JP3557827B2 - Compressed audio burst output method, apparatus, and data stream reproducing apparatus - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a compressed audio burst output method and apparatus, an audio data reproducing apparatus, and a video reproducing apparatus with an audio reproducing function.
[0002]
[Prior art]
In a conventional compressed audio reproduction processing apparatus such as a laser disk supporting compressed audio, one type of compressed audio format is employed, which is a digital data transmission standard defined by the digital audio interface (DAI) of IEC958. Burst transmission output is performed at regular intervals with a word header at the beginning.
[0003]
FIG. 2 shows the DAI signal based on the IEC958. The DAI signal 101 is shown in FIG. 1 ), A 4-bit preamble 102, a 4-bit auxiliary data area 103, a 20-bit LSB head-justified 20-bit audio data area 104, a 1-bit validity flag (V) 105, and a 1-bit The user data (U) 106, the 1-bit channel status (C) 107, and the 1-bit parity flag (P) 108 make up a total of 32 bits, thereby forming one DAI subframe. The 16-bit PCM stereo sound is stored with the LSB leading justified so that one sample of Lch comes to the audio data area 104 with the MSB immediately before the validity flag (V) 105. One sample of Rch is similarly stored in the audio data area 109 of the immediately following DAI subframe, and this LchDAI subframe and RchDAI subframe constitute one DAI frame, and data of one sample can be transmitted. . Therefore, the DAI frame occurs at the same cycle as the sampling frequency (Fs), and the DAI subframe occurs at the same cycle as twice the sampling frequency (Fs).
[0004]
In IEC958, not only audio data transmission (audio mode) but also a mode for transmitting non-audio digital data (digital data mode) is prepared. 2 ), 1 word (16 bits) of digital data is transmitted in the non-audio data area 110 corresponding to the upper 16 bits of the 20-bit audio data area 104. The next 1-word (16-bit) digital data is stored in the non-audio data area 112 corresponding to the upper 16 bits of the 20-bit audio data area 109, and the DAI subframe in 1 word, the first 16-bit word and the second 16-bit word A DAI frame is configured. As described above, the DAI described in IEC958 is a standard for an encoding and transmission method and apparatus for converting data into a signal to which a synchronization word, a parity, and the like are added at a clock frequency depending on a sampling frequency of audio, and transmitting the signal. It is.
[0005]
When transmitting a compressed voice burst in this digital data mode, in addition to the main part of the compressed voice burst, a synchronization word indicating the start of the burst, a burst header including information indicating the content of the burst, information indicating the length of the information burst, and the like are included. use. One example of this is defined in Annex B of Digital Audio Compression Standard (AC-3), and FIG. 4 ) Shows that. A 16-bit first synchronization word 115, a 16-bit second synchronization word 116, a 16-bit burst data information 117, and a 16-bit burst length code 118 are added to the head of the compressed voice burst body 119. On the receiving side, the head of the burst is detected by detecting the first synchronization word 115 of 16 bits and the second synchronization word 116 of 16 bits, and only the data indicated by the data information 117 in the burst and the burst length code 118 subsequent thereto are detected. Read the burst data of After the end of the burst, dummy data is transmitted, and burst transmission is performed at a fixed interval from the head of the burst 114 to the head of the next burst 114. FIG. 2 ( 5 ) Is an example of this, in which burst transmission is performed with a compressed voice burst body of 768 words, a header of 4 words, dummy data of 2300 words, and an interval of 3072 words. The DAI 16-bit data signal 120 including the dummy data is shown in FIG. 3 ), The data is treated as continuous data at the head of the MSB with a 16-bit delimiter, is converted to the head of the LSB, and is stored in the non-audio data area 110 or the non-audio data area 112 after transmission and transmitted.
[0006]
FIG. 3 shows a data stream reproducing apparatus provided with a circuit for externally outputting a compressed audio burst as an example of a conventional device that realizes these processes. The reproduction data stream 38 read from the recording medium disk 36 by the reader 37 is demodulated by the demodulation circuit 39 to become a demodulated stream 40. A compressed image stream 42 and a compressed audio stream 43 are extracted from the demodulated stream 40 by a stream separation circuit 41. The compressed audio stream 43 is temporarily stored in a buffer RAM 44, and is read out by a burst header adding circuit 46 at a predetermined timing. The burst header adding circuit 46 intermittently reads the compressed audio stream from the buffer RAM 44 in the form of a compressed audio burst 45 at fixed time intervals, adds a burst header corresponding to the compressed audio to the beginning of the compressed audio burst 45, and outputs it. . The compressed audio stream 12 with the header for burst is encoded into a DAI signal 14 by the DAI encoder 13 and output to the DAI signal terminal 15. At this time, the burst header addition circuit 46 and the DAI encoder 13 operate at a clock timing synchronized with the sampling frequency Fs according to the sampling frequency information 52. The sampling frequency information 52 is extracted from the compressed audio stream 43 by the auxiliary information extracting circuit 47. The auxiliary information extracting circuit 47 includes a synchronization detection 48 and an auxiliary information reading circuit 49. The synchronization detection 48 detects a synchronization pattern indicating the head of the compressed audio basic unit in the compressed audio stream 43, The data 50 of the auxiliary information part is transmitted, and the auxiliary information reading circuit 49 reads out the information part relating to the sampling frequency from the data 50 of the auxiliary information part, and outputs the sampling frequency information 52. In such a process, the conventional device converts the compressed sound into a DAI signal and outputs the signal to an external device.
[0007]
FIG. 4 shows an amplifier with a built-in multi-channel audio full decoder as an example of an external device receiving the DAI signal 14 of FIG. An amplifier 59 with a built-in multi-channel audio full decoder inputs a DAI signal 61 from a DAI signal input terminal 60, and the DAI signal 61 is returned to 16-bit digital data 96 by an internal DAI decoder 62. The 16-bit digital data 96 is subjected to burst header detection and compressed voice burst main body extraction processing by a burst extraction circuit 95, and sent to a buffer RAM 64 as an output 63. The compressed audio full channel decoder 66 receives the compressed audio stream 65 from the buffer RAM 64 and decodes it to obtain FL (front left) / FR (front right) linear digital audio 67, SL (rear left) / SR (rear right) linear The digital audio 68 and the C (center) / SW (low frequency) linear digital audio 69 are output. The FL (front left) / FR (front right) linear digital sound 67 is converted into an analog FL (front left) sound 73 and an analog FR (front right) sound 75 by a 2ch DA converter 70, and SL (rear left) / SR (rear) The right) linear digital audio 68 is converted by a 2ch DA converter 71 into an analog SL (rear left) audio 77 and an analog SR (rear right) audio 79, and the C (center) / SW (low frequency) linear digital audio 69 is converted into a 2ch DA converter 72. Is converted into an analog C (center) sound 81 and an analog SW (low frequency) sound 83. The analog FL (front left) sound 73 is output to an output terminal 74, the analog FR (front right) sound 75 is output to an output terminal 76, the analog SL (rear left) sound 77 is input to an output terminal 78, and the analog SR (Rear right) audio 79 is input to an output terminal 80, analog C (center) audio 81 is output to an output terminal 82, and analog SW (low frequency) audio 83 is output to an output terminal 84.
[0008]
Thus, the multi-channel audio full decoder built-in amplifier 59 of the external device reproduces the multi-channel audio.
[0009]
[Problems to be solved by the invention]
FIG. 5A shows a burst transmission of AC-3 384 kbps at a sampling frequency of 48 kHz as a typical example of the prior art. On the other hand, in the prior art, it is further determined that another compressed sound having the same sampling frequency can be transmitted together with one DAI signal, and an example is shown in FIG. 5 (2). FIG. 5B shows an example in which a source A of AC-3 384 kbps with a sampling frequency of 48 kHz and a source B of 320 kbps of AC-3 with a sampling frequency of 48 kHz are transmitted by one DAI signal. The interval from the start of the burst of the source A to the start of the next burst of the source A is an interval of 3072 words, and the interval from the start of the burst of the source B to the start of the next burst of the source B is also an interval of 3072 words. As described above, the number of bursts can be increased until the dummy data area disappears. However, mixing different types of bursts was not envisioned.
[0010]
However, in the digital video disk, the compressed audio must be AC-3 of 5.1 channel compressed audio using 1024 points MDCT in the NTSC area, and 7.1 channel compressed audio MPEG using 32 equally divided polyphase filter banks. -2audio is optional, 5.1-channel compressed sound DTS (Digital Theater Sound) using 4-split filter and ADPCM, or 7.1-channel compressed sound SDDS (512-point MDCT using 512-point MDCT) Sony Digital Digital Sound is also defined as an option so that two or more types of compressed audio can be handled. Therefore, when it is desired to simultaneously reproduce each compressed audio read from the disk or to read and display parameters included in the compressed audio data without depending on the selection of the compressed audio of the digital video disk itself. It is necessary to transmit two or more types of compressed audio with one DAI signal.
[0011]
Here, FIG. 5 (3) shows burst transmission of AC-3 384 kbps at a sampling frequency of 48 kHz, and FIG. 5 (4) shows burst transmission of MPEG-1 audio layer2 384 kbps at a sampling frequency of 48 kHz. In AC-3, 1536 samples are in one compression unit, and in MPEG-1 audio, 1152 samples are in one compression unit. Therefore, the cycle is 3072 words in the AC-3 burst and 2304 words in the MPEG-1 audio burst. Become.
[0012]
When the two are arranged side-by-side and the timing is observed, there is a timing at which the two overlap as in the first compressed voice burst, so that even if there is room in the dummy data area, it cannot be easily accommodated in one DAI signal.
[0013]
According to the present invention, two types of compressed audio bursts having different periods are stored in one DAI signal and output, and the external device decodes both types of compressed audio without being affected by the switching of the compressed audio on the data reproducing apparatus side. The purpose is to make it possible to observe parameter information inside data and data.
[0014]
[Means for Solving the Problems]
A long section longer than the normal interval (T1) as a burst cycle of the first-type compressed voice corresponding to the length of the section from the top of the first-type compressed voice burst of the two types to the top of the next first-type compressed voice burst From (T1 + D1) and normal interval (T1) short A short interval (T1-D1) is provided, and a normal interval (T2) is set as a burst cycle of the second type compressed voice corresponding to the length of the section from the head of the second type compressed voice burst to the head of the next second type compressed voice burst. ) Longer interval (T2 + D2) and normal interval (T2) short A short section (T2-D2) is provided (D1> 0, D2> 0).
[0015]
Further, a mixing designating signal and a burst switching signal are provided, and when the mixing designating signal is invalid, only the compressed voice burst of the type selected by the burst switching signal is burst-transmitted at regular intervals (Tn) at regular intervals. When the mixed designation signal is valid, the compressed voice burst of the type selected by the burst switching signal is transmitted in bursts at a constant period of the normal interval (Tn), and simultaneously the compressed voice burst of the other type not selected is transmitted. On the other hand, a predetermined long section (Tn + Dn), a short section (Tn-Dn) and a normal interval (Tn) are adopted in a predetermined order (n is 1 or 2), and the type of the selected type is determined. The signals are arranged so as not to overlap with the compressed voice burst, mixed, and stored in one DAI signal.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows an example of a compressed voice burst mixing output device according to an embodiment of the present invention. In this example, a first-type compressed audio input terminal 1, a second-type compressed audio input terminal 4, and a first buffer RAM 3 for storing a first-type compressed audio stream 2 input from the first-type compressed audio input terminal 1 A second buffer RAM 6 for storing a second type compressed audio stream 5 input from a second type compressed audio input terminal 4; and a first type compressed audio 7 from the first buffer RAM 3 according to the burst switching signal 34. A burst selection circuit 9 for switching between the second type of compressed audio 8 from the two-buffer RAM 6, a burst head position signal 35 and a burst switching signal 34, and a burst for intermittently reading the compressed audio 10 and adding a burst header to the beginning. Encoder 1 that inputs a header addition circuit 11 for use with the output 12 from the header addition circuit 11 for burst and outputs a DAI signal 14 And a DAI signal terminal 15 receiving the output 14 of the DAI encoder 13, a first synchronization detection 22 for inputting the compressed audio stream 2 of the first kind and transmitting data 24 of the auxiliary information portion, and a data 24 of the auxiliary information portion. A first auxiliary information extracting circuit 21 composed of a first auxiliary information reading circuit 23 for inputting and outputting first auxiliary information 25, and a second type compressed audio stream 5 are input, and data 29 of an auxiliary information portion is input. A second auxiliary information extracting circuit 26 comprising a second synchronization detection 27 to be transmitted, a second auxiliary information reading circuit 28 for inputting data 29 of an auxiliary information part, and outputting second auxiliary information 30; A mixed mode input terminal 16, a burst designation signal input terminal 18, a heterogeneous burst mixed mode signal 17 from the heterogeneous burst mixed mode input terminal 16, A burst designation signal 19 from the constant signal input terminal 18 is inputted, first auxiliary information 25 and second auxiliary information 30 are inputted, and a mixed designation signal 31 and a code 32 indicating a sampling frequency of the compressed sound are output. A multiplexed burst output circuit 85 comprising a mode determination circuit 20, a timing generation circuit 33 which receives a mixed designation signal 31, a code 32 and a burst designation signal 19, and outputs a burst head position signal 35 and a burst switching signal 34. This is a compressed voice burst mixing output device composed of:
[0017]
Next, the operation will be described. The first type compressed audio stream 2 is input from the first type compressed audio input terminal 1, and the second type compressed audio stream 5 is input from the second type compressed audio input terminal 4. The input first-type compressed audio stream 2 is stored in the first buffer RAM 3, and the input second-type compressed audio stream 5 is stored in the second buffer RAM 6. A burst header adding circuit 11 intermittently reads the first-type compressed audio 2 from the first buffer RAM 3 in the form of a first-type compressed audio burst 7 and compresses the second-type compressed audio stream 5 from the second buffer RAM 6 into a second-type compression. Intermittent reading is performed in the form of an audio burst 8, and between the burst header adding circuit 11 and the first buffer RAM 3 and the second buffer RAM 6, the burst selection circuit 9 operates as a first type compressed audio burst 7 or a second type compressed audio burst. One of the eight is selected and sent to the burst header addition circuit 11. The burst header addition circuit 11 starts to input a compressed audio burst at a clock frequency dependent on the audio sampling frequency according to the burst head position signal 35, and the first type compressed audio or the second type compressed audio indicated by the burst switching signal 34. A burst header for voice is added to the head of the compressed voice burst 10 and output. The compressed audio stream 12 with the header for burst is encoded by the DAI encoder 13 into a DAI signal 14 at a clock frequency dependent on the sampling frequency of the audio, and is output to the DAI signal terminal 15.
[0018]
Here, the heterogeneous burst mixed mode signal 17 is inputted from the heterogeneous burst mixed mode input terminal 16, and the burst designation signal 19 is inputted from the burst designation signal input terminal 18 and supplied to the mode decision circuit 20. The mode determination circuit 20 reads the sampling frequency and the length of the compression basic unit from the information included in the first auxiliary information 25 and the second auxiliary information 30, and the code 32 indicating the sampling frequency indicates the code indicated by the burst designation signal 19. Output a code indicating the sampling frequency of. Here, the basic unit of the compressed audio is a conversion unit when compression encoding from a linear digital audio to a compressed audio stream is performed. For example, information indicating a bit rate, the number of channels, etc., which starts with a synchronization pattern, is entered one by one. , A time-frequency conversion coefficient for applying the psychoacoustic model in the frequency domain corresponds to only one set, and is the minimum unit that can be decoded.
[0019]
At the same time, the sampling frequency of the first-class compressed voice is equal to the sampling frequency of the second-type compressed voice, and the sum of the length of the compression basic unit of the first-type compressed voice and the length of the compression basic unit of the first-type compressed voice is The mixing designation signal 31 is output as valid only when the value is equal to or less than a predetermined value and the heterogeneous burst mixed mode signal 17 indicates valid.
[0020]
The timing generation circuit 33 generates four types of timings depending on the states of the mixed designation signal 31 and the burst designation signal 19. When the mixed designation signal 31 is invalid and the burst designation signal 19 indicates the first-type compressed voice, a burst head position signal 35 for transmitting the first-type compressed voice burst at a constant interval is output as shown in FIG. , The burst switching signal 34 keeps indicating the first type compressed voice. When the mixed designation signal 31 is invalid and the burst designation signal 19 indicates the second type compressed voice, as shown in FIG. 7, the burst head position signal 35 for transmitting the second type compressed voice burst at constant intervals is output. , The burst switching signal 34 is kept indicating the second type compressed voice.
[0021]
When the mixed designation signal 31 is valid and the burst designation signal 19 indicates the second type compressed voice, the second type compressed voice burst 122 in FIG. 8 (4) is constant as shown in FIGS. 8 (1) to 8 (5). In the burst transmission at intervals, the first-type compressed voice burst 121 in FIG. 8 (3) becomes non-constant-space burst transmission arranged at predetermined intervals so as not to overlap with the second-type compressed voice burst 122. The burst head position signal 35 shown in FIG. 8A and the burst switching signal 34 shown in FIG. 8B for outputting the compressed audio stream 12 with the burst header shown in FIG. In this example, when the burst switching signal 34 is "eH", the first kind of compressed sound is shown, and when it is "eL", the second kind of compressed sound is shown. Further, in this example, the rising position of the burst head position signal 35 is the start position of the 4-word header of the burst head. Here, the normal cycle of the first kind compressed sound is T1, the burst length is B1, the long section is (T1 + D1), the short section is (T1-D1), the normal cycle of the second kind compressed sound is T2, and the burst length is B2. In some cases, the long section of the compressed voice burst of the first kind is calculated by (T1 + D1) = T2 + (4 + B2) + (4 + B1). Since it is necessary to fall within the compressed voice bursts a and c, it is checked in advance whether T1 + (4 + B1) ≦ 2 × T2− (4 + B2) is satisfied.
[0022]
When the mixed designation signal 31 is valid and the burst designation signal 19 indicates the first-type compressed voice, as shown in FIGS. 9A to 9C, the first-type compressed voice burst 123 of FIG. In the burst transmission at a constant interval, the second type compressed voice burst 124 in FIG. 9 (4) becomes a non-constant interval burst transmission arranged at a predetermined interval so as not to overlap with the first type compressed voice burst 123. A burst head position signal 35 shown in FIG. 9A and a burst switching signal 34 shown in FIG. 9B for outputting the compressed audio stream 12 with a burst header 9 (5) are output. . Here, the normal cycle of the first kind compressed voice is T1, the burst length is B1, the normal cycle of the second kind compressed voice is T2, the burst length is B2, the long section is (T2 + D2), and the short section is (T2-D2). At one time, the short section of the second type compressed voice burst is calculated by (T2−D2) = T1− (4 + B2) − (4 + B1). Since it is necessary to fall within b and c of the compressed voice burst of the first kind, it is checked in advance whether 2 × (4 + B2) + (4 + B1) ≦ T1 is satisfied.
[0023]
In the example of FIG. 8, the normal section (T1) is performed once, the long section (T1 + D1) is performed once, and the short section (T1-D1) is performed once. In the example of FIG. 9, the long section (T2-D2) is performed once. Burst mixing is realized in the order of one normal section (T2), one short section (T2-D2), and one normal section (T2). As a result, two types of compressed audio bursts can be output with one DAI signal without overlapping.
[0024]
As a result, in the external device, two types of compressed audio bursts are simultaneously reproduced, or compressed audio is decoded and reproduced at regular intervals, and compressed audio at non-constant intervals is included in the compressed audio burst. Processing such as extracting and displaying parameter information can be performed.
[0025]
Here, FIG. 10 shows an example of a calculation procedure of preconditions regarding the length of one compressed speech burst among the predetermined length and order of the long section and the short section, and one of the conditions for specifying the mixture. . Beginning with the start of the calculation in the calculation start step 301, first in step 304, the normal cycle of the first kind compressed voice is T1, the burst length is B1, the long section (T1 + D1), the short section is (T1-D1), and the second kind compression is performed. Assuming that the normal period of the voice is T2, the burst length is B2, the long section is (T2 + D2), and the short section is (T2-D2), numerical values are substituted into T1, T2, B1, and B2 (where T1> T2. Set the first type and the second type). Then, natural numbers M1 and M2 (M1 <M2) satisfying M1 × T1 = M2 × T2 are obtained. For example, if T1 = 3072 and T2 = 2304, M1 = 3 and M2 = 4. Next, in step 305, recognition symbols are assigned to the M1 first-type compressed voice bursts that are continuous and the M2 second-type compressed voice bursts that are continuous. For example, when M1 = 3 and M2 = 4, three consecutive first-type compressed audio bursts are a1, b1 and c1, and four consecutive second-type compressed audio bursts are a2, b2, c2 and d2. In step 306, it is selected whether to calculate the first type or the second type of the compressed voice burst to be transmitted at a constant interval. In the case of calculation for transmitting the first type at regular intervals, the process proceeds to step 307, where the burst b2 is arranged immediately after the burst b1, and the burst c2 is arranged immediately before the burst c1. As a result, the interval between the burst b2 and the burst c2 is a short section (T2-D2), and the position is also determined as a relative position with respect to the first-type compressed voice burst transmitted at a constant interval. Next, in step 308, the burst a2 is arranged at a timing position earlier than the burst b2 by a period T2, and the burst d2 is arranged at a timing position later than the burst c2 by a period T2. Thus, the normal period (T2) is between the bursts a2 and b2, the normal period (T2) is between the bursts c2 and d2, and the long interval (T2 + D2) is between the remaining bursts d2 and a2. The position is also determined as a relative position with respect to the first-type compressed voice burst transmitted at a constant interval. This leads to the determination of the burst position in step 303.
[0026]
Also, in step 306, when the calculation for transmitting the second type at a fixed interval is selected, the process proceeds to step 310, where the burst b2 is arranged immediately before the burst c2 and the burst c2 is arranged immediately after the burst c1. As a result, the interval between the burst b1 and the burst c1 becomes a long section (T1 + D1), and the position is also determined as a relative position to the second-type compressed voice burst transmitted at a constant interval. Next, in step 311, the burst a1 is arranged at a timing position earlier than the burst b1 by the period T1. As a result, the period between the burst a1 and the burst b1 is a normal period (T2), and the period between the burst c1 and the burst a1 is a short period (T1-D1). It is determined as a relative position. This leads to the determination of the burst position in step 303. Further, in step 309, each numerical value is substituted into the formula of T1 + (4 + B1) ≦ 2 × T2- (4 + B2) of the mixing precondition, and the relational expression of the burst lengths B1 and B2 is used to determine the burst length condition for mixing designation in step 302. Reach.
[0027]
By calculating in advance before designing the timing generation circuit 33 in such a procedure, the actual circuit only needs to perform switching of some preset timings. Is achieved.
[0028]
FIG. 15 shows an example in which a normal interval section is not provided. Steps 316 and 308 are provided instead of step 316 and step 308, and steps 314 and 315 are provided instead of step 311. In step 312 following step 307, the basic unit DIST2 for shifting the position of the second-type compressed audio burst is calculated by the equation DIST2 = {T1- (4 + B1)-(4 + B2)} / 3. Next, in step 313, the head of the burst a2 is arranged at a timing position delayed by DIST2 from the end point of the burst a1, and the head part of the burst d2 is arranged at a timing position delayed by DIST2 × 2 from the end point of the burst c1. . As a result, the interval between the bursts a2 and b2, the interval between the bursts c2 and d2, the interval between the bursts d2 and a2 are equal to each other, and the burst interval is different from the normal interval (T2).
[0029]
In step 314 subsequent to step 310, the basic unit DIST1 for shifting the position of the compressed voice burst of the first kind is calculated by the equation DIST1 = {T2- (4 + B1)-(4 + B2)} / 2. Next, in step 314, the head of the burst a1 is arranged at a timing position delayed by DIST1 from the end point of the burst a2. As a result, the interval between the burst a1 and the burst b1 and the interval between the burst c1 and the burst a1 are equal to each other, and the burst interval is different from the normal interval (T1).
[0030]
In step 316 subsequent to step 304, since the normal interval need not be adopted, the mixing precondition is (4 + B1) + 2 × (4 + B2) ≦ T1, and each numerical value is substituted. As a relational expression of the lengths B1 and B2, a burst length condition for mixing designation is determined in step 302.
[0031]
According to such a procedure, the present invention can also be realized at a preset timing.
[0032]
FIGS. 11 (1) to 11 (5) are examples in which the mixed designation signal 31 is valid and the burst designation signal 19 indicates the first-type compressed voice at another bit rate. Here, the first type compressed voice burst 125 (48 kHz, AC-3, 320 kbps, unit = 1536 sample) has a length (B1) of 640 words (word = 16 bits), a normal period (T1) of 3072 words, and a second type compressed voice burst. 126 (MPEG-2 audio layer 2 with Multichannel Extension, 704 kbps, unit = 1152 sample) has a length (B2) of 1056 words (word = 16 bits) and a normal cycle (T2) of 2304 words. In this example, three first-type compressed voice bursts and four second-type compressed voice bursts have a common length (M1 = 3, M2 = 4), but two out of four second-type compressed voice bursts Are already set in advance according to the procedure shown in FIG. 10, one long section (T2 + D2), one normal section (T2), one short section (T2-D2), and one section of the normal section. (T2) Burst mixing is realized in one order. From the formula of short section (T2-D2) = T1- (4 + B1)-(4 + B2), the short section (T2-D2) = 1368, D2 = 936, and the long section (T2 + D2) = 3240, which are the conditions necessary for the mixture designation. Since b and c of the second-type compressed voice burst need to be inside the b and c of the first-type compressed voice burst, B1 + 2 × B2 ≦ from the expression 2 × (4 + B2) + (4 + B1) ≦ T1. 3060 (unit: word).
[0033]
In the above example, the length of the predetermined long section of the burst, the length of the short section of the burst, and their order are different from those calculated using the largest bit rate that can be considered as an input. It is possible to respond to the input of the bit rate with one timing. For example, if AC-3 of the first-class compressed audio is specified in the range of 64-384 kbps and MPEG-2audio of the second-type compressed audio is specified in the range of 64-736 kbps, the AC-3 of the first-type compressed audio is specified. If the timing is set in advance using the maximum bit rate of 384 kbps and the maximum bit rate of the second kind compressed audio in MPEG-2 audio of 736 kbps, it is possible to cope with all bit rates lower than that. FIGS. 12 (1) to 12 (5) show the timings when the mixed designation signal 31 is valid and the burst designation signal 19 indicates the first type compressed voice, and the first type is AC-3 384 kbps. The signal 127 shown in FIG. 12 (3) is obtained by mixing the compressed audio (T1 = 3072, B1 = 768) and the second type compressed audio (T2 = 2304, B2 = 1104) of MPEG-2 audio 768 kbps. 12 (1), and the burst switching signal 34 is shown in FIG. 12 (2).
[0034]
On the other hand, there is an example in which the first type compressed audio (T1 = 3072, B1 = 640) of 320 kbps AC-3 and the second type compressed audio (T2 = 2304, B2 = 1104) of MPEG-2 audio 768 kbps are mixed. FIG. 12 (4) shows a first-type compressed audio (T1 = 3072, B1 = 768) of AC-3 384 kbps and a second-type compressed audio (T2 = 2304, B2 = 576) of MPEG-2 audio 384 kbps. An example of mixing is shown in FIG. As is apparent from these figures, mixing can be performed without any problem at all bit rates in the variable range only by changing the gap after each burst.
[0035]
Here, from the formula of short section (T2-D2) = T1- (4 + B1)-(4 + B2), short section (T2-D2) = 1192, D2 = 1111, long section (T2 + D2) = 3416, and A necessary condition is that b and c of the second-type compressed voice burst need to be inside of b and c of the first-type compressed voice burst, so that B1 + 2 is obtained from the formula of 2 × (4 + B2) + (4 + B1) ≦ T1. × B2 ≦ 3060 (unit: word).
[0036]
FIG. 13 shows an example in which the present invention is applied to a digital video disk reproducing apparatus, in which the multiplex burst output circuit 85 in FIG. 1 is provided inside.
[0037]
In this example, a recording medium disk 91 on which a multiplexed data stream has been recorded in advance, a reader 37 that reads the multiplexed data stream from the recording medium disk 91 and outputs the multiplexed data stream as a reproduced data stream 92, and a reproduced data stream 92, A demodulation circuit 39 that outputs a demodulated stream 93; a stream separation circuit 94 that extracts and outputs the compressed image stream 42, the first-type compressed audio stream 2, and the second-type compressed audio stream 5 from the demodulated stream 93; A video signal processing circuit 56 that receives the compressed image stream 42 and outputs a video signal 57, a video output terminal 58 that receives the video signal 57, and an audio decoder that receives the first-class compressed audio stream 2 and performs 2ch decoding processing 53 and the output from the audio decoder 53 4 a digital stereo audio output terminal 55 for receiving a, and a multi-burst output circuit 85.
[0038]
Next, the operation will be described. The reproduction data stream 92 read from the recording medium disk 91 by the reader 37 is demodulated by the demodulation circuit 39 and becomes a demodulated stream 93. From the demodulated stream 93, the compressed image stream 42, the first-type compressed audio stream 2, and the second-type compressed audio stream 5 are extracted by the stream separation circuit 94. The compressed image stream 42 is decoded by a video signal processing circuit 56 and is sent to a video output terminal 58 as a video signal 57. The first-type compressed audio stream 2 is subjected to 2ch decoding processing by the audio decoder 53, and sent to a digital stereo audio output terminal 55 as a 2ch output 54. At the same time, the first-type compressed audio stream 2 and the second-type compressed audio stream 5 are input to the multiplex burst output circuit 85, and thereafter operate in the same manner as that shown in FIG.
[0039]
In this way, the present invention as shown in FIG. 1 can be applied to a digital video disk reproducing apparatus.
[0040]
As an external device for the digital video disc reproducing apparatus shown in FIG. 13, an amplifier having two kinds of compressed audio decoders as shown in FIG. 14 can be considered. The amplifier 86 receives the DAI signal 61 from the DAI signal input terminal 60, and the DAI signal 61 is returned to 16-bit digital data 96 by the internal DAI decoder 62. The 16-bit digital data 96 is subjected to burst header detection and compressed audio burst main body extraction processing by a burst extraction circuit 87, and is output as a first-type compressed audio burst 63 and a second-type compressed audio burst 88. The first-type compressed audio burst 63 is sent to the first buffer RAM 64, and the second-type compressed audio burst 88 is sent to the second buffer RAM 89. The first-type compressed audio full-channel decoder 66 reads the first-type compressed audio stream 65 from the first buffer RAM 64, decodes it, and outputs three first digital 2ch linear audio 203 and first parameter information 202. The second kind compressed audio full channel decoder 201 reads out the first kind compressed audio stream 90 from the second buffer RAM 89, decodes it, and outputs three second digital 2ch linear sounds 205 and second parameter information 204. The parameter display circuit 206 inputs the first parameter information 202 and the second parameter information 204 and displays them. The audio output selection circuit 209 receives the output switching signal 208 input from the output switching signal input terminal 207, and outputs the three first digital 2ch linear audio 203 and the three second digital 2ch linear audio 205. One of the output switching signals 208 is sent to the 2ch DA converters 70, 71, 72. The 2ch DA converter 70 converts the sound into an analog FL (front left) sound 73 and an analog FR (front right) sound 75. The 2ch DA converter 71 converts the sound into an analog SL (rear left) sound 77 and an analog SR (rear right) sound 79. The 2ch DA converter 72 converts the signal into an analog C (center) sound 81 and an analog SW (low frequency) sound 83 and outputs the converted sound.
[0041]
In this way, the external device simultaneously reproduces both the essential compressed audio (AS-3) and the optional compressed audio (MPEG-1 audio), or decodes and reproduces the compressed audio at a fixed interval, and performs non-constant decoding. For the compressed voice at the interval, processing such as extracting and displaying parameter information (number of channels, bit rate, extended stereo mode, etc.) included in the compressed voice burst can be performed.
[0042]
【The invention's effect】
Different types of compressed audio bursts can be stored in a single DAI signal for external output. This allows simultaneous playback of two different types of compressed audio with an external full-decoder-incorporated device, etc., without depending on the selection of compressed audio by a compressed audio signal playback device that does not have a compressed audio simplified version decoder or a compressed audio full decoder. It is possible to display the parameter data included in each compressed audio stream without performing the reproduction.
[Brief description of the drawings]
FIG. 1 is a block diagram of a compressed audio mixed burst output device to which the present invention is applied.
FIG. 2 is an explanatory diagram of a DAI signal conforming to IEC958 and burst transmission according to the related art using the DAI signal.
FIG. 3 is a block diagram of a conventional data reproducing apparatus including compressed audio.
FIG. 4 is a block diagram of a device with a built-in compressed audio full decoder as an external device with respect to a conventional data reproducing device including compressed audio.
FIG. 5 is a burst timing chart of transmission of a plurality of bursts and bursts of different types according to the related art.
FIG. 6 is a burst transmission timing chart when a heterogeneous mixed mode is invalid (normal mode) and burst selection is a first type in the present invention.
FIG. 7 is a burst transmission timing chart when the heterogeneous mixed mode is invalid (normal mode) and burst selection is the second type in the present invention.
FIG. 8 is a burst transmission timing chart when a heterogeneous mixed mode is valid (normal mode) and burst selection is a second type in the present invention.
FIG. 9 is a burst transmission timing chart when the heterogeneous mixed mode is valid (normal mode) and the first type of burst is selected in the present invention.
FIG. 10 is a flowchart of a procedure for calculating a long section, a short section, and their order in the present invention.
FIG. 11 is a burst transmission timing chart when the heterogeneous mixed mode is valid (normal mode) and burst selection is the first type in the present invention.
FIG. 12 is an explanatory diagram in a case where there are several possible bit rates in the present invention and the timing is calculated in advance at the maximum rate among them.
FIG. 13 is a block diagram of an embodiment in which the present invention is applied to a digital video disc reproducing apparatus.
FIG. 14 is a block diagram of an amplifier with a built-in decoder that may appear in the future as an external device for a digital video disc reproducing apparatus to which the present invention is applied.
FIG. 15 is a flowchart of a procedure for calculating a long section, a short section, and their order in the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... 1st kind compressed sound input terminal, 3 ... 1st buffer RAM, 4 ... 2nd kind compressed sound input terminal, 6 ... 2nd buffer RAM, 9 ... burst selection circuit, 11 ... burst addition circuit, 13 ... DAI encoder, 15: DAI signal terminal, 16: heterogeneous burst mixed mode input terminal, 18: burst designation signal input terminal, 20: mode determination circuit, 33: timing generation circuit.

Claims (5)

A compressed audio burst output method of inputting a first-type compressed audio stream and a second-type compressed audio stream, bursting the two types of compressed audio streams, and outputting digital data at a clock frequency depending on a sampling frequency of the audio. ,
The compressed voice burst selected by the burst selection signal is transmitted at a constant interval, and the other compressed voice burst is a regular interval having a constant interval, a long section longer than the normal section, and a short section shorter than the normal section. It is assumed that the digital data is output at a clock frequency dependent on the sampling frequency of audio by performing time-division multiplexing so that the two types of compressed audio bursts do not overlap with each other so that the two types of compressed audio bursts do not overlap with each other. Characteristic compressed voice burst output method. The compressed voice burst output method according to claim 1,
The length (B1) word (1 word = 16 bits) of the basic compression unit of the first-type compressed audio corresponds to a period from the synchronization pattern of the first-type compressed audio stream to the next synchronization pattern. Assuming that the length from the synchronization pattern of the stream to the next synchronization pattern corresponds to the length (B2) word of the compression basic unit of the second type compressed voice, the sampling frequency for the first type compressed voice and the second A compressed audio burst output method that requires that the sampling frequencies for the two types of compressed audio are equal and B1 and B2 are smaller than a predetermined value. 3. The compressed voice burst output method according to claim 1 or 2,
With respect to the long section and the short section, the normal transmission cycle of the first-type compressed voice burst is (T1) word, and the normal transmission cycle of the second-type compressed voice burst is (T2). ) Word (T1> T2), the long section of the first type compressed voice burst is (T1 + D1) word, the short section is (T1-D1) word, and the long section of the second type compressed voice burst is (T2 + D2) word. , When the short section is (T2-D2) word,
D1 is determined so that (T1 + D1) = T2 + (4 + B2) + (4 + B1),
D2 is determined such that (T2−D2) = T1− (4 + B1) − (4 + B2), and
A long section (T1 + D1) of the first type compressed voice burst, a short section (T1-D1) of the first type compressed voice burst, a long section (T2 + D2) of the second type compressed voice burst, and the second type A compressed voice burst output method in which a short section (T2-D2) of the compressed voice burst is determined in advance. 4. The compressed audio burst output method according to any one of claims 1 to 3,
The normal transmission cycle of the first-type compressed voice burst is (T1) word, the normal transmission cycle of the second-type compressed voice burst is (T2) word (T1> T2), and the least common multiple of T1 and T2 is When T1 × M1 (= T2 × M2) (M1 and M2 are natural numbers and M1 <M2), at least (M2−M1) of the M1 first-type compressed voice bursts of the consecutive ones As for the seed compressed voice burst, the above-mentioned second kind compressed voice burst is arranged immediately adjacent thereto, and at least (M2-M1) of the first kind compressed voice bursts among the M1 number of said first kind compressed voice bursts are consecutive. A compressed audio burst output method in which the timing is set in advance such that the second type compressed audio burst is arranged immediately before the audio burst. First buffer storage means for storing a first-type compressed audio stream that has been compression-coded according to the first-type compressed audio standard,
Second buffer storage means for storing a second-type compressed audio stream that has been compression-encoded by the second-type compressed audio standard,
Burst selection means for selecting and outputting one of the input from the first buffer storage means and the input from the second buffer storage means in accordance with a burst switching signal, and a burst head position signal indicating a timing at which burst reading is started. The signal is read out intermittently from the burst selecting means into a burst form, and a header including data indicating a burst length or the like at the head thereof is suitable for the type of compressed voice in which the burst switching signal indicates. A burst header addition circuit to add in the form
A digital audio encoding means for converting a signal from the burst header addition circuit into a signal to which a synchronization word, a parity or the like is added at a clock frequency dependent on a sampling frequency of the audio; At
A heterogeneous burst mixed mode input means for further inputting a heterogeneous burst mixed mode signal;
Burst designation signal input means for inputting a burst designation signal;
First auxiliary information extracting means for extracting an information portion necessary for determining the sampling frequency or the length of the compression basic unit or the length of the compression basic unit from the first type compressed audio stream and outputting the extracted information as first auxiliary information; ,
Second auxiliary information extracting means for extracting an information portion necessary for determining the sampling frequency and the length of the compression basic unit or the length of the compression basic unit from the second type compressed audio stream and outputting the extracted information as second auxiliary information; ,
The heterogeneous burst mixed mode signal, the burst designation signal, the first auxiliary information, and the second auxiliary information are input, and the sampling frequency of the first type of compressed audio and the sampling frequency of the second type of compressed audio are input. , The mixed designation signal is output as valid only when the heterogeneous burst mixed mode signal indicates valid, otherwise, the mixed specified signal is output as invalid, and the compressed voice indicated by the burst specified signal is also output. Mode determining means for outputting a code indicating a sampling frequency for
When the mixed designation signal indicates invalid, a timing signal for reading out the compressed audio stream of the first type compressed audio stream and the compressed audio stream of the second type compressed audio stream indicated by the burst designation signal at regular intervals. And outputs the burst start position signal
When the mixed designation signal indicates validity, the compressed audio stream indicated by the burst designation signal is read out at regular intervals, and the burst interval is determined for the compressed audio stream not indicated by the burst designation signal. The constant interval is a normal interval, a long interval longer than the normal interval, and a short interval shorter than the normal interval are changed in a predetermined order so that the two types of compressed voice bursts do not overlap with each other. A compressed audio burst output device comprising: a burst head position signal that is a timing signal for time division multiplexing; and a timing generation unit that outputs a burst switching signal.

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