An original blanking period of a video signal is shortened to a set blanking period, and audio data is multiplexed into a resulting superimposing period. Table distinguishing data indicating the length of the superimposing period is inserted into the period as a blanking signal. With this configuration, it is possible to enable transmission and reception of an audio signal in a system capable of transmitting and receiving a video signal.
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0. 34. An information processing method, comprising:
receiving a transmitted signal;
detecting a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
capturing video data from the transmitted signal and audio data which is multiplexed into a second period corresponding to a difference between the blanking period and the first period;
outputting the video data to a display; and
outputting the audio data to a speaker,
wherein the step of receiving comprises receiving the transmitted signal via transition minimized differential signaling (TMDS).
0. 23. An information processing method, comprising:
reproducing by a display or a speaker;
setting a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
multiplexing audio data into a second period corresponding to a difference between the blanking period and the first period; and
transmitting an audio/video (AV) signal which includes video data, the audio data and distinguishing data for distinguishing the second period,
wherein the step of transmitting comprises transmitting the AV signal via transition minimized differential signaling (TMDS).
0. 21. An information processing apparatus, comprising:
an output unit comprising a display and a speaker; and
a transmitter that
sets a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
multiplexes audio data into a second period corresponding to a difference between the blanking period and the first period; and
transmits an audio/video (AV) signal which includes video data, the audio data and distinguishing data for distinguishing the second period,
wherein the transmitter transmits the AV signal via transition minimized differential signaling (TMDS).
0. 33. An information processing apparatus, comprising:
a display;
a speaker; and
a receiver that
receives a transmitted signal;
detects a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
captures video data from the transmitted signal and audio data which is multiplexed into a second period corresponding to a difference between the blanking period and the first period; and
outputs the video data to the display and outputs the audio data to the speaker,
wherein the receiver receives the transmitted signal via transition minimized differential signaling (TMDS).
0. 37. An information processing apparatus comprising:
a display, a speaker and a processor,
wherein the processor controls the apparatus to:
receive a transmitted signal;
detect a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
capture video data from the transmitted signal and audio data which is multiplexed into a second period corresponding to a difference between the blanking period and the first period; and
output the video data to the display and output the audio data to the speaker,
wherein the transmitted signal is transmitted via transition minimized differential signaling (TMDS).
0. 28. An information processing apparatus comprising:
a display, a speaker and a processor,
wherein the processor controls the apparatus to:
perform processing of the display and the speaker;
set a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
multiplex audio data into a second period corresponding to a difference between the blanking period and the first period; and
transmit an audio/video (AV) signal which includes video data, the audio data and distinguishing data for distinguishing the second period,
wherein the A/V signal is transmitted via transition minimized differential signaling (TMDS).
0. 35. A processor for an apparatus, wherein the apparatus includes a display and a speaker, the processor comprising:
a processing device and a memory configured to store instructions which, when executed by the processing device, control the apparatus to:
receive a transmitted signal;
detect a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
capture video data from the transmitted signal and audio data which is multiplexed into a second period corresponding to a difference between the blanking period and the first period; and
output the video data to the display and output the audio data to the speaker,
wherein the transmitted signal is transmitted via transition minimized differential signaling (TMDS).
0. 25. A processor for an apparatus, wherein the apparatus includes a display and a speaker, the processor comprising:
a processing device and a memory configured to store instructions which, when executed by the processing device, control the apparatus to:
perform processing of the display and the speaker;
set a first period in a blanking period, the duration of the first period being shorter than the duration of the blanking period;
multiplex audio data into a second period corresponding to a difference between the blanking period and the first period; and
transmit an audio/video (AV) signal which includes video data, the audio data and distinguishing data for distinguishing the second period,
wherein the AV signal is transmitted via transition minimized differential signaling (TMDS).
0. 1. A data transmission apparatus comprising
a processor to implement:
a first input unit for inputting video data of a predetermined number of bits;
a second input unit for inputting audio data;
a setting unit for setting, within a blanking period of the video data, a setup period that is shorter than the blanking period;
a multiplexing unit for multiplexing the audio data into a superimposing period, the superimposing period occurring within the blanking period and not including the setup period, and the setup period at least preceding the superimposing period;
a video data transmitting unit for encoding the video data to generate encoded video data having a number of bits greater than the predetermined number of bits and transmitting the encoded video data to a data channel; and
a retaining unit for retaining information on the setup period or the superimposing period, wherein the retaining unit retains a correspondence between a type of the video data and the setup period or superimposing period as the information on the setup period or superimposing period, and wherein the multiplexing unit multiplexes the audio data into the superimposing period on the basis of the information retained by the retaining unit,
the setup period being used to convey predetermined data other than video data or audio data; and
the predetermined data comprising information for identifying the encoded video data and the superimposing period.
0. 2. A data transmission apparatus as claimed in
0. 3. A data transmission apparatus as claimed in
0. 4. A data transmission apparatus as claimed in
0. 5. A data transmission apparatus as claimed in
0. 6. A data transmission apparatus as claimed in
0. 7. A data transmission apparatus as claimed in
0. 8. A data transmission apparatus as claimed in
0. 9. A data transmission apparatus as claimed in
0. 10. A data transmission apparatus as claimed in
0. 11. An information receiving apparatus comprising
a processor to implement:
a receiver for receiving a transmitted signal;
a first capturing unit for capturing video data from the received signal;
a detecting unit for detecting a blanking period of the captured video data, the blanking period being set to a duration different from the duration of an original blanking period of the video data;
a second capturing unit for capturing information on a superimposing period of the received signal in which audio data is multiplexed, the superimposing period occurring within the original blanking period and not including the blanking period of the captured video data, and the blanking period of the captured video data at least preceding the superimposing period;
a third capturing unit for capturing the audio data from the received signal on the basis of the captured information and superimposing period;
a correcting unit for correcting the detected blanking period on the basis of the captured information on the superimposing period; and
a retaining unit for retaining the information on the superimposing period, wherein the retaining unit retains a correspondence between a type of the video data and the superimposing period as the information on the superimposing period, and wherein the second capturing unit captures the information on the superimposing period from the information retained by the retaining unit,
data indicative of the duration of the superimposing period being received during the blanking period of the captured video data.
0. 12. An information receiving apparatus as claimed in
0. 13. An information receiving apparatus as claimed in
0. 14. An information receiving apparatus as claimed in
0. 15. An information receiving apparatus as claimed in
0. 16. An information receiving apparatus as claimed in
0. 17. An information receiving apparatus as claimed in
0. 18. An information receiving apparatus as claimed in
0. 19. An information receiving apparatus as claimed in
further comprising an expanding unit for expanding the compressed audio data.
0. 20. An information receiving apparatus as claimed in
0. 22. The information processing apparatus according to claim 21, wherein the transmitter sets the first period by disposing, only in the first period, a blanking signal.
0. 24. The information processing method according to claim 23, wherein the step of setting the first period comprises disposing, only in the first period, a blanking signal.
0. 26. The processor according to claim 25, wherein the first period is set by disposing, only in the first period, a blanking signal.
0. 27. The processor according to claim 25, wherein the audio data is compressed on the time axis, and the processing device controls the apparatus to encode the video data and the audio data into 10 bits.
0. 29. The information processing apparatus according to claim 28, wherein setting the first period comprises disposing, only in the first period, a blanking signal.
0. 30. The information processing apparatus according to any one of claims 21 and 28, wherein the audio data is compressed on the time axis, and
further comprising:
an encoding unit that encodes the video data and the audio data into 10 bits.
0. 31. The information processing apparatus according to claim 30, further comprising:
an encrypting circuit that encrypts the video data and the audio data.
0. 32. The information processing apparatus according to claim 30, further comprising:
a buffer that stores the audio data.
0. 36. The processor according to claim 35, wherein the audio data is compressed on the time axis, and the processing device controls the apparatus to encode the video data and the audio data into 10 bits.
0. 38. The information processing apparatus according to any one of claims 33 and 37, wherein the audio data is compressed on the time axis, and
further comprising:
an encoding unit that encodes the video data and the audio data into 10 bits.
0. 39. The information processing apparatus according to claim 38, further comprising:
an encrypting circuit that encrypts the video data and the audio data.
0. 40. The information processing apparatus according to claim 38, further comprising:
a buffer that stores the audio data.
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This application is a continuation reissue of application Ser. No. 13/934,892, which is an application for reissue of U.S. Pat. No. 8,064,361, and is related to application Ser. No. 13/936,843 and application Ser. No. 13/936,871, which are continuation reissues of application Ser. No. 13/934,892, which is an application for reissue of U.S. Pat. No. 8,064,361.
The present application is a continuation of U.S. patent application Ser. No. 11/724,770, filed Mar. 16, 2007, which is a continuation of U.S. patent application Ser. No. 10/095,848, filed Mar. 12, 2002 and which claims priority from Japanese Application No. 2001-067969 filed Mar. 12, 2001, the disclosures of which are hereby incorporated by reference herein.
The present invention relates to an apparatus and a method for transmitting information, an apparatus and a method for receiving information, a system and a method for transmitting and receiving information, a recording medium and a program, and particularly to an apparatus and a method for transmitting information, an apparatus and a method for receiving information, a system and a method for transmitting and receiving information, a recording medium and a program that make it possible to transmit audio data more efficiently by multiplexing the audio data into video data.
A blanking period of video data is often used when the video data has other data superimposed thereon for transmission. In teletext broadcasting, text data is inserted into a vertical blanking period, for example.
Since the blanking period is extremely short as compared with a period for transmitting original video data, however, types of data capable of being multiplexed are limited to low-volume data such as text data.
The present invention has been made in view of the above, and it is accordingly an object of the present invention to enable efficient transmission of data such as, for example, audio data which is low in volume as compared with video data, but high in volume as compared with text data or the like.
According to a first aspect of the present invention, there is provided an information transmitting apparatus including a first capturing unit operable to capture a video signal; a second capturing unit operable to capture a compressed audio signal; a setting unit operable to set a blanking period of the video signal to a predetermined period of a length different from an original period; a multiplexing unit operable to multiplex the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting unit; and a video signal transmitter operable to transmit the video signal having the compressed audio signal multiplexed therein.
The setting unit may set the blanking period to the predetermined period by disposing a blanking signal representing the blanking period only in the predetermined period other than the differential period of the blanking period of the video signal.
The blanking signal may form a control signal.
The information transmitting apparatus may further include a retaining unit operable to retain information on the differential period or the predetermined period, and the multiplexing unit may multiplex the compressed audio signal into the differential period on the basis of the information retained by the retaining unit.
The retaining unit may retain a correspondence between a type of the video signal and the differential period or the predetermined period as the information on the differential period or the predetermined period.
The information transmitting apparatus may further include a distinguishing information transmitter operable to transmit distinguishing information for distinguishing the differential period or the predetermined period.
The distinguishing information transmitting unit may transmit the distinguishing information in the predetermined period of the video signal as a type of blanking signal representing a blanking period.
The distinguishing information transmitting unit may transmit the distinguishing information in a vertical blanking period.
The distinguishing information transmitting unit may transmit the distinguishing information via a transmission line different from a transmission line of the video signal.
The distinguishing information may be information allowing determination of a period from a start point to an end point of the predetermined period or a period from a start point to an end point of the differential period.
The information transmitting apparatus may further include a compressing unit operable to compress the audio signal.
The information transmitting apparatus may further include an encrypting unit operable to encrypt the audio signal by a method common with the video signal.
According to a second aspect of the present invention, there is provided an information transmitting method, including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; and transmitting the video signal having the compressed audio signal multiplexed therein.
According to a third aspect of the present invention, there is provided a recording medium recorded with a computer readable program for transmitting information, the program including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; and transmitting the video signal having the compressed audio signal multiplexed therein.
According to a fourth aspect of the present invention, there is provided a system for performing an information transmission process, including a processor for executing instructions; and instructions, the instructions including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; and transmitting the video signal having the compressed audio signal multiplexed therein.
According to a fifth aspect of the present invention, there is provided an information receiving apparatus including a receiver operable to receive a transmitted signal; a first capturing unit operable to capture a video signal from the received signal; a detecting unit operable to detect a blanking period of the captured video signal, the blanking period being set to a length different from an original period; a second capturing unit operable to capture information on a multiplexing period in which a compressed audio signal is multiplexed; a third capturing unit operable to capture the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the multiplexing period; and a correcting unit operable to correct the detected blanking period on the basis of the captured information on the multiplexing period.
The information receiving apparatus may further include a converting unit operable to convert the compressed audio signal captured by the third capturing unit into a continuous signal.
A blanking signal representing the blanking period may form a control signal.
The information receiving apparatus may further include a retaining unit operable to retain the information on the multiplexing period, and the second capturing unit may capture the information on the multiplexing period from the information retained by the retaining unit.
The retaining unit may retain a correspondence between a type of the video signal and the multiplexing period as the information on the multiplexing period.
The information receiving apparatus may further include a distinguishing information extracting unit operable to extract distinguishing information for distinguishing the multiplexing period.
The distinguishing information extracting unit may extract the distinguishing information from a blanking signal representing the blanking period, the blanking signal being inserted in the blanking period of the video signal.
The distinguishing information extracting unit may extract the distinguishing information from the blanking signal in a vertical blanking period.
The distinguishing information extracting unit may extract the distinguishing information from a signal received via a transmission line different from a transmission line of the video signal.
The distinguishing information may be information allowing determination of a period from a start point to an end point of the multiplexing period or a period from a start point to an end point of the blanking period being set to the length different from the original period.
The information receiving apparatus may further include an expanding unit operable to expand the compressed audio signal.
The information receiving apparatus may further include a decrypting unit operable to decrypt the audio signal by a method common with the video signal, the audio signal being encrypted by a method common with the video signal.
According to a sixth aspect of the present invention, there is provided an information receiving method including receiving a transmitted signal; capturing a video signal from the received signal; detecting a blanking period of the captured video signal, the blanking period being set to a length different from an original period; capturing information on a multiplexing period in which a compressed audio signal is multiplexed; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the multiplexing period; and correcting the detected blanking period on the basis of the captured information on the multiplexing period.
According to a seventh aspect of the present invention, there is provided a recording medium recorded with a computer readable program for receiving information, the program including receiving a transmitted signal; capturing a video signal from the received signal; detecting a blanking period of the captured video signal, the blanking period being set to a length different from an original period; capturing information on a multiplexing period in which a compressed audio signal is multiplexed; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the multiplexing period; and correcting the detected blanking period on the basis of the captured information on the multiplexing period.
According to an eighth aspect of the present invention, there is provided a system for performing information reception, including a processor for executing instructions; and instructions, the instructions including receiving a transmitted signal; capturing a video signal from the received signal; detecting a blanking period of the captured video signal, the blanking period being set to a length different from an original period; capturing information on a multiplexing period in which a compressed audio signal is multiplexed; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the multiplexing period; and correcting the detected blanking period on the basis of the captured information on the multiplexing period.
According to a ninth aspect of the present invention, there is provided an information transmitting and receiving system, including an information transmitting apparatus; and an information receiving apparatus; the information transmitting apparatus including a first capturing unit operable to capture a video signal; a second capturing unit operable to capture a compressed audio signal; a setting unit operable to set a blanking period of the video signal to a predetermined period of a length different from an original period; a multiplexing unit operable to multiplex the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting unit; and a video signal transmitter operable to transmit the video signal having the compressed audio signal multiplexed therein; and the information receiving apparatus including a receiver operable to receive a signal transmitted from the information transmitting apparatus; a third capturing unit operable to capture the video signal from the received signal; a detecting unit operable to detect the blanking period of the captured video signal, the blanking period being set to the predetermined period; a fourth capturing unit operable to capture information on the differential period; a fifth capturing unit operable to capture the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the differential period; and a correcting unit operable to correct the detected blanking period on the basis of the captured information on the differential period.
According to a tenth aspect of the present invention, there is provided an information transmitting and receiving method, including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; transmitting the video signal having the compressed audio signal multiplexed therein; receiving the transmitted signal; capturing the video signal from the received signal; detecting the blanking period of the captured video signal, the blanking period being set to the predetermined period; capturing information on the differential period; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the differential period; and correcting the detected blanking period on the basis of the captured information on the differential period.
According to an eleventh aspect of the present invention, there is provided a recording medium recorded with a program for transmitting and receiving information, the program including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; transmitting the video signal having the compressed audio signal multiplexed therein; receiving the transmitted signal; capturing the video signal from the received signal; detecting the blanking period of the captured video signal, the blanking period being set to the predetermined period; capturing information on the differential period; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the differential period; and correcting the detected blanking period on the basis of the captured information on the differential period.
According to a twelfth aspect of the present invention, there is provided a system for performing information transmission and reception processes, including a processor for executing instructions; and instructions, the instructions including capturing a video signal; capturing a compressed audio signal; setting a blanking period of the video signal to a predetermined period of a length different from an original period; multiplexing the compressed audio signal into a differential period corresponding to a difference between the blanking period of the video signal and the predetermined period set by the setting step; transmitting the video signal having the compressed audio signal multiplexed therein; receiving the transmitted signal; capturing the video signal from the received signal; detecting the blanking period of the captured video signal, the blanking period being set to the predetermined period; capturing information on the differential period; capturing the multiplexed compressed audio signal from the captured video signal on the basis of the captured information on the differential period; and correcting the detected blanking period on the basis of the captured information on the differential period.
The apparatus and method for information transmission, and the program according to the present invention, multiplex the compressed audio signal into the differential period created by setting the blanking period of the video signal to the predetermined period.
The apparatus and method for information reception, and the program according to the present invention, capture the compressed audio signal superimposed in the multiplexing period of the received video signal, and correct the blanking period on the basis of the multiplexing period.
The system and method for information transmission and reception, and the program according to the present invention, multiplex the compressed audio signal into the differential period of the video signal, and thereby transmit the compressed audio signal from the information transmitting apparatus. The information receiving apparatus captures the compressed audio signal multiplexed in the differential period, and corrects the blanking period on the basis of the differential.
Preferred embodiments of the present invention will hereinafter be described in detail with reference to the drawings.
The digital tuner 31 has a front end 41. The front end 41 demodulates the broadcast wave received via the antenna 32, and then outputs video data and audio data (hereinafter also referred to as AV data) obtained by demodulating the broadcast wave to an AV decoder 42. The AV decoder 42 decodes the AV data supplied from the front end 41, and then outputs the result to a transmitter 43. The transmitter 43 is controlled by a control unit 44, and outputs the AV signal supplied from the AV decoder 42 to the monitor 33 via the TMDS 34.
The monitor 33 incorporates a receiver 51. The receiver 51 receives the AV data supplied from the transmitter 43 of the digital tuner 31 via the TMDS 34, and then separates audio data, video data, and synchronizing data.
The audio data output from the receiver 51 is subjected to D/A conversion by a D/A converter 52, and then output from left-channel and right-channel speakers 53 and 54.
The video data output from the receiver 51 is subjected to D/A conversion by a D/A converter 55, amplified by an RGB amplifier 56, and output to a CRT 58.
An H/V sync generating unit 57 generates a horizontal synchronizing signal and a vertical synchronizing signal on the basis of the synchronizing data supplied from the receiver 51, and then supplies the horizontal synchronizing signal and the vertical synchronizing signal to a driving circuit of the CRT 58.
A terminal 91 is supplied with data of 2 bits forming horizontal synchronizing data and vertical synchronizing data. The 2-bit data is supplied to an encoder 83A.
A terminal 92 is supplied with data of 2 bits forming a control signal (CTL0, CTL1) as shown in
A terminal 93 is supplied with audio data, in this example, as data to be superimposed (multiplexed). The audio data input from the terminal 93 is stored temporarily by a buffer 84, and then supplied as data in units of 8 bits to the lower input terminal (as viewed in
A terminal 94 is supplied with a blanking signal indicating a blanking period as shown in
A terminal 95 is supplied with a pixel clock of 25 MHz to 165 MHz as shown in
The timing generating unit 85 generates a timing signal to control the buffer 84, the switches 81A, 81B, and 81C, and encrypting units 82A, 82B, and 82C in synchronization with the blanking signal and the pixel clock. The timing generating unit 85 also sets (shortens) the blanking signal to a predetermined length, and supplies the set blanking signal to encoders 83A, 83B, and 83C.
The switches 81A, 81B, and 81C are each turned to the upper input terminal or the lower input terminal in the figure on the basis of the timing signal supplied from the timing generating unit 85 to select the pixel data A to C or the audio data. The switches 81A, 81B, and 81C output the selected pixel data or audio data to their corresponding encrypting units 82A, 82B, and 82C, respectively.
The encrypting units 82A, 82B, and 82C encrypt the video data (pixel data) or the audio data input thereto by a common algorithm, and then output the results to their corresponding encoders 83A, 83B, and 83C.
A superimposing period table 86 prestores data on length of a horizontal blanking period and length of a vertical blanking period corresponding to the pixel data to be output from the encoders 83A to 83C.
For example, when pixel data to be encoded and output is 480p (the number represents the number of scanning lines, and p denotes a progressive system), the horizontal blanking period corresponds to a length of 138 pixels. When pixel data to be encoded and output is 720p, the length of the horizontal blanking period corresponds to 370 pixels. When pixel data to be encoded and output is 1080i (i denotes an interlacing system), the length of the horizontal blanking period corresponds to 280 pixels.
That is to say, data for displaying position (length) of a horizontal blanking period and position (length) of a vertical blanking period corresponding to the displaying system are stored in the superimposing period table 86.
The timing generating unit 85 turns the switches 81A and 81C to the lower side thereof (as viewed in the figure) to select audio data for a superimposing period (multiplexing period) stored in the superimposing period table 86.
During a period when the blanking signal set by the timing generating unit 85 (hereinafter referred to as the set blanking signal) is not supplied, the encoder 83A encodes the 8-bit pixel data A or audio data supplied from the encrypting unit 82A on the basis of a predetermined algorithm, and then outputs the result as 10-bit data of the data channel A.
During a period when the set blanking signal is input (hereinafter referred to as a set blanking period), the encoder 83A encodes (generates) 10-bit blanking data on the basis of the 2-bit horizontal synchronizing signal or vertical synchronizing signal input from the terminal 91, and then outputs the blanking data as data of the data channel A.
As with the encoder 83A, during the period other than the set blanking period, the encoder 83B or 83C encodes the pixel data or audio data input from the encrypting unit 82B or 82C, respectively, and then outputs the result as 10-bit data. During the set blanking period, the encoder 83B encodes (generates) 10-bit blanking data on the basis of the 2-bit control signal input from the terminal 92, and the encoder 83C encodes (generates) 10-bit blanking data on the basis of 2-bit data indicating the superimposing period supplied from the superimposing period table 86. The output of the encoder 83B and the output of the encoder 83C are transmitted to the monitor 33 as an output of the data channel B and an output of the data channel C, respectively.
In addition, the pixel clock generated by the PLL circuit 87 is transmitted to the monitor 33 as data of a clock channel.
Eight-bit pixel data A or audio data decoded by the decoder 101A is supplied to a decrypting unit 102A. When the 10-bit blanking data is input, the decoder 101A converts the 10-bit blanking data into 2-bit horizontal synchronizing data or vertical synchronizing data, and then supplies the 2-bit horizontal synchronizing data or vertical synchronizing data to the H/V sync generating unit 57.
Eight-bit pixel data B or audio data output by the decoder 101B is supplied to a decrypting unit 102B. When the 10-bit blanking data is input, the decoder 101B converts the 10-bit blanking data into a 2-bit control signal, and then supplies the 2-bit control signal to a control unit 59 of the monitor 33.
Eight-bit pixel data C or audio data output by the decoder 101C is supplied to a decrypting unit 102C. When the 10-bit blanking data is input, the decoder 101C converts the 10-bit blanking data into 2-bit data indicating the superimposing period, and then supplies the 2-bit data to a timing generating unit 103.
The decoders 101A to 101C also output the set blanking signal (Data Enable) indicating the set blanking period to the timing generating unit 103. The timing generating unit 103 extends the set blanking period and thus generates a blanking signal of an original length by referring to a superimposing period table 105 (the same table as the superimposing period table 86 in
The decrypting units 102A to 102C decrypt the 8-bit pixel data A or audio data, the pixel data B or audio data, and the pixel data C or audio data input thereto, respectively, and then output the pixel data to the D/A converter 55.
The 8-bit audio data decrypted by the decrypting units 102A to 102C is supplied to the buffer 104 to be converted into continuous data, and then output to the D/A converter 52.
The blanking signal generated by the timing generating unit 103 is supplied to the H/V sync generating unit 57 in conjunction with the pixel clock of the frequency 1/10 that of the clock supplied to the decoders 101A to 101C, which pixel clock is generated by the PLL circuit 106 (clock of the same frequency as that of the pixel clock input to the terminal 95 of the transmitter 43 in
The operation of the transmitting and receiving system will next be described. When the front end 41 of the digital tuner 31 receives a radio wave of a channel specified by a user via the antenna 32, the front end 41 of the digital tuner 31 demodulates the received signal, and then outputs the demodulated signal to the AV decoder 42. The AV decoder 42 decodes the received signal input thereto, and then outputs decoded audio data and video data to the transmitter 43. The transmitter 43 multiplexes the audio data into the horizontal blanking period of the video data input thereto, and then outputs the result to the monitor 33 via the TMDS 34.
The TMDS 34 is essentially an interface for personal computers, and therefore is in a format not allowing transmission of audio data. In this case, however, the audio data is multiplexed into the blanking period of the video data, and therefore the audio data can be transmitted via the TMDS 34.
The receiver 51 on the monitor 33 side receives the video data transmitted via the TMDS 34, separates the audio data inserted in the blanking period, and then outputs the audio data to the D/A converter 52. The D/A converter 52 converts the audio data input thereto into analog audio signals for a left and a right channel to be output from the speakers 53 and 54.
Horizontal synchronizing data and vertical synchronizing data also extracted and generated from the blanking period by the receiver 51 are supplied to the H/V sync generating unit 57. The H/V sync generating unit 57 generates a horizontal synchronizing signal and a vertical synchronizing signal on the basis of the data input thereto, and then outputs the horizontal synchronizing signal and the vertical synchronizing signal to the driving circuit of the CRT 58.
The receiver 51 also outputs pixel data extracted from the data input thereto to the D/A converter 55 to subject the pixel data to D/A conversion. RGB signals output from the D/A converter 55 (signals of the pixel data A to C) are amplified by the RGB amplifier 56, and then supplied to the CRT 58 for display. In this case, the CRT 58 is controlled in the scanning of scanning lines on the basis of the horizontal synchronizing signal and the vertical synchronizing signal generated by the H/V sync generating unit 57.
Transmission processing on the channel A of the transmitter 43 in
At a step S1, the timing generation unit 85 determines whether the timing generation unit 85 is now in a blanking period on the basis of input from the terminal 94. When the timing generation unit 85 is not in a blanking period, the processing proceeds to a step S2, at which the timing generation unit 85 generates a switch control signal and then outputs the switch control signal to the switch 81A to turn the switch 81A to the upper input terminal (as viewed in
At a next step S5, the encrypting unit 82A encrypts the data selected by the switch 81A (pixel data A in this case). At a step S6, the encoder 83A encodes the pixel data A encrypted by the encrypting unit 82A at the step S5, and at a step S8, the encoder 83A outputs the encoded data to the TMDS 34 as data of the data channel A.
When the timing generation unit 85 determines at the step S1 that the timing generation unit 85 is now in a blanking period, on the other hand, the processing proceeds to a step S3. At the step S3, the timing generation unit 85 refers to a table of the superimposing period table 86 to determine whether the timing generation unit 85 is in a period for superimposing (multiplexing) audio data. Specifically, as described above, a period for superimposing audio data (superimposing data) in a horizontal blanking period is predefined in the superimposing period table 86. The timing generation unit 85 determines on the basis of the definition whether the timing generation unit 85 is now in a period for superimposing (multiplexing) audio data.
When the timing generation unit 85 determines that the timing generation unit 85 is in a horizontal blanking period but not in a period for superimposing audio data, the processing proceeds to a step S7. At the step S7, the timing generation unit 85 controls the encoder 83A to generate 10-bit horizontal or vertical blanking data on the basis of 2-bit horizontal or vertical synchronizing data input from the terminal 91 and then output the 10-bit horizontal or vertical blanking data.
When the 2-bit data is denoted by (C1, C0), the encoder 83A outputs 10-bit control (CTL) data provided for the 2-bit data as shown in
In the example of
Although the processing of the step S7 is basically performed over the entire blanking period, the processing of the step S7 in the present invention is performed only in a period when audio data is not superimposed. This means that the blanking period is set to a length shorter than the original period.
The step S7 is succeeded by a step S8, at which the encoder 83A outputs the blanking data generated at the step S7 via the TMDS 34.
When the timing generation unit 85 determines at the step S3 that the timing generation unit 85 is now in a period for superimposing audio data, on the other hand, the processing proceeds to a step S4. At the step S4, the timing generation unit 85 controls the switch 81A to turn the contact of the switch 81A to the lower side (as viewed in
At the step S5, the encrypting unit 82A encrypts the audio data input via the switch 81A, and then outputs the encrypted audio data to the encoder 83A. At the step S6, the encoder 83A encodes the encrypted audio data input from the encrypting unit 82A, and at the step S8, the encoder 83A outputs the encoded data to the TDMS 34. Thus, the video data (pixel data) and the audio data are encrypted by the common encrypting unit 82A. It is therefore possible to simplify the configuration, miniaturize the apparatus, and lower the cost as compared with a case where the video data (pixel data) and the audio data are provided as data separate from each other.
Transmission processing on the channel B will next be described with reference to the flowchart of
The processing at steps S21 to S28 in
In addition, at the step S27, the encoder 83B generates 10-bit horizontal or vertical blanking data (
The other processing is the same as in
Transmission processing on the channel C is as shown in
The processing described above will be described further with reference to the timing charts of
As shown in
The audio data, which is continuous data as shown in
In the period T1, horizontal synchronizing data or vertical synchronizing data is transmitted in the example of
The receiving processing of the channel A of the receiver 51 in
At a step S42, the decoder 101A determines whether the decoded data is blanking data. When the decoder 101A determines that the decoded data is blanking data, the processing proceeds to a step S43, at which the decoder 101A generates horizontal or vertical synchronizing data (generates 2-bit data corresponding to the 10-bit control code in
The decoder 101A also outputs data of a period corresponding to the blanking data as data of a set blanking period to the timing generating unit 103. As will be described in detail in the processing at a step S83 in
When the decoder 101A determines at the step S42 that the decoded data is not blanking data, the data is either pixel data or audio data. Therefore, the decoder 101A outputs the data to the decrypting unit 102A. At a step S44, the decrypting unit 102A decrypts the data input thereto. The decrypting unit 102A determines whether the decrypted data is audio data on the basis of a timing signal from the timing generating unit 103 at a step S45. When the decrypting unit 102A determines that the decrypted data is audio data, the processing proceeds to a step S46, at which the audio data is supplied to the buffer 104 to be stored therein.
Specifically, the timing generating unit 103 reads a superimposing period T2 corresponding to table distinguishing data for distinguishing the superimposing period, which data is output by the decoder 101C, from the superimposing period table 105 on the basis of the table distinguishing data. The timing generating unit 103 then outputs a timing signal corresponding to the period T2. The decrypting unit 102A determines that data in the period T2 is audio data.
The buffer 104 is also supplied with audio data decrypted by the decrypting unit 102B or 102C of the channel B or the channel C. The buffer 104 outputs these pieces of audio data as continuous data.
When the decrypting unit 102A determines at the step S45 that the decrypted data is not audio data (when the decrypting unit 102A determines that the decrypted data is pixel data A), on the other hand, the processing proceeds to a step S47, at which the decrypting unit 102A outputs the data to the D/A converter 55.
The flowchart of
The timing generating unit 103 reads from the superimposing period table 105 the superimposing period T2 corresponding to the table distinguishing data supplied from the decoder 101C, and then sets the period T2 in an internal memory. The timing generating unit 103 generates a timing signal for separating audio data from pixel data by using the superimposing period T2 until new table distinguishing data is received in a next vertical blanking period.
In addition, the timing generating unit 103 lengthens (corrects) the set blanking period T1 by the period T2 on the basis of the set blanking data supplied from the decoders 101A to 101C and the set superimposing period T2. The timing generating unit 103 generates a blanking signal corresponding to the blanking period T0 of original length, and then outputs the blanking signal to the H/V sync generating unit 57.
The receiving processing described above will be described further with reference to the timing charts of
As shown in
The processing of inserting table distinguishing data into the period T1 as shown in
In the embodiment of
The series of processing steps described above may be carried out not only by hardware but also by software. In such a case, the digital tuner 31 is formed as shown in
A CPU (Central Processing Unit) 221 in
The CPU 221, the ROM 222, and the RAM 223 are connected to each other via a bus 224. The bus 224 is also connected with an input/output interface 225.
The input/output interface 225 is connected with an input unit 226 formed by a keyboard, a mouse and the like, an output unit 227 formed by a display formed by a CRT, an LCD or the like and a speaker or the like, the storage unit 228 formed by a hard disk or the like, and a communication unit 229 formed by a modem, a terminal adapter or the like. The communication unit 229 performs processing for communication via a network.
When necessary, the input/output interface 225 is also connected with a drive 230 to which a magnetic disk 241, an optical disk 242, a magneto-optical disk 243, a semiconductor memory 244 or the like is inserted as required. Computer programs read from the magnetic disk 241, the optical disk 242, the magneto-optical disk 243, the semiconductor memory 244 and the like are installed in the storage unit 228 as required.
Though not shown in the figure, when the series of processing steps is to be carried out by software, the receiver 51 and the like may also be formed by a computer as with the digital tuner 31. When the series of processing steps is to be carried out by software, a program forming the software is installed from a network or a recording medium onto a computer that is incorporated in special hardware, or a general-purpose personal computer that can perform various functions by installing various programs thereon, for example.
Examples of the recording medium include not only program-recorded packaged media distributed to users to provide the program separately from the apparatus proper, which packaged media are formed by magnetic disks 241 (including floppy disks), optical disks 242 (including CD-ROM (Compact Disk-Read Only Memory) and DVD (Digital Versatile Disk)), magneto-optical disks 243 (including MD (Mini-Disk)), or semiconductor memories 244 as shown in
It is to be noted that in the present specification, the steps describing the program recorded on a recording medium include not only processing steps carried out in time series in the described order, but also processing steps carried out in parallel or individually and not necessarily in time series.
Also, in the present specification, a system denotes the whole apparatus formed by a plurality of apparatus.
As described above, the apparatus and method for information transmission, and the program according to the present invention multiplex a compressed audio signal into a differential period created by setting a blanking period to a predetermined period. It is therefore possible to transmit an audio signal efficiently.
The apparatus and method for information reception, and the program according to the present invention capture the compressed audio signal multiplexed in the multiplexing period of a captured video signal, and correct the blanking period on the basis of the multiplexing period. It is therefore possible to reliably extract the compressed audio signal, recover the length of the original blanking period readily and reliably, and thereby prevent adverse effects on reproduction of the video signal.
According to the system and method for information transmission and reception, and the program according to the present invention, the information transmitting apparatus multiplexes a compressed audio signal into a differential period created by setting a blanking period of a video signal to a predetermined period, and thereby transmits the compressed audio signal, and the information receiving apparatus captures the compressed audio signal multiplexed in the differential period, and corrects the blanking period. Therefore, it is possible to transmit and receive the compressed audio signal other than the video signal readily and reliably in a system capable of transmitting and receiving a video signal, and thus realize a system having no adverse effects on transmission and reception of an original video signal.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
4589018, | Jun 03 1983 | AT&T Bell Laboratories | Technique for the time frequency multiplexing on three television signals |
4680647, | Sep 26 1983 | Pioneer Electronic Corporation | Method for recording and reproducing video format signal |
5523795, | Aug 24 1993 | Sony Corporation | Method and apparatus for serial transmission and/or reception of nonsynchronous, multiplexed signals |
5796441, | Apr 27 1995 | S AQUA SEMICONDUCTOR, LLC | Video coding and decoding system with teletext capability |
5929921, | Mar 16 1995 | Matsushita Electric Industrial Co., Ltd. | Video and audio signal multiplex sending apparatus, receiving apparatus and transmitting apparatus |
5940070, | May 12 1995 | SAMSUNG ELECTRONICS CO , LTD | Device and method for transmitting an audio signal using a video signal line in a computer system |
6151334, | Oct 05 1995 | Silicon Image, Inc. | System and method for sending multiple data signals over a serial link |
6243469, | Sep 18 1997 | Matsushita Electric Industrial Co., Ltd. | Information transmission method and apparatus |
6297797, | Oct 30 1997 | Kabushiki Kaisha Toshiba | Computer system and closed caption display method |
6437824, | Feb 07 1997 | Canon Kabushiki Kaisha | Image pickup apparatus and system |
6678333, | Oct 18 1999 | Sony Corporation | Method of and apparatus for transmitting digital data |
7096487, | Oct 27 1999 | TIVO CORPORATION | Apparatus and method for combining realtime and non-realtime encoded content |
7499545, | Feb 05 2001 | ATI Technologies, Inc. | Method and system for dual link communications encryption |
7499628, | Aug 19 1991 | Index Systems inc. | Enhancing operations of video tape cassette players |
20010036193, | |||
20020171761, | |||
20020199149, | |||
20030145336, | |||
20090052471, | |||
20140078155, | |||
EP1032200, | |||
EP1231795, | |||
EP1303145, | |||
JP2002281464, | |||
JP4254084, | |||
JP4284084, | |||
JP5219488, | |||
JP6121313, | |||
JP678280, | |||
JP9046661, | |||
JP9179536, | |||
RE37879, | Jul 13 1988 | Seiko Epson Corporation | Image control device for use in a video multiplexing system for superimposition of scalable video data streams upon a background video data stream |
WO14626, | |||
WO209443, | |||
WO9748056, | |||
WO9912306, |
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