for targeted advertising, billing, receiving prizes (pickup), or other commercial Alternatively, demographic data can be transferred from the user to the broadcast network for non-commercial purposes.
As previously mentioned, compression systems generally do little efficiently when the frame-to-frame content includes many changes in the pixel content (eg, during fast motion or background changes). The system of the present invention can be advantageously programmed to ease the processing load on uncompressed programs. When a key on the controller is pressed to select the desired signal, a slight delay that cannot be perceived can be made if desired. This delay gives the uncompressed or decompressed algorithm a short period of time to adjust for rapid changes from one video signal to another. Note that this change usually results in a degradation in the efficiency of the algorithm that causes video glitches to appear on the screen display.
As shown in FIG. 7, a bi-directional link (similar to FIG. 2) can also be used, employing a virtual channel back to the user. In this embodiment, the multiple video signals, preferably time-related and synchronized with each other, are present in the cable headend 300 on multiple channels A, B, C... The signal may be generated locally or received by a receiver 200, 202, 204 and 206 from a remote location (such as a sports area). Alternatively, if the remotely received signal is digitally multiplexed onto one channel, the digital demultiplexer replaces receivers 200-206, demultiplexes the signal, and separates each signal separately Will put on the bus channel. Local or remote signals are synchronized by synchronization circuit 208. A number of remote control interactive switches 210, 212, 214, 216 and 218 are connected to the video signal bus 250. Multiple channels on the video signal bus 250 are provided synchronously and simultaneously to a series of remote control interactive switches 210, 212, 214, 216 and 218. These remote control interactive switches are dynamically assigned to users requesting access to interactive programs. Each switch is connected to frequency agile modulators 220, 222, 224, 226, and 228, and assigns the switch to a virtual channel to connect the signal from video signal bus 250 to a particular user at a remote location. Each switch is assigned to a single user, so the number of switches present at the headend is a limiting factor on the number of users that can interact simultaneously. If only some of the users are assumed to interact at the same time, an algorithm is used to determine the optimal number of remote switches needed to guarantee an acceptable percentage of access.
After passing through frequency agile modulators 220, 222, 224, 226, and 228, the signal from video signal bus 250 travels through cable (or broadcast TV) system 260. The signal may pass through an RF feed 262 and an amplifier 230. User set top boxes 232, 234 and 236 that contain frequency agile demodulators are tuned to the frequencies of the associated frequency agile modulators 220, 222, 224, 226 and 228. Decoded signals from set top boxes 232, 234 and 236 are displayed on television monitor 10.
When the user wants to interact, the user issues a command on the controller 9. Commands are received by set top boxes 232, 234 and 236. User requests are sent back to the remote control interactive switches 210, 212, 214, 216 and 218 down the cable or other transmission system 260. At the appropriate time, based on user requirements and the algorithms for interactivity associated with the program, the remote switch can perform a vertical shift from one signal on the video signal bus 250 to another signal on the video signal bus 250. Cut during the blanking interval. The result of this switch is modulated by one of the frequency agile modulators 220, 222, 224, 226 and 228 and sent down to the virtual channel to the user. The user sees a seamless cut from one image to another as a result of the interaction. The signal supplied to the user can be full bandwidth or compressed video. Similarly, the video signal on the video signal bus 250 that supplies simultaneous signals to multiple remote control interactive switches 210, 212, 214, 216, and 218 may be compressed video. This embodiment allows for a relatively low cost remote user box since the most costly switching device is located at the headend and each remote switch can be assigned to any user. Thus, the cost is distributed to a large number of users.
As an example, the signal received by the receiver 206 is placed on the bus line 270 of the video signal bus 250, sent to the set top box 236, and displayed on the monitor 10. At some point, the set top box 236 generates a user request. This user request is based on current or past entries on the controller 9 and / or information stored in the set top box 236 (eg, the stored information is previous user response information or personal profile information). possible.). Cable TV system 260 may amplify the user request with amplifier 230 while conveying the user request back to frequency agile modulator 226. The frequency agile modulator 226 communicates user requests to the remote switch 216. During the vertical blanking interval, remote switch 216 disconnects from bus line 270 and switches to the appropriate line on video signal bus 250, in this example line 280, based on a user request. This is indicated by the dashed line at 290. The signal from the new connection (received by the receiver 204) is sent to the user's set top box 236 via the frequency agile modulator 226 on the channel 47 and the cable TV system 260. The new signal is displayed seamlessly on the television monitor 10 without any switching occurring in the set top box 236.
As an alternative to the cable headend 300 and cable TV 260 of FIG. 7, a telephone central office and / or telephone line may be used. This alternative allows set top boxes 232, 234 and 236 to receive interactive programming from the telephone company or cable headend via telephone communication.
FIGS. 3 to 6 show preferred embodiments of the receiver 7 and the signal selector 8 of the present invention for enabling seamless and flicker-free transparent switching between digital video signals on the same channel or on different channels. An embodiment is shown. These embodiments can be connected to any transmission medium or simply connected to the output of any stand-alone storage means for digitized and multiplexed interactive programs. The receiver 7 and the signal selector 8 are components of both the interactive program box 11, which is connected to a television or other display monitor. Alternatively, the required functionality of the RF receiver 7, signal selector 8 and monitor can all be combined in a standard personal computer by adding several components to the personal computer. To provide this capability, only the RF demodulator board, digital demultiplexer, decompressor (s), frame buffer (s) and synchronization components need to be added to the personal computer. These items and any other components can be connected to the PC processor and storage elements as disclosed in FIGS. In this embodiment, the user makes a selection via a computer keyboard. FIG. 3 shows an embodiment with a single analog frame buffer. FIG. 4 includes an RF demodulator, error corrector and demultiplexer and / or a pair of digital video buffers, as described below. FIG. 5 utilizes a single digital multiple frame memory. FIG. 6 is directed to an alternative method using the memory 190 described in FIG. 5 and illustrates buffering memory contents over time. Similar circuit components visible in FIGS. 3-5 are referred to by using the same reference numbers.
FIG. 3 illustrates an embodiment that allows seamless video switching between two or more separate digital video signals. As shown in FIG. 3, the microprocessor 108 is connected to the RF demodulator 102 and the digital demultiplexer 106. The microprocessor 108 guides the proper channel and data stream demodulation and demultiplexing to obtain the correct video signal. Appropriate channels are examined either by user input from user interface 130 and / or any other information or criteria stored in RAM / ROM 120 (such as personal profile information). Is determined by For example, RAM / ROM 120 is described in US Pat. Commands provided in the video signal may be stored as described in US Pat. No. 4,602,279 and incorporated herein. The user interface 130 may be an infrared or wireless or wired receiver that receives information from the multiple selection control unit 9.
The RF demodulator 102 is a part of the receiver 7 and demodulates data from the broadcast channel guided by the microprocessor 108. After the data stream is demodulated, it passes through the forward error correction circuit 104 and into the digital demultiplexer 106. This demultiplexer is controlled by the microprocessor 108 and extracts a particular video signal from a number of video signals that can be placed in a data stream on the demodulated broadcast channel. The demultiplexed video signal is then decompressed and decoded by the decompressor / decoder 110. The decompressor / decoder 110 includes a digital / analog converter for converting the decompressed signal into an analog signal. The analog video signal is synchronized by the synchronous adder circuit 150 and the synchronization generator 140. The analog video signal is then buffered by the analog video frame buffer 160. This buffered video signal is modulated by modulator 170 into an NTSC compatible signal.
By using the analog video frame buffer 160 and delaying the viewing of a given signal, it locks, decompresses, converts to analog, and waits for the resulting vertical interval of the second video signal Sufficient time for the decompressor / decoder 110 is provided. For example, assume that video signal A is currently being processed and transferred through the circuit shown in FIG. 3 and displayed on a television set or monitor 10. Based on the user's selection, microprocessor 108 directs digital demultiplexer 106 and RF demodulator 102 to switch to another video signal, video signal B. To accomplish this, an analog video from the first video signal, video signal A, which is complete with video synchronization, is provided to the analog video frame buffer 160. This buffer holds all video pictures for "n" number of frames, after which the signal is output to the display. In fact, the delayed video signal A is seen in “n” number of frames after the signal is received by the television receiver. When the user selects a different video path by pressing a button on the keypad, the microprocessor stops the digital demultiplexer 106 from decoding signal A, locks onto signal B, and instead of signal A Command signal B to begin decoding.
While this happens, the display is still displaying the video signal A, even if the decompressor / decoder 110 no longer decompresses the video signal A. This is because the video signal A is being read from the analog video frame buffer 160. As soon as decompression and decoding occurs, the microprocessor 108 looks for the next vertical blanking interval (VBI) and instructs the analog video frame buffer 160 to buffer the output of the buffer 160 at the occurrence of VBI. Rather, it switches to the input of the buffer 160. Since RF demodulator 102, forward error corrector 104, digital demultiplexer 106 and decompressor / decoder 110 require a certain period of time to decompress and decode video signal B from its data stream. The size of the analog video frame buffer 160 must be large enough so that this process can occur without interruption during video signal switching. If desired, the system may continue to use the analog video frame buffer 160 in anticipation of future switching. By manipulating the fill and vacancy of the analog video frame buffer 160 using the microprocessor 108, the analog video frame buffer 160 is quickly filled with video signal B frames, and then for a period of time. Will be reset and ready for another switch to another video in the same way. The analog video frame buffer 160 can also be reset by skipping frames to fill it or by providing a delay between the output of short sequential frames. If the delay is used to maintain the output of the video signal or frame while the analog video frame buffer 160 is being filled, slight distortion can occur for a short time. Since the first video signal is always displayed as the output of the buffer after the delay, the buffered video masks the capture and decoding of the second video signal. As long as the buffer is large enough to keep the first video signal running while the second video signal is decompressed and decoded, seamless switching will occur.
FIG. 4 shows an alternative dual tuner embodiment for seamless switching between separate video signals. In this embodiment, the microprocessor 108 controls the selection of the RF channel that is demodulated by the RF demodulators 102A, 102B. The demodulated data stream enters forward error corrector 104A, 104B. At the output of the forward error corrector, the data stream is sent to the inputs of digital demultiplexers 106A, 106B. Similar to the RF demodulators 102A, 102B, the digital demultiplexers 106A, 106B are controlled by the microprocessor 108. This form allows the microprocessor 108 to independently select two different individual time multiplexed video signals on different channels and data streams. A single RF demodulator connected in series and feeding two digital video buffers, forward error if all video signals of the interactive program are contained in a single channel or data stream It would only be necessary to have a corrector and a digital demultiplexer.
Two data streams are provided from digital demultiplexers 106A, 106B. One data stream carries video information related to the video signal that the user is currently viewing. The second data stream carries a video signal selected based on the user's previous and / or current interactive selection from the user interface 130 as determined by the microprocessor 108.
Digital information on each of the two streams is buffered in digital video buffers 164, 165. The buffered signal is then decompressed and converted to an analog signal by a decompressor / decoder 110A, 110B including a digital / analog converter. The decompressors 110A, 110B are preferably MPEG decoders. The local synchronization generator 140 is connected to synchronization adding circuits 151 and 152 and frame synchronization circuits 153 and 154. Since both streams are synchronized based on the signal from the same local synchronization generator 140, each stream is synchronized to the other. In particular, the signals on each stream are frame synchronized.
A vertical blanking interval (VBI) switch 180 is connected to the microprocessor 108 so that its input is switched during the vertical blanking interval of the current stream, resulting in a seamless switch for the viewer.
The embodiment of FIG. 4 operates as follows. Based on the user response and control code, assume that the microprocessor 108 determines that a switch from video signal A to video signal B should be performed. The RF demodulator 102A and digital demultiplexer 106A are processing the currently viewed video signal, video signal A, which is going through the upper branch components 164, 110A, 151, 153, 180. Yes. A command is issued from the microprocessor 108 to the RF demodulator 102B instructing switching to the channel and data stream on which the video signal C is arranged. The microprocessor 108 also instructs the digital demultiplexer 106B to provide the video signal C from the received data stream to the digital video buffer 165.
At this point, RF demodulator 102A and digital demultiplexer 106A still receive and process video signal A independently, which continues through the upper branch of the circuit.
At some point, the digital decompressor / decoder 110B in the lower branch will begin filling with video C frames. After the video signal C is decompressed and decoded, it is converted to analog. In order to synchronize the video signal C with the currently displayed video signal A, the local synchronization generator 140 performs both local synchronization and frame synchronization for the video signal C via the synchronization adding circuit 152 and the frame synchronization circuit 154. insert. The video signal A is still being provided from the digital video buffer 164. At the appropriate switching point, triggered by programming code supplied with video signals A and C, the microprocessor directs the VBI switch 180 to switch from video A to video in the vertical blanking interval. Then, at that time, video C appears seamlessly on the television set monitor 10.
Digital video buffers 164 and 165 may be used in the circuit of FIG. 4, but are optional. However, in an alternative embodiment, the circuit of FIG. 4 has a single RF demodulator 102, single forward error correction (as in FIG. 3), each with a single input and a single output. When modified to incorporate the unit 104 and the single digital demultiplexer 106, the digital video buffers 164 and 165 would be required to provide seamless switching. In this alternative embodiment, the circuit cannot receive and demultiplex two data streams on different frequency channels independently. One buffer is used to store the previously received video signal, while the other buffer is quickly passed through the selected video signal.
Based on the same assumptions above, video signal A is traveling through the upper branch of the circuit and is preferably switched to video signal C. However, in this alternative embodiment, digital video buffer 164 provides maximum buffering for video signal A.
Since it is desirable to switch to video signal C, microprocessor 108 receives a data stream on which video signal C is located and demultiplexes it (single RF demodulation connected in series). An alternative circuit (comprising unit 102, single forward error corrector 104 and single digital demultiplexer 106). Note that the data stream is different from that of the video signal A. When video signal C is demultiplexed, microprocessor 108 directs digital video buffer 165 to provide maximum buffering of video signal C so that decompressor / decoder 110B quickly decompresses the digital signal. To decrypt. After decompression and decoding, video signal C is synchronized with video signal A. At this time, video signal A is read from the digital video buffer 164 for display. The digital video buffer 164 outputs during the time it takes for the RF demodulator and digital demultiplexer to switch to the video signal C and during the time it takes to decompress, decode and synchronize the video signal C. Must be large enough to give a video frame for.
When video signal C is synchronized with video signal A, the microprocessor guides VBI switch 180 to switch from video signal A to video signal C in the vertical blanking interval of video signal A, thereby seamlessly and flickering. Provides no switching.
At this time, the digital video buffer 165 begins to utilize maximum buffering by changing its fill / empty rate as described above with respect to the embodiment of FIG. Once proper buffering is achieved, switching to another video signal can be performed in the same manner as described above.
Another preferred embodiment is shown in FIG. This embodiment also includes an RF demodulator 102, a forward error corrector 104, and a digital demultiplexer 106. However, this circuit is different in the rest of the chain to the television set or monitor 10. In this embodiment, a large memory 190 is incorporated and connected to the output of the digital demultiplexer 106 for storing the compressed composite digital video signal. A decompressor / decoder 110 is inserted into the output of the compressed memory 190. The decompressor / decoder 110 decompresses the digital signal, converts the signal to analog, and sends the analog signal to the RF encoder 170 for transmission to the monitor 10. Once the composite compressed digital video signal is supplied to the compressed memory 190, the microprocessor 108 directs the pointer to be placed somewhere along the compressed digital video signal. Based on the placement of the pointer, different frames and different segments of the composite digital video signal are read from memory 190 for decompression and decoding. Different video signals are distinguishable from each other because they are preferably labeled with a header. Assuming that video signal A is selected for play on monitor 10, compressed digital memory 190 is full of A frames. Assuming that switching to video signal C is desired, microprocessor 108 directs RF demodulator 102 and digital demultiplexer 106 to begin filling compressed memory 190 with video C frames. The decoder pointer begins to move down. As soon as a sufficient number of C frames have entered the compressed memory 190, the pointer jumps to the beginning of the C frame. The C frame is then output to a decompressor / decoder 110 where the digital frame is converted to an analog signal.
Digital video is multiplexed into a series of easily identifiable packets. These packets may include all compressed frames of video (I frames) or only the differences between all frames (B frames or P frames). Because the entire video image can be reconstructed, the decompressor / decoder 110 needs to have a minimum number of I, P and B frames. In this embodiment, buffer memory 190 is filled with compressed packets from a given stream of data including I, B, and P frames. If the microprocessor 108 instructs the digital demultiplexer 106 to start sending packets from a different data stream, the next packet is the I packet required to decode the second video stream. There is no way to be sure. The video image corruption occurs when the decompressor / decoder 110 suddenly starts to receive packets unrelated to the stream it was decoding to avoid this video image corruption. The microprocessor 108 begins to fill the memory 190 with the video signal C until the microprocessor 108 determines that the full sequence of I, B and P frames are available. As soon as a valid sequence is in memory, the microprocessor 108 moves the memory read pointer to the beginning of the valid sequence video signal packet so that the decompressor / decoder successfully decodes the C video signal. be able to. This results in a seamless switch from video signal A to video signal C.
This embodiment requires a data channel to enable synchronous switching between the first video stream and the second video stream. This data channel contains ACTV codes that link together different program elements and information segments on different video signals. In addition, the data channel also includes a sync pulse and a time code to signify the proper time for the pointer, separate from the memory location representing one video signal to allow seamless switching. Skip to the memory location representing the video signal.
Microprocessor 108 reads the data signal from digital demultiplexer 106 and communicates the associated data to synchronization add circuit 150. The synchronization adding circuit 150 is connected to the synchronization generator 140. Microprocessor 108 can then communicate synchronously with memory 190.
The sent time code will identify the timing for one picture, as well as for multiple pictures, and lock different pictures together. This is done by using similar clocks at both the transmitter and receiver. A time code is used to maintain two clocks on both the transmitting and receiving sides that are synchronously connected to each other. Once the clocks on both sides operate in synchrony, each of the multiplexed video streams must be synchronized to the clock. In order to synchronize the multiplexed video stream to the clock, each individual channel must reference a common reference point and must be identified.
In the preferred embodiment, the packet header will be incorporated into the transport layer of the MPEG signal to identify the various channels. The packet header also contains information on where to insert the vertical blanking interval. In MPEG, the vertical blanking interval is not transmitted from the head end. Therefore, the vertical blanking interval must be generated locally. Packet header eye (eye) will identify whether the vertical blanking interval in any time for switching seamless between analog pictures exist. In summary, the combination of the clock and information embedded in either the MPEG transport layer or a separate packet on a separate data channel provides a link between each video signal and its corresponding point in time. Do. The data channel also contains information specifying when all the various video signals are synchronized with each other. In these respects, the microprocessor 108 directs the pointer to skip from one location to another when a seamless switch occurs (such as during VBI).
FIG. 6 illustrates a method of using the memory 190 described with respect to FIG. FIG. 6 shows a timed sequence video signal stored in memory 190. In FIG. 6, the decompressor / decoder 110 requests, for example, five specific video frames before decompression and decoding begins. In particular, the decompressor / decoder 110 requires frames A, a, a, a, A, B, b, b, b, B or C, c, c, c, C, and so on. Because of the MPEG compression algorithm used, a video signal in one frame (represented by lower case letters (lowercase)) is replaced with information in some other compressed frame (represented by uppercase (uppercase)). Without use, it cannot be decrypted and decompressed.
At time T0, the viewer is watching channel A, the memory is filled with the frame associated with channel A, and the pointer is frame A.₁Pointing. At time T1, A₁Is output to the decompressor / decoder 110 and the microprocessor 108 switches to channel C. Like the buffer, the memory contents are shifted, so new data c₁Is stored and the pointer is data a₂Data a₂Is ready to be output to the decompressor / decoder 110. At this point in time, the microprocessor 108 monitors the data as it arrives and determines when there is data associated with channel C. At time T2, c₂Is stored and the memory contents are shifted, so a_ThreeIs ready for output. At time T3, C_ThreeIs read into memory and its contents are shifted again, so a_FourIs ready for output. The position of the pointer does not change.
At time T4, the compressed video signal c_FourIs memorized. A_FiveA frame is given for output at the pointer position. At time T5, c_FiveWhile the data is shifted again and a₆Is ready for output.
In this example, the microprocessor 108 receives data C for channel C at times T6 and T7.₆And C₇Is immediately recognized, and the data in the memory is continuously shifted without moving the pointer. Therefore, the data frame a of channel A₇And A₈Is output to the decompressor / decoder 110. Assuming that at time T8, the decompressor / decoder 110 needs three frames (c, c, c) that reference two frames (C, C) for decompression and decoding purposes, the decoding sequence is There is enough channel C data to get started. Therefore, at time T8, the pointer is frame C._ThreeIs moved to point to the frame C_ThreeWill be the next frame output to the decompressor / decoder 110. Frame C_ThreeIs frame c_Four, C_FiveAnd c₆Are used for decompression and decryption of one or more of them.
Rather than outputting the compressed video signal separately, C_Three, C_Four, C_Five, C₆And C₇Can be output to the decompressor / decoder 110 at a time. This is C₇Is the previous frame (ie c_Four, C_FiveOr c₆) Is the preferred technique required for decoding.
Similar to the example described above and shown in FIGS. 3 and 4, the buffer may change its fill and vacancy rate to provide maximum buffering. If this is done, the pointer will be reset to its original position, as shown at time Tn in FIG.
Using FIGS. 3-6 and the previous description of memory and buffers, those skilled in the art can provide seamless switching to switch between interactive channels of the interactive television system of the present invention without flicker. it can. Other variations using the above scheme are also possible as will be realized by those skilled in the art.
Although the invention has been described in detail with respect to certain embodiments and examples, there are variations and modifications that are within the scope of the invention as defined in the following claims.

Claims (43)

Each of the plurality of subscriber television receiving systems includes a multi-channel television receiver, each of the multi-channel television receivers having a plurality of different television receiving channels, each of the television receiving channels. The plurality of subscriber television receiving systems having different associated communication frequencies;
A television subscriber distribution network connected to the plurality of subscriber television receiving systems;
Television programming transmitting means connected to the subscriber distribution network for providing the television distribution network with interactive television programming to be transmitted;
The subscriber distribution network provides the transmitted interactive television programming to the plurality of subscriber television receiving systems;
The television programming sending means includes means for providing multiple information interactive television program communication signals substantially simultaneously to the subscriber distribution network as the transmitted interactive television programming.・ In the system,
A plurality of different program information message signals given simultaneously in relation to each other in real time and content,
The plurality of program information message signals are in a compressed digital format and include the multiple information interactive television program communication signal;
Each of the plurality of program information message signals has an associated communication frequency corresponding to one of the plurality of different television reception channels;
Two or more of the program information message signals have the same associated communication frequency and, together with at least one other of the program information message signals, are multiplexed interactive television program information signals. Combined,
The combined program information signal is transmitted in the multiple information interactive television program communication signal;
Each of the program information message signals can be received independently;
Any of the different television reception channels carry either a single signal of the program information message signal or the multiplexed interactive television program information signal,
Each of the multi-channel television receivers independently receives and selects one of the plurality of program information message signals according to a selected television reception channel and a signal selected therefrom;
Each of the multi-channel television receivers demultiplexes the multiplexed interactive television program information signal and multiplexes to select a frequency associated with the television receiving channel to be received. Demultiplexing channel selection means, signal selection means for selecting a particular program information message signal from the demultiplexed interactive program information signal, and the compressed digital signal of the selected program information message signal A decompression means for decompressing the format,
The decompression means requires an adjustment period when switching from the first selected multiplexed program information message signal to the next selected multiplexed program information message signal,
Each of the program information message signals has a designated position indicator in the demultiplexing multi-channel selection means;
The interactive television system further comprises delay providing means connected to the decompression means, from the first selected multiplexed program information message signal of the multi-channel interactive program. For enhancing the efficiency of the decompression means by providing a delay for the time corresponding to the adjustment period and adjusting for the switch during switching to the selected multiplexed program information message signal The delay providing means for providing a period to the decompression means;
The delay providing means comprises:
Synchronization means for synchronizing the first selected multiplexed program information message signal and the next selected multiplexed program information message signal;
Connected to the synchronization means from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals are performed without a visually perceptible delay; The next selected multiplexed program from the first selected multiplexed program information message signal based on one or more time codes representing the time to skip to the storage location representing the signal Means for switching to an information message signal,
The delay providing means performs a delay for the adjustment period in response to the selection of the next selected multiplexed program information message signal;
The demultiplexing multiple channel selection means decodes the next selected multiplexed program information message signal in response to the selection of the next selected multiplexed program information message signal;
The multi-information interactive television program communication signal simultaneously provided with an associated program information message signal is obtained from the initially selected multiplexed program information message signal without an associated visually perceptible delay. Allows switching of the program information signal to the selected multiplexed program information message signal,
The multi-channel television further wherein at least one of the program information message signals further corresponds to an information label to be dynamically assigned to the designated location indicator for a particular multi-information interactive television program. Including video information for display on the John receiver,
The information label can be dynamically changed according to the contents of the multiple information interactive television program,
Flexible multi-information interactive television programming is given a reduced number of television channels,
An interactive television system wherein a multi-channel interactive program is viewed without a visually perceptible delay when switching between channels of the interactive program during the interactive television program. The interactive television system of claim 1, wherein the displayable information label dynamically changes in response to a selection of consecutive decision trees made. The transmitted interactive television programming further includes at least one regular broadcast television signal having an associated communication frequency;
The television programming transmission means further includes means for providing the at least one legitimate broadcast television signal to the subscriber distribution network substantially simultaneously at the associated communication frequency;
The interactive television system of claim 1, wherein the multi-channel television receiver is adapted to receive the at least one regular broadcast television signal on a channel matching the associated frequency. A plurality of subscriber television receiving systems;
Each of the subscriber television receiving systems includes a television receiver;
Each of the television receivers has a plurality of television receiving channels;
Each of the television receiving channels has a different associated communication frequency;
A television subscriber distribution network connected to the plurality of subscriber television receiving systems;
Television programming transmission means connected to the television subscriber distribution network for providing the television subscriber distribution network with interactive television programming to be transmitted;
The television subscriber distribution network provides the transmitted interactive television programming to the plurality of subscriber television receiving systems;
The television programming transmitting means is for providing a compressed multiplexed digital multiple information interactive television program communication signal to the television subscriber distribution network as the transmitted interactive television programming. Including means,
The compressed multiplexed digital multiple information interactive television program communication signal includes a plurality of multiple information packets;
Each multiplexed information packet includes a plurality of simultaneously provided different program information messages that are related to each other in real time and content and multiplexed at an associated communication frequency to be substantially simultaneously played,
Each of the television receivers independently receives and selects information on any one of the simultaneously provided program information message signals;
Each of the plurality of subscriber television receiving systems further includes multiple information selection means connected between the television subscriber distribution network and the television receiver;
The multiple information selection means is connected to the television subscriber distribution network and decompresses and demultiplexes the compressed multiplexed digital multiple information interactive television program communication signal and the subscriber television. Signal selection means for selecting and providing an output signal including only one of said related different program information message signals for said television receiver in a John reception system;
The multiple information selection means adjusts for proper signal reconstruction of the next selected program information message signal when switching from the first selected program information message signal to the next selected program information message signal. Takes time,
The multiple information selection means is further configured for the adjustment period to enhance the efficiency of the multiple information selection means during switching from the first selected program information message signal to the next selected program information message signal. Including means for providing a delay;
Means for providing said delay;
Synchronization means for synchronizing the first selected multiplexed program information message signal and the next selected multiplexed program information message signal;
Connected to the synchronization means from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals are performed without a visually perceptible delay; The next selected multiplexed program from the first selected multiplexed program information message signal based on one or more time codes representing the time to skip to the storage location representing the signal Means for switching to an information message signal,
A subscriber in the interactive television system can independently select and view the interactive television programming received on the multiplexed receive channel and visually during the interactive television programming. An interactive television system for switching between program information message signals of the interactive television programming without any perceptible delay. The interactive television system of claim 4, wherein said television subscriber distribution network is selected from the group consisting of cable television, telephone, broadcast television and direct broadcast satellite. The multiple information selection means converts any one of the related communication frequencies of the different regular television program information given simultaneously to the related frequency of the television reception channel according to the selected key. 6. The method according to claim 4 or 5, comprising a plurality of keys for selectively enabling any one of: performing, receiving any one of said, and selecting any one of said ones. Interactive television system. The multiplex information packet includes video information that can be displayed on the television receiver corresponding to an information label to be dynamically assigned to the key for a particular multiplex information packet;
7. The interactive television system according to claim 6, wherein the information label that can be displayed on the television can be dynamically changed according to the contents of the specific multiple information packet. 8. An interactive television system according to any one of claims 4, 5 and 7, wherein at least two of the program information message signals include synchronized camera angles of different views of the same event. Each of the plurality of subscriber television receiving systems includes a television receiver, each of the television receivers having a plurality of receiving channels, each receiving channel having a different associated communication frequency. A television receiver system,
An improved interactive television system having a television subscriber distribution network connected to the plurality of subscriber television receiving systems;
Television programming transmitting means connected to the subscriber distribution network for providing the subscriber distribution network with interactive television programming to be transmitted;
The subscriber distribution network provides the transmitted interactive television programming to the plurality of subscriber television receiving systems;
The television programming transmission means includes means for providing a multi-information interactive television program communication signal substantially simultaneously to the subscriber distribution network as the transmitted interactive television programming;
The multi-information interactive television program communication signal includes a plurality of different program information message signals that are given simultaneously in relation to each other in real time and content,
The interactive television system further selects one of the plurality of different program information message signals provided simultaneously in response to a control signal corresponding to a particular television receiver to select the selected signal. Switching means for transmitting to the specific television receiver,
The control signal is received via a transmission medium;
Said means for providing a multi-information interactive program substantially simultaneously further comprises said switching means;
Each of the television receivers independently selects and receives any of the plurality of program information message signals in response to the selected program information message signal;
Each of the television receivers generates and transmits the control signal to the subscriber distribution network and transmits a specific program information message signal from the plurality of program information message signals to the television receiver. Signal selection means for informing the switching means with a signal,
The switching means was initially selected by requiring an adjustment period when switching from the first selected channel to the next selected channel in order to properly reconstruct the signal on the next selected channel. Said switching from one channel to the next selected channel results in a visually perceptible transition without delay,
The signal selecting means further selects the next selected channel from the first selected channel by providing a delay corresponding to the adjustment period during switching from the first selected channel to the next selected channel. A delay providing means for enhancing the efficiency of the switching means during switching to a designated channel,
The delay providing means comprises:
Synchronization means for synchronizing the first selected multiplexed program information message signal and the next selected multiplexed program information message signal;
Connected to the synchronization means from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals are performed without a visually perceptible delay; The next selected multiplexed program from the first selected multiplexed program information message signal based on one or more time codes representing the time to skip to the storage location representing the signal Means for switching to an information message signal,
Flexible multi-information interactive television programming is given a reduced number of television channels,
A subscriber in the interactive television system can independently select and view multiple information interactive television programming and the multiple without any visual perceptible delay in the multiple information interactive television program. An interactive television system that switches between channels of an information interactive television program. The program information message signal includes a plurality of consecutive information packets,
At least some of the plurality of consecutive information packets on the plurality of program information message signals are content related to a decision tree relationship between consecutive individual packets and between the program information message signals;
10. An interactive television system according to any one of claims 1, 4 and 9, wherein a memory storage program format is received as the selectable multiple information interactive television programming. A subscriber television receiving system for receiving interactive television programming;
The interactive television programming includes one or more interactive television program signals located at one or more communication frequencies;
Each interactive television program signal has a data stream that includes a plurality of digitally compressed video signals;
The subscriber television receiving system includes:
A user interface for receiving subscriber selections;
A microprocessor connected to the user interface for selecting one of the video signals and directing a seamless switch to the selected video signal;
A multi-frequency receiver for tuning to one or more frequencies and demodulating an interactive television program on the tuned frequencies;
Means for demultiplexing the demodulated interactive television program signal to obtain a selected video signal;
A memory for storing the selected video signal;
A decompressor / decoder for decompressing the selected video signal and converting the decompressed video signal to an analog television signal;
Synchronization means connected to the decompressor / decoder for synchronizing the analog television signal;
Connected to the synchronization means from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals are performed without a visually perceptible delay; A vertical blanking interval switch for switching between said synchronized analog television signals based on one or more time codes representing a time to skip to a storage location representing the signal ;
Display means connected to the vertical blanking interval switch for displaying the selected video signal;
The seamless switching results in transitioning to the selected video signal without a visually perceptible delay on the display means;
An interactive television system in which subscribers in an interactive television system select and view the interactive television programming independently. A subscriber television receiving system for receiving interactive television programming;
The interactive television programming includes one or more interactive program signals located at one or more communication frequencies;
Each interactive television program signal has a data stream that includes a plurality of digitally compressed video signals;
The subscriber television receiving system includes:
A user interface for receiving subscriber selections;
A microprocessor connected to the user interface for selecting one of the video signals and directing a seamless switch to the selected video signal;
Means for independently receiving and demodulating interactive program signals from one or more communication frequencies;
Means for demultiplexing the received interactive program signal into two video signals;
A pair of digital video buffers, each digital video buffer receiving a video signal from the demultiplexing means and buffering the demultiplexed video signal;
Each decompressor / decoder is connected to one digital video buffer to decompress the buffered video signal and convert the decompressed signal to a standard video signal A canceler / decoder;
A pair of synchronization means, each synchronization means connected to the decompressor / decoder to synchronize the standard video signal;
A vertical blanking interval switch connected to each synchronizing means and for switching between said synchronized signals during the vertical blanking interval of the current synchronized signal;
Means for displaying the selected video signal connected to the vertical blanking interval switch;
Seamless switching to the selected video signal results in a visually perceptible transition without delay,
An interactive television system in which subscribers in an interactive television system select and view the interactive television programming independently. A subscriber television receiving system for receiving interactive television programming;
The interactive television programming includes one or more interactive television program signals located at one or more communication frequencies;
Each interactive television program signal has a data stream that includes a plurality of digitally compressed video signals;
The subscriber television receiving system includes:
A user interface for receiving subscriber selections;
A microprocessor connected to the user interface for selecting one of the video signals and directing a seamless switch to the selected video signal, wherein the seamless switch is visually perceived The processor providing transition to the selected video signal without possible delay;
A multi-frequency receiver for tuning to one or more frequencies and receiving an interactive television program signal on the tuned frequencies;
Means for demultiplexing the received interactive television program signal to obtain a selected video signal;
A memory connected to the demultiplexing means for storing the demultiplexed video signal, comprising a microprocessor controlled pointer for identifying the memory contents to be output;
A decompressor / decoder connected to the memory for decompressing the stored video signal and converting the decompressed signal into a standard video signal;
Synchronization means connected to the decompressor / decoder for synchronizing the standard video signal;
Connected to the synchronization means from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals are performed without a visually perceptible delay; Means for switching between said synchronized standard video signals based on one or more time codes representing a time to skip to a storage location representing the signal;
An RF encoder connected to the switching means for encoding the standard video signal into a standard video broadcast signal ;
Is connected before SL RF encoder further comprises means for displaying the selected video signal,
An interactive television system in which subscribers in an interactive television system select and view the interactive television programming independently. A method of receiving and showing an interactive television program,
An interactive program consists of one or more interactive program signals arranged on one or more communication frequencies,
In the method, the interactive program signal comprises a digitally compressed video signal having video and command information.
Receiving an interactive program signal;
Demultiplexing the received interactive program signal to obtain a digitally compressed video signal;
Storing the digitally decompressed video signal in at least one memory having at least one memory output;
Decompressing the demultiplexed digitally compressed video signal to obtain the command information;
Receiving user input related to interactive program selection;
Processing the command information and the received user input to obtain a selected video signal;
Determining a switching point at which a current video signal is seamlessly replaced with the selected video signal, wherein the seamless switching to the selected video signal without a visually perceptible delay; Said determining step resulting in a transition of:
At the time of the switching, the selected video signal is output by switching to the memory output for the selected video signal, and a seamless switching from the current video signal to the selected video signal occurs . And synchronizes the current video signal with the selected video signal such that one or more synchronization pulses and switching between signals is performed without a visually perceptible delay. Switching from the current video signal to the selected video signal based on one or more time codes representing times to skip from a storage location representing one video signal to a storage location representing a second signal A step in which seamless switching occurs, including steps ;
Displaying an interactive television program comprising: displaying the selected video signal. A method of receiving and showing an interactive television program,
An interactive program consists of one or more interactive program signals arranged on one or more communication frequencies,
In the method, the interactive program signal comprises a digitally compressed video signal having video and command information.
Receiving one or more interactive selections from a user;
Receiving an interactive program signal;
Demultiplexing the received interactive program signal to obtain first and second compressed video signals;
Independently demultiplexing and decoding the first and second compressed video signals to obtain the first and second video signals;
Frame-synchronizing the first and second video signals independently to obtain first and second synchronized video signals;
Passing the first and second synchronized video signals through a vertical blanking interval switch;
The seamless switching between the first and second synchronized video signals according to the following steps, wherein the seamless switching is performed without the visually perceivable delay. Switching without the seam, resulting in a transition to a video signal,
The following steps are:
Determining whether switching is necessary by processing the interactive selection and the first and second command information with a processor;
Instructing the vertical blanking interval switch to switch between the first and second video signals only when the processor determines that switching is necessary;
Skip from the storage location representing the first video signal to the storage location representing the second signal so that switching between the one or more synchronization pulses and the signal is performed without a visually perceptible delay. Switching between the first and second synchronized video signals based on one or more time codes representing time;
Displaying a video signal via the vertical blanking interval switch;
How to receive and show an interactive television program. Means for providing programming comprising means for acquiring programming and bus means for carrying said acquired programming on one or more bus channels;
Means for transmitting interactive television programming,
The means for transmitting is
Means connected to said bus means for synchronizing programming on a previous bus channel with programming on a next bus channel;
Connected to the means for synchronizing, comprising: at least one remote switch means for switching from programming on the destination bus channel to the programming on the next bus channel synchronization on the destination bus channel By switching from programming on the previous bus channel to programming on the next bus channel during a vertical blanking interval of programmed programming, the switch is visually perceived once programming is displayed for the user. Including said at least one remote switch means that provides a transition to programming on the next bus channel without possible delays;
The next bus channel is determined by the switch means based on a user request;
The means for transmitting further includes
Connected to the remote switch means, receiving a user request, communicating the user request to the remote switch means, and receiving the switched program from the remote switch means and the switched program Including a program transmission means for transmitting to a user on a virtual channel,
A user communicates a user request to the means for providing the programming, and receives interactive television programming on a single virtual channel, the received programming being based on the user request. Interactive television system. Means for receiving the user's selection;
Means for receiving digitally compressed interactive television programming, wherein the interactive television programming includes a plurality of video signals related to time and content;
Means for connecting to said means for receiving and for providing a selected video signal based on a user selection;
Means for outputting the analog signal connected to the means for providing and for outputting an analog signal comprising means for decompressing, buffering and synchronizing the selected video signal Means of
Means for controlling the buffering means connected to the means for decompressing, buffering and synchronizing and connected to the means for giving, the means for giving When selecting another video signal based on the selection , one or more synchronization pulses and a storage representing the first video signal so that switching between signals is performed without a visually perceptible delay Said buffer comprising means for seamlessly switching between said synchronized video signals based on one or more time codes representing a time to skip from a position to a storage position representing a second signal Means for controlling the means;
Means for encoding the synchronized analog video signal into a format compatible with a television display, connected to the means for decompressing, buffering and synchronizing;
The encoded signal is related to the user's choice, the user can interactively and seamlessly switch between video signals, and the seamless switching between video signals can be visually perceived on the display An interactive television system that brings about a transition without. A receiver for receiving a broadcast program generated by using a plurality of cameras located at various camera viewpoints;
The broadcast program has a plurality of digital video signals, and the plurality of digital video signals correspond to the various camera viewpoints;
Means for generating the plurality of digital video signals from the received broadcast program;
Means for synchronizing said plurality of generated digital video signals;
Connected to the means for synchronizing, and from the storage location representing the first video signal such that one or more synchronization pulses and switching between the signals is performed without a visually perceptible delay. Means for switching between said synchronized digital video signals based on one or more time codes representing a time to skip to a storage location representing a signal of:
A display device for displaying the selected channel;
Switching from one channel to the selected channel is a seamless digital switch, and the seamless digital switching results in a transition to the selected channel without a visually perceptible delay;
An interactive television system further comprising a remote controller that is remotely coupled to the display and selects a desired camera viewpoint by selecting a corresponding digital video signal. In a method for providing live interactive digital television via an interactive television system,
Obtaining video signals from a plurality of video cameras, wherein one or more of the cameras relay different views of the event;
Digitally encoding one or more of the video signals;
Transmitting said digital video signal;
Receiving a combined digital program stream;
Collecting viewer choices from a remote controller;
Seamlessly switching to a selected digital video signal, wherein the seamless switching results in a transition to the selected digital video signal without a visually perceptible delay; A step of switching between the current digital video signal and the selected digital video signal, without one or more synchronization pulses, and without a delay in which the switching between the signals is visually perceptible From the current digital video signal based on one or more time codes representing a time to skip from a storage location representing the first video signal to a storage location representing the second signal to be executed Switching without the seam, including switching to the selected video signal ;
Displaying the selected video signal on a screen. A receiver for receiving a broadcast program shot using a plurality of cameras located at various camera viewpoints;
The broadcast program has a plurality of digital video signals, and the plurality of digital video signals correspond to the various camera viewpoints;
A remote controller that receives the viewer entry; and
Means for generating the plurality of digital video signals from the received broadcast program;
Means for synchronizing said plurality of generated digital video signals;
Connected to the receiver and remotely coupled to the remote controller to select one of the digital video signals and to the selected digital video signal based on the viewer entry A signal selector that directs seamless switching;
Connected to the means for synchronizing, and from a storage location representing the first video signal such that one or more synchronization pulses and switching between signals is performed without a visually perceptible delay. The synchronized selected digital video signal from the current synchronized digital video signal based on one or more time codes representing a time to skip to a storage location representing the signal of And means for switching to
The seamless switching results in a transition to the selected video signal without a visually perceptible delay;
An interactive television system further comprising a monitor for displaying the selected video signal. 20. The method of claim 19, wherein one of the digital video signals includes a standard broadcast signal for the event. 22. A method according to claim 19 or 21, wherein one of the digital video signals comprises a close-up view of the event. 23. A method according to any one of claims 19, 21 and 22, wherein one of the digital video signals comprises a continuously updated field of view of event highlights. 24. A method according to any one of claims 19, 21, 22, and 23, wherein one of the digital video signals includes statistical information. 21. An interactive television system according to claim 18 or 20, wherein one of the digital video signals includes a standard broadcast signal of the event. 26. An interactive television system according to any one of claims 18, 20 and 25, wherein one of the digital video signals includes a close-up view of the event. 27. An interactive television system according to any one of claims 18, 20, 25 and 26, wherein one of the digital video signals includes a continuously updated field of view of event highlights. 28. An interactive television system according to any one of claims 18, 20, 25, 26 and 27, wherein one of the digital video signals includes statistical information. The digital video signal is digitally compressed;
29. The interactive television system further comprises a decompressor / decoder connected to the receiver for decompressing the digitally compressed video signal. Interactive television system as described in. The compressed digital video signal is multiplexed;
30. The interactive television of any one of claims 18, 20, 25 to 29, wherein the interactive television system further comprises a demultiplexer that demultiplexes the multiplexed digital video signal. ·system. Further comprising a headend operably connected to the receiver;
The remote controller indicates a plurality of camera viewpoints and generates a corresponding unique camera control signal, and transmits the unique camera control signal to the display device;
The display device transmits the camera control signal to the head end;
31. An interactive television system according to any one of claims 18, 20, 25 to 30, wherein the headend seamlessly switches between digital video signals selected by the remote controller. 32. The interactive television system of claim 31, wherein the headend stores digital video signals from a corresponding camera. A personal profile is generated
The interactive television system further comprises a memory for storing the personal profile;
33. An interactive television system according to any one of claims 18, 20, 25 to 32, wherein a desired camera viewpoint is selected based on a viewer profile. Generating a personal profile;
Storing the personal profile;
20. The method of claim 19, wherein the step of selecting a video signal is based in part on the personal profile. A device for seamlessly switching between digital video signals,
A receiver interface for receiving a plurality of digital video signals;
A processor for selecting a video signal for display and directing seamless switching to the selected video signal ;
Means for synchronizing said plurality of received digital video signals;
A seamless video switch connected to the processor;
The seamless video switch includes a second from a storage location representing the first video signal such that switching between the one or more synchronization pulses and the signal is performed without a visually perceptible delay. based on the number of times code than 1 or represents a time to skip to a storage position indicating a signal, switch seamlessly to a digital video signal from the digital video signal is said selected displayed earlier, the An apparatus wherein seamless switching results in transitioning to the selected digital video signal without a visually perceptible delay. A user interface for receiving a subscriber selection;
36. The apparatus of claim 35, wherein the processor selects a video signal based on one or more subscriber selections. A memory connected to the processor for storing at least one of personal information and a video signal;
37. The apparatus of claim 35 or 36, wherein the processor selects a video signal based on personal profile information. The plurality of digital video signals are multiplexed;
The seamless video switch includes a demultiplexer connected to the processor;
The demultiplexer demultiplexes the plurality of digital video signals to obtain the selected video signal;
38. The apparatus of any one of claims 35 to 37, wherein the seamless video switch further comprises a decompressor operatively connected to the demultiplexer for decompressing the selected video signal. A method for seamlessly switching between video signals,
Receiving a plurality of digital video signals;
Synchronizing the received plurality of digital video signals;
Selecting a video signal for display using a processor;
Skip from the storage location representing the first video signal to the storage location representing the second signal so that switching between the one or more synchronization pulses and the signal is performed without a visually perceptible delay. Seamlessly switching from the previously displayed synchronized digital video signal to the selected synchronized video signal based on one or more time codes representing time of day. The seamless switching, wherein the seamless switching results in a transition to the selected video signal without a visually perceptible delay;
Displaying the selected video signal. A method of seamlessly switching between digital video signals at a point located remotely from one or more subscriber receiving systems, comprising:
Receiving a plurality of digital video signals;
Synchronizing the received plurality of digital video signals;
Selecting one of the digital video signals for distribution to at least one of the subscriber receiving systems;
Skip from the storage location representing the first video signal to the storage location representing the second signal so that switching between the one or more synchronization pulses and the signal is performed without a visually perceptible delay. Seamlessly switching from the previously selected synchronized digital video signal to the selected synchronized digital video signal based on one or more time codes representing time of day ; ,
Transmitting the selected video signal to the subscriber receiving system;
The transition from the previously selected digital video signal to the selected digital video signal on a display associated with the subscriber receiving system is visible due to the seamless switching occurring at a remote location. A method that is done without any perceptible delay. Further comprising receiving a user selection made in the subscriber receiving system;
41. The method of claim 40, wherein the selected video signal is selected based on a user selection made at a subscriber receiving system. 42. The method of claim 40 or 41, wherein the selected video signal comprises one selected from the group consisting of a standard broadcast signal, a close-up view of the event, a playback of a portion of the event, and statistical information. A device for seamlessly switching between digital video signals at a point located remotely from one or more subscriber receiving systems,
A receiver for receiving a plurality of digital video signals;
Means for synchronizing said plurality of received digital video signals;
Selecting one of the digital video signals for distribution to at least one of the subscriber receiving systems and seamlessly from the previously selected digital video signal to the selected digital video signal A processor that directs switching;
Connected to the means for synchronizing, and from a storage location representing the first video signal such that one or more synchronization pulses and switching between signals is performed without a visually perceptible delay. The selected synchronized digital video signal from the previously selected synchronized digital video signal based on one or more time codes representing the time to skip to the storage location representing Means for switching to a video signal;
Means for transmitting the selected digital video signal to the subscriber receiving system;
There is no visually perceptible delay in transition from the previously selected digital video signal to the selected video signal on the display associated with the subscriber receiving system due to seamless switching occurring at a remote location. The device made in.

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