NL8901402A - Wide-band digital transmission system using transmitter and receiver - sending wide-band digital signal and producing second digital signal that contains multiple of information packets in consecutive frames - Google Patents

Abstract

The system includes a transmitter for sending a wide-band digital signal through a medium and a receiver with input terminal int transmitter coupled to the signal source input. It is arranged to generate a second digital signal and provide an output that includes a multiple of information packets containing N bits. The receiver includes a decoder with input for receiving the second digital signal and provides an output to supply the wide-band digital signal.

Description

N.V. Philips' Incandescent lamp factories in Eindhoven.

Digital transmission system, transmitter and receiver to be used in the transmission system and record carrier obtained with the transmitter in the form of a recording device.

The invention relates to a digital transmission system with a transmitter and a receiver for transmitting via a transmission medium and receiving a broadband digital signal with a certain sampling frequency Fg, for example a digital audio signal, the transmitter being provided with an input terminal for receiving the broadband digital signal, which input terminal is coupled to an input of a signal source belonging to the transmitter which is arranged to generate and supply an output of a second digital signal, which is composed of successive frames, each frame is composed of a number of information packets, each information pack containing N bits where N is greater than 1, the receiver being provided with a decoder having an input for receiving the second digital signal, which decoder having an output which is coupled with an output terminal for outputting the broadband digital si The invention also relates to a transmitter and a receiver for use in the transmission system, a transmitter in the form of a device for recording the second digital signal in a track on a record carrier, a record carrier obtained with the transmitter, and a receiver in the form of a device for reading the second digital signal from the track on the record carrier. A transmission system of the type mentioned in the preamble.

kind, is known from the article "The Critical Band Coder _ Digital

Encoding of Speech signals based on the Percentual requirements of the Auditory System by ME Krasner in Proc. IEEE ICASSP 80, Vol 1, pp 327.331, April 9-11, 1980. Although this concerns a transmission system in which the transmitter is used of a subband encoding system and in the receiver a corresponding subband decoding system, the invention is not, however, limited to such an encoding system, as will appear later.

The system known from the aforementioned publication uses a division of the speech signal band into a number of sub-bands, the bandwidths of which correspond approximately to the bandwidths of the critical bands of the human ear in the respective frequency ranges (compare Fig. 2 in Krasner's article). This division has been chosen because, based on psychoacoustic experiments, it can be expected that the quantization noise in such a subband will be optimally masked by the signals in this subband, when the noise-masking curve of the human ear is taken into account in the quantization. this curve gives the threshold value for masking noise in a critical band by a single tone in the center of the critical band (compare Fig. 3 in Krasner's article).

In the case of a high quality digital music signal, which according to the Compact Disc standard is represented with 16 bits per signal sample at a sampling frequency of 1 / T = 44.1 kHz, it appears that the application of this known sub-band encoding with an appropriate selected bandwidth and an appropriately selected quantization for the respective sub-bands results in quantized coder outputs that can be presented with an average number of about 2.5 bits per signal sample, while the quality of the music signal replica does not discernably differ from that of the original music signal in almost all passages of almost all kinds of music signals.

The subbands do not necessarily correspond to the bandwidths of the critical bands of the human ear. It is also possible that the subbands have a different bandwidth, for instance all the same bandwidth, provided that this is taken into account when determining the masking threshold.

The invention now aims to provide a number of measures for the transmission system, in particular a very specific choice for the format with which the digital broadband signal, after conversion to the second digital signal, can be transmitted via the transmission medium, such that a flexible and m.in or more universally usable transmission system is obtained. This means that the transmitter is capable of broadband digital signals of different formats (these formats are distinguished, inter alia, by the sampling frequency Fg of the broadband digital signal, which may have different values, such as 32 kHz, 44.1 kHz and 48 kHz, as defined in the digital audio interface standard of the AES and the EBU) to the second digital signal. Likewise, the receiver is able to derive the correct format of broadband signal from this second digital signal. To this end, the transmission system according to the invention is characterized in that, if P in the formula

where BR is the bit rate of the second digital signal, and ns is the number of samples of the broadband digital signal, of which the corresponding information belonging to the second digital signal is contained in one frame of the second digital signal, a whole number, the number of information packets B in one frame is P, and that, if P is not an integer, the number of information packets in some of the frames is P ', where P' is the next lower on P integer, and the number of information packets in the other frames is equal to P '+ 1, such that the requirement that the average frame rate of the second digital signal is substantially equal to Fs / ns, that a frame is exactly is composed of at least a first frame portion, containing synchronization information and information related to the number of information packets in the frame. The purpose of dividing the frames into B information packets is that the average frame rate of the second digital signal broadcast by the transmitter for a broadband digital signal with any sampling frequency Fg is now such that the duration of a frame in the second digital signal corresponds to the length of time ng samples of the broadband signal take. In addition, it makes it possible to maintain the synchronization on an information packet basis, which is simpler and more reliable than maintaining the synchronization on a bit basis. Thus, in those cases where P is not an integer, the sender is capable of providing a frame with P '+ 1 instead of P' information blocks at those times when it is possible and necessary, so that the average frame rate of the second digital signal equivalent to Fg / nS 9e} iOU, 3en. Because in this case the synchronization information (synchronization signals or synchronization words) included in the first frame part of successive frames are spaced a whole number of times the length of an information packet, it is thus possible to maintain the synchronization on an information packet basis. The first frame portion also contains information related to the number of information packets in a frame. In a frame with B information packets, that information may be equal to the value B. This means that this information for frames with P 'information packets corresponds to P' and for frames with P '+ 1 information packets corresponds to P' + 1. Another possibility is that for all frames this information corresponds to P ', regardless of whether a frame contains P' or P '+ 1 information packets. The extra added (P '+ 1) information package can, for example, only consist of' zeros', in which case this information package does not contain any useful information. If necessary, the additional information package can of course also be filled with useful information. The first frame portion may further contain system information. This includes, for example, the sampling frequency Fg of the broadband digital signal offered to the transmitter, copy protection codes, the type of signal that is presented to the transmitter as a broadband digital signal, such as a stereo audio signal or a mono audio signal, or is it digital signal composed of two more or less independent audio signals.

However, other system information is also possible, as will be shown later in the description. By sending the system information, it is possible to allow the receiver to be flexible and to correctly convert the received second digital signal back to the broadband digital signal. The second and third frame portion of a frame contains signal information. The transmitter may comprise a transmission system as claimed in or, wherein the transmitter is provided with a coder-containing signal splitting means for generating a second digital signal in the form of a number of M sub-signals in response to the broadband digital signal, M being larger is then 1, and comprising means for quantizing the respective sub-signals. One can think of a random transform coding, such as a fast fourier transform (FFT). In that case, the transmission system is characterized in that the second frame part of a frame contains allocation information indicating for at least some of the sub-signals the number of bits with which the samples of the quantized sub-signals obtained from those sub-signals are displayed, and that the third frame portion contains the samples of at least these quantized sub-signals (if any). On the receiving side, an inverse transform coding, i.e. an inverse fourier transform (IFFT) must then be performed for the recovery of the broadband digital signal. It. transmission system, wherein the signal splitting means are in the form of analysis filtering means for generating a plurality of M sub-band signals in response to the broadband digital signal, the analysis filtering means dividing the signal band of the broadband digital signal with sampling rate reduction into successive sub-bands having band numbers m which increase with the frequency, and the quantizing means are arranged for blockwise quantization of the respective sub-band signals, is a system using sub-band coding as previously discussed. Such a transmission system is further characterized in that the allocation information in the second frame part of a frame for at least some of the subband signals indicates the number of bits with which the samples of the quantized subband signals obtained from those subband signals are displayed, and that the third frame portion contains the samples of at least these quantized subband signals (if any). Thus, this basically means that the allocation information is stored in a frame before the samples. This allocation information is necessary in order to be able to subdivide the continuous serial bitstream of the samples in the third frame part on the receiving side into the various individual samples with the correct number of bits. The allocation information may mean that all samples are represented with a fixed number of bits per subband per frame. In this case we speak of a transmitter that is based on a fixed bit allocation (fixed or static bit allocation).

The allocation information may also imply that for a subband over time a variable number of bits is used for the samples in those subbands. In that case we speak of a transmitter that is based on the system of an adaptive or dynamic bit allocation. The fixed and adaptive bit allocation is described, inter alia, in the publication "Low bit-rate coding of high quality audio signals. An introduction to the MASCAM system" by G. Theile et al, from EBü Technical review, no. 230 (August 1988). Placing the allocation information in front of the samples in a frame has the advantage of allowing easier decoding on the receiving side which can be performed in real time and gives rise to only a small signal delay due to the decoding. Namely, this sequence makes it unnecessary to first store all information in the third frame part in a memory in the receiver. Upon entry of the second digital signal, the allocation information is stored in a memory in the receiver. The information content of the allocation information is much smaller than the information content of the samples in the third frame part, so that a much smaller memory suffices than if all samples were to be stored in the receiver. Immediately upon entering the serial data stream of the samples in the third frame portion, this data stream can be divided into the different samples by the number of bits defined by the allocation information, so that no storage of the signal information is required in advance. Allocation information for all subbands can be included in a frame. This is not necessary, as will become clear later.

The transmission system may further be characterized in that the third frame portion additionally includes scale factors, a scale factor associated with at least one of the quantized subband signals stored in the third frame portion, and the scale factors before the quantized subband signals in the third frame portion. The samples can be encoded in the transmitter without being normalized, i.e. without the amplitudes of a block of samples in a subband divided by the amplitude of the sample with the largest amplitude in this block. In that case, no scale factors are required. If the samples are normalized during coding, scale factors must be included, which are a measure of the largest amplitude mentioned. In this case, too, by storing the scale factors before the samples in the third frame part, the possibility is created upon receipt to store these scale factors first in a memory and immediately upon receipt, the samples immediately, with the reverse value of these multiply scale factors. It goes without saying that a scale factor such as that stored in the third frame part can also already be the inverse value of the amplitude of the largest sample in a block, so that the determination of the inverse value can be omitted in the receiver and thus a faster decoding is possible.

Furthermore, it goes without saying that if after quantization in the transmitter the subband signal in a subband is equal to zero, which will of course be apparent from the allocation information for the subband, no scaling factor for that subband needs to be transmitted. The transmission system in which the receiver is provided with a decoder-containing synthesis filtering means for constructing a replica of the broadband digital signal in response to the respective quantized subband signals, which synthesis filtering means combining the subbands with sampling rate increase into the signal band of the broadband digital signal, may be characterized , in that the samples of the subband signals (if any) are stored in an order in the third frame portion corresponding to the order in which these samples are presented to the synthesis filter means upon receipt in the receiver. By storing the samples in the third frame portion in the same order as with which they are added in the receiver to the synthesis filter means, a rapid decoding is also realized, whereby again no additional storage is required in the receiver of the samples before they can be further processed. processed. The amount of memory required in the receiver can thus be limited to mainly memories for the storage of the system information, the allocation information and possibly the scaling factors. In addition, there is a limited signal delay which is mainly due only to the signal processing on the samples. The allocation information for the different quantized subband signals is preferably stored in the same order in the second frame portion as the order in which the samples of these subband signals are stored in the third frame portion. The same applies to the order of the scale factors. If desired, one could also quarter the frames, the first, second and third frame parts being as before. explained. The last (fourth) frame portion in the frames may then contain error detection and / or error correction information. After receiving this information in the receiver, it is possible to correct for errors occurring during the transmission in the second digital signal. As mentioned earlier, the broadband digital signal can be a mono signal. The broadband digital signal may also be a stereo audio signal composed of a first (left) and a second (right) signal portion. If the transmission system is based on a subband coding system, the transmitter supplies subband signals, each consisting of a first and a second subband signal part, which after quantization in the quantizing means are converted into first and second quantized subband signal parts. Also in this case, allocation information and information about the scale factors (if the samples in the transmitter are scaled) should be included in the frames. The sequence is also important here. Such a transmission system is therefore the subject of claims 10 to 14. It goes without saying that the system is expandable to a broadband digital signal that consists of more than two signal parts.

The measures according to the invention can be applied in digital transmission systems, such as transmission of digital audio signals (digital audio broadcast) over the air. However, other applications are also possible. This could include a transmission via optical or magnetic media. Optical media may include transmission via glass fibers or by means of optical plates or tapes. Magnetic media can be a magnetic plate or magnetic tape. In one or more tracks of a record carrier, such as an optical or magnetic plate or a magnetic tape, the second digital signal is then stored in the format as proposed according to the invention.

The universality and flexibility of the transmission system is thus based on the special format with which the information in the form of the second digital signal is transmitted, for example via a record carrier. This combined with the special version of the transmitter that can generate this special format for different types of input signals. The transmitter generates the system information required for each type of signal and inserts it into the data stream to be sent. On the receiving side, this delivers with a specific receiver, which splits off that system information from the data stream and uses it for correct decoding.

The invention will be explained in more detail by means of a number of exemplary embodiments in the figure description below. Figure 1 shows the second digital signal generated by the transmitter, which is built up of frames, each frame being built up again from information packets. Figure 2 the construction of a frame, figure 3 the construction of the first frame part of a frame, figure 4 an example of the transmission system, Fig. 5 is a table indicating the number of information packets B in a frame, for certain values for the bit rate BR and the sampling frequency F_, Fig. 6 for a number of values for the bit rate BR, the number of frames in a "padding" sequence and the number of frames thereof containing an additional information packet (dummy slot), figure 7 the system information included in the first frame part of a frame, figure 8 the distribution of the digital information over the different (two) channels for a number of modes, figure 9 the meaning of the allocation information as it is included in the second frame part, figures 10 and 11 the order of storage of the allocation information in the second frame part, for two formats, format A resp. format B, figure 12 an example of a receiver, figure 13 the transmitter, in the form of a device for recording the second digital signal on a magnetic record carrier, figure 14 in the receiver the form of a device for displaying the second digital signal from a magnetic record carrier, FIG. 15 in FIGS. 15a to 15d some other storage options of the scale factors and the samples in the third frame portion of a frame, and.

figure 16 shows a further elaboration of the transmitter.

Figure 1 schematically shows the second digital signal as it is generated by the transmitter and via it. transmission medium is sent. The second digital signal is in the form of a serial digital data stream. The second digital signal is made up of frames, two of which, frame j and frame j + 1, are shown in figure 1a. The frames, such as frame j, contain a number of information packets IP1, IP2, IP3, ... see figure 1b. Each information packet, such as IP3, contains N bits bQ, b-j, b2, ... »bN_.j, see figure 1c. The number of information packets in a frame depends on (a) the bit rate BR at which the second digital signal is transmitted via the transmission medium, (b) the number of bits N in an information packet, where N is greater than 1, (c) Fs, the sampling frequency of the broadband digital signal, and (d) the number of samples nc of the broadband digital signal, the corresponding information of which, after conversion in the transmitter, to the second digital signal is contained in one frame, as follows: .

The quantity P is calculated according to the following formula.

If this calculation yields a whole value for P, the number of .information packets B in a frame is equal to P. If the calculation does not yield an integer, a number of frames P 'contain information packets and the remaining frames P' + 1 information packets.

P 'is the first lower integer following P. The number of frames with P 'and P' + 1 information packets is of course chosen such that the average frame rate is equal to Fs / ns. In the following it will be assumed that N = 32 and ns - 384. The table in figure 5 now gives for these values for N and ns and for four values for the bitrate BR and three values for the sampling frequency Fs the number of information packets ( slots) located in one frame. It is clear that for a sampling frequency Fs equal to 44.1 kHz the quantity P is in all cases not an integer, so that a number of frames contain 34 information packets and the rest 35 information packets (for BR equal to 128 kbit / s). This is also indicated in figure 2. Figure 2 shows one frame. The frame consists of P 'information packets IP1, IP2, ..., IP P'. Sometimes a frame P '+ 1 contains information packets. This is achieved by adding one extra information package (dummy slot) to the frames of P 'information packages. The table in Figure 6, for the sampling frequency of 44.1 kHz for the aforementioned four bit rates in the second column, indicates the number of frames contained in the padding sequence. Of this number, column 3 indicates the number of frames in the sequence containing P '+ 1 information packets. Subtracting the numbers in the second and third columns yields the number of frames in the sequence containing P 'information packets. The (P '+ 1) information pack does not need to contain information. For example, the (P '+ 1) information pack can contain all zeros. It goes without saying that the bit rate BR is not necessarily limited to the four values as shown in the tables of Figures 5 and 6. Other (for example intermediate) values are also possible.

Figure 2 shows that a frame is composed of three frame parts FD1, FD2 and FD3, in this order. The first frame portion FD1 contains synchronization information and system information. The second frame portion FD2 contains allocation information. The third frame part FD3 contains samples and possibly also scaling factors of the second digital signal. For further explanation it is necessary to first consider the operation of the transmitter in the transmission system according to the invention.

Figure 4 schematically shows the transmission system with a transmitter 1, which is provided with an input terminal 2 for receiving the broadband digital signal SBB, which may for instance be a digital audio signal. In the case of an audio signal, one can think of a mono signal, or a stereo signal, in which the digital signal consists of a first (left) and a second (right) signal part. It will be assumed that the transmitter has a coder for subband coding of the broadband digital signal, and thus the receiver has a subband decoder for recovering the broadband digital signal. The transmitter is provided with analysis filtering means 3 for generating a number of M sub-band signals SSB-SSBM in response to the digital broadband signal SBB, which analysis filtering means divide the signal band of the broadband signal SBB with sampling frequency reduction. successive subbands with band numbers m (1 <m <.M), which increase with frequency. These subbands can all have the same bandwidth, but it is also possible to have the subbands have a mutually different bandwidth. In that case, the subbands may correspond, for example, to the bandwidths of the critical bands of the human ear. The transmitter is further provided with means for blockwise quantization of the respective subband signals. These quantizing means are included in the block with reference number 9 in Figure 4.

Such a subband coder is known per se and is described, inter alia, in the aforementioned publications of:

Krasner and van Theile et al. See also, optionally, published European Patent Application 289,080 (PHN 12.108).

Reference is made to these publications for further explanation of the operation of the subband coder. They are therefore deemed to have been included in this application. With such a subband coder, a significant data reduction can be achieved, such as a reduction of 16 bits per sampling for the broadband digital signal SBB to, for example, 4 bits per sampling in the signal sent via the transmission medium 4, see figure 4, is transmitted to the receiver 5. It has previously been stated that n .. was taken equal to 384. Thus, this concerns blocks of 384 samples of the broadband digital signal, each sample being 16 bits long. Furthermore, it is now assumed that M = 32. The broadband digital signal is thus split in the analysis filter means 3 into 32 subband signals. 32 (blocks of) subband signals are now delivered to the 32 outputs of the analysis filter means, each block consisting of 12 samples (the subbands are the same width), each sample being 16 bits long. At the outputs of the filter means 3, the information content is therefore just as large as the information content of the block of 384 sampling of the signal SBB at the input 2. The means 9 now realize the data reduction because, using the knowledge about masking, the samples in the 32 blocks of 12 samples, each block for a subband, more roughly quantized, and thus can be displayed with fewer bits. In a static bit allocation, all samples per subband per frame are expressed in a fixed number of bits. Different in each subband, but also possibly the same, for example expressed in 4 bits. With a dynamic bit allocation, the number of bits for each subband can be chosen differently in time, so that sometimes even greater data reduction or higher quality can be achieved at the same bit rate.

The subband signals quantized by the block 9 are added to a generator unit 6. Starting from the quantized subband signals, this unit 6 generates the second digital signal, as indicated in Figures 1 and 2. The construction and content of the frames can now be further explained. The first frame part FD1 in figure 2 is further elaborated in figure 3. It is clear from figure 3 that the first frame part here contains exactly 32 bits and is therefore exactly equal to one, information packet, namely the first information packet IP1 of the frame. The first 16 bits of the information packet form the synchronization signal (or synchronization word). For example, the synchronization signal can consist of all "ones". Bits 16 through 31 provide the system information. Bits 16 through 23 indicate the number of information packets in a frame. This number therefore corresponds to P ', both for frames with P' information packets and for the frames with the additional information pack IP P '+ 1. P 'can be up to 254 (1111 1110 in bit notation), to avoid similarity to the synchronization signal. Bits 24 through 31 provide frame size information. An example of the format and meaning of this information is shown in Figure 7. Bit 24 indicates the type of frame. In the case of format A, the second frame part has a different length (a different number of information packets) than in the case of format B. As will be shown below, the second frame part FD2 in the A format is composed of 8 information packets, namely the information packets IP2 to IP9 and in the B format composed of 4 information packages, namely the information packages IP2 to IP5. Bits 25 and 26 indicate whether or not there is information subject to a prohibition of copying or not. Bits 27 through 31 indicate the function mode. This means: a) the channel mode, which indicates what kind of signal the broadband signal is concerned (as mentioned before, it can be a stereo audio signal, a mono audio signal or an audio signal composed of two different signal parts for example the same text but pronounced in two different languages). Figure 8 indicates the channel mode. That is to say, indicates how the signal parts are divided over the two channels (channel I and channel II) in the aforementioned cases.

b) the sampling frequency Fe of the broadband signal.

c) any emphasis on the broadband digital signal applied in the transmitter. The 50 and 15 ps indicate the time constants of the emphasis and CCITT J.17 indicates a certain standard of the emphasis, as established by the CCITT (Committee Consultative Internationale de Télégraphie et Téléphonie).

The content of the frame portion FD2 in Figure 2 will be further discussed with reference to Figures 9, 10 and 11. In the A format, the second frame portion contains eight information packets. This is because a conversion of the broadband digital signal SBB is assumed to 32 subband signals (for each signal part of the digital signal SBB).

Each subband is assigned a four-bit a.loca word. In total, these are 64 4-bit long allocation words that can be stored exactly in eight information packets. In the B format, allocation information for only half of the number of subbands is stored in the second frame part, so that in that case the second frame part is only 4 information packets. Figure 9 shows the meaning of the four bit allocation words AW. An allocation word associated with a certain subband indicates the number of bits by which the samples of the subband signal in the relevant subband, after quantization in the unit 9, are represented. An example: the allocation word AW equal to 0100 indicates that the samples are represented with 5 bit words. Furthermore, it is clear from figure 9 that the allocation word 0000 indicates that no samples have been generated in the relevant subband. This can happen, for example, if the subband signal in a neighboring subband has such a large amplitude that this signal completely masks the subband signal in the relevant subband. Furthermore, the allocation word 1111 is not used because of the great similarity to the sync word m the first information packet IP1. The order in which the allocation words AW j, m associated with the two channels j, where j = I or II, and the 32 subbands with rank number m, where m ranging from 1 to 32, are stored in the second frame part, is in Figure 10, in case it concerns frame mode A. The allocation word AWI, 1 associated with the first subband signal portion of the first and lowest subband (channel I, subband 1) is stored first. Thereafter, the allocation word AW 11.1 associated with the second subband signal portion of the first and lowest subband (channel II, subband 1) is stored in the second frame portion FD2. Then, the allocation word AW 1.2 associated with the first subband signal portion of the second and second lowest subband (channel I, subband 2) is stored in the frame portion FD2. Thereafter, the allocation word AW 11.2, associated with the second subband signal portion of the second subband (channel II, subband 2) follows. This continues until the allocation word AW 11.4 associated with the second subband signal portion of the fourth subband (channel II, subband 4) is stored in the second frame portion FD2. With this, exactly the second information packet IP2 (slot 2) of the frame, which is the first information packet in the frame part FD2 of the frame, is filled. The information package IP3 (slot 3) is then filled with AW 1.5; AW 11.5; .... AW II.8. This continues in the order shown in Figure 10. Fig. 10 indicates only the indices j-m of the stored allocation words AW j, m. Figure 11 indicates the order for the allocation words in the case of a B format frame. In this case, only allocation words from subbands 1 to 16 are stored. The order, as shown in Figure 10, corresponds to the order in which the individual samples associated with a one channel j and a subband m, upon receipt in the receiver, are added to the synthesis filtering means. This will be explained in more detail later. In serial data stream, for example, there are all frames according to the A format. In that case, the allocation information in each frame is used in the receiver to properly derive the samples from the information stored in the third frame portion of that frame. The serial data stream may also contain, more or less alternately, frames in the A format and frames in the B format. However, the frames of both formats may contain samples for all channels and all subbands in the third frame section. A frame according to the B format then in fact lacks the allocation information that is needed. to derive the samples for the channels I and II of the subbands 17 to 32 from the third frame part of a B-format frame. The receiver contains a memory in which the allocation information contained in the second frame portion of an A format frame can be stored. If the subsequent frame is a B format frame, in memory only the allocation information for subbands 1 to 16 and channels I and II is replaced by the allocation information stored in the second frame portion of the B format frame, and to derive the samples for the subbands 17 to 32 from the third frame portion of the B-format frame, use is made of the allocation information for these subbands obtained from the previous A-format frame in the. memory are available. The reason why A-format frames are alternated with B-format frames is that the allocation information for some subbands, in the present case the allocation information for the higher subbands 17 to 32, does not change so quickly. Since the sender knows during quantization what the allocation information is for the various subbands, if the allocation information for the subbands 17 to 32 does not change (practically), this sender can decide to generate a B-format frame instead of an A format frame. In addition, this gives as an example that there will now be extra storage space for storing the samples in the third frame part FD3. Namely, with a certain value for P ', the third frame part of a B-format frame is four information packets longer than the third frame part of an A-format frame. This thus makes it possible to increase the number of bits with which the samples are presented in the lower subbands 1 to 16, so that a greater accuracy in the transfer can be realized for these subbands. Also, if it is necessary to quantize the lower subbands more precisely, the transmitter may automatically choose to generate B format frames. In that case, this may compromise the accuracy with which the higher subbands are quantized.

The third frame portion FD3 in Figure 2 contains the samples of the quantized subband signal portions for the two channels. If for none of the subbands and channels the allocation word 0000 is present in the frame part FD2, this means in the example that for each of the 32 subbands and 2 channels, twelve samples are included in the third frame part FD3. So in total 768 samples. The samples may have been multiplied by a scale factor in the transmitter for their quantization. For each of the subbands and channels, the twelve samples are amplitude divided by the sampling amplitude of the twelve samples, which have the greatest amplitude. In that case, a scaling factor must be included for each subband and each channel in order to be able to perform the inverse processing on the samples on the receiving side. To this end, the third frame part then contains scale factors SF j, m one for each of the quantized subband signal parts in the different subbands. Scale factors are represented by 6 bit numbers, the most significant bit first, with values ranging from 000000 to 111110. The scale factors of the subbands to which bits are assigned, i.e. whose allocation information is non-zero, are sent before the transmission of the samples begins. This means that the scale factors are located at the front in the third frame part FD3, before the sampling. This allows for rapid decoding in the receiver 5, without the necessity of storing all the samples in the receiver, as will be seen later. Thus, a scale factor SF j, m may indicate the value by which the samples of the signal in the j-th channel of the m-th subband have been multiplied. Another possibility is to store just one divided by this value as a scaling factor, so that on the receiving side it is not necessary to first divide the scaling factors before scaling the samples to the correct value.

The maximum number of scale factors is at the frame size A 64. If the allocation word AWj, m for a certain channel j has a certain subband m of the value 0000, which means that there are no samples for this channel and this subband in the frame part FD3 there is also no need to store a scale factor for this channel and this subband. The number of scale factors is then less than 64. The order in which the scale factors SFj, m are stored in the third frame part FD3 is the same as with which the allocation words are stored in the second frame part. The order is thus as follows: SF 1.1; SF 11.1; SF 1.2; SF 11.2; SF 1.3; SF 11.3; SF I, 32, SF 11.32.

If a scale factor does not have to be stored, the sequence is not complete. The example then is: ____ SF 1.4; SF 1.5; SF 11.5; SF 11.6; ____

In this case, the scale factors for the fourth subband of channel II and the sixth subband of channel I are not stored. If the frame is a B-format frame, scale factors could still be included in the third frame part for all subbands and all channels. This does not necessarily have to be the case. In this case it would be possible to store scale factors for the sub-bands 1 to 16 in the third frame part of the frame only. In the receiver one must then have a memory in which all scale factors can be stored at the moment of entry of a previously entered A format frame. Upon receipt of the B format frame, only the scale factors for the subbands 1 to 16 are subsequently replaced by the scale factors stored in the B format frame. The scaling factors from the previously received A format frame for the subbands 17 to 32 are then used to scale up the samples for these subbands stored in the third frame portion of the B format frame again.

The samples are stored in the same order in the third frame portion FD3 as the allocation words and the scaling factors, one sample for each subband of each channel in succession. That is, first all first samples for the quantized subband signals for all subbands of both channels, then all second samples, ..... and so on. The binary representation of the samples can be chosen as desired, whereby the binary word consisting of all 'ones' is preferably not used again.

The second digital signal generated by the transmitter 1 is then applied via the output 7 to a transmission medium 4, and is supplied via the transmission medium 4 to the receiver 5. The transmission via the transmission medium 4 can be in the form of a wireless transmission, such as for example a radio transmission channel. However, other transmission media are equally possible. One can think of an optical transmission, for instance via optical fibers or optical record carriers, such as compact disc-like media, or a transmission by means of magnetic recording carriers, which can use RDAT or SDAT-like recording and reproduction techniques, see the book "The art of digital audio" by J. Watkinson, Focal press, London 1988.

The receiver 5 contains a decoder, which decodes the signal encoded in the coder 6 of the transmitter 1 and converts it into a replica of the broadband digital signal which is applied to the output 8.

A further elaboration of the receiver 5 in Figure 4 is shown in Figure 12. The encoded signal (the second digital signal) is presented via a terminal 10 to a unit 11. The essential information in the incoming signal is contained in the scale factors and the samples. The remaining information contained in the second digital signal is only necessary for "good accounting" so that correct decoding can take place. The decoder process is repeated for every frame that comes in. The transmitter first extracts the synchronization and system information from the frames.

In the unit 19, the sync words contained in the first 16 bits of the first frame portion of each frame are detected each time. Since the sync words of successive frames are each an integer number of P 'or P' + 1 information packets from each other, these sync words can be detected very accurately. Once the receiver is in synchronization, the detection of the sync word in unit 19 can be realized by opening a time window of, for example, one information packet long in unit 19 around the P 'information packets, so that only that part of the incoming information is presented to the sync word detector in unit 19. If the sync word is not detected, the time window remains open for one more information pack, because the previous frame may have been a frame with P '+ 1 information packets. Starting from these sync words, a PEL incorporated in the unit 19 can derive a clock signal with which the central control unit 18 can be controlled.

It is clear from the above that the recipient must know how many information packets a frame contains. To that end, the system information is added via an input of the control unit 18 to switching means 15, which are then in the drawn position. The system information can now be stored in a memory 18a of the control unit 18. Via the control signal line 20, information about the number of information packets in a frame can be supplied to the unit 19, so that the time window for the sync word detection can be opened at the correct moments. After receiving the system information, the switch 15 switches to the bottom position. The allocation information located in the second frame part of a frame can now be stored in the memory 18b. If the allocation information in the incoming frame does not contain an allocation word for all subbands and channels, this has already become clear from the derived system information. Think of the information indicating whether it was an A format or a B format frame. The control unit 18 will therefore store the received allocation words at the correct position in the allocation memory 18b under the influence of the relevant information in the system information. It goes without saying that the allocation memory 18b in the example has 64 memory positions.

If no scale factors are included, then the elements with reference numbers 11, 12 and 17 are superfluous and the content of the third frame part of a frame becomes via the input 10, which is directly coupled via the connection 16 to the input of the synthesis filter means 21 are supplied to these filtering means. The order in which the samples are fed to the filter means 21 is the same as the order in which the filter means 21 processes the samples to obtain a reconstructed broadband signal. The allocation information stored in the memory 18b is required to divide the serial data stream of the samples into the individual samples in the filtering means 21, each sample with the correct number of bits. Therefore, the allocation information is supplied via the line 22 to the filtering means 21. The receiver further includes a de-emphasis unit 23 which performs a de-emphasis on the reconstructed digital signal output from the filter 21. To output the correct damping base, the relevant information in bits 24 through 31 of the first frame portion therefore from the memory 18a to be supplied to the emphasis unit 23 via line 24.

If the third frame part also contains the scale factors SF j, m, the switch 11, the memory 12 and the multiplier 17 are included in the receiver. At the moment of the entry of the third frame part FD3 of a frame, the switch 11 is in the lower position under the influence of a control signal supplied by the control unit 18 via the line 13. The scale factors can now be supplied to the memory 12. Under the influence of addressing signals which are applied to the memory 12 via the line 14 by the control unit 18, the scaling factors are placed in the correct position in the memory 12. Memory 12 has 64 positions for storing the 64 scale factors. Again, upon receipt of a B format frame, the control unit 18 supplies addressing signals to the memory 12 such that only the scaling factors for the subbands 1 through 16 are overwritten by the scaling factors stored in the B format frame. Subsequently, the switch 11 switches to the drawn (upper) position under the influence of the control signal which is applied via the line 13, so that the samples are supplied to the multiplier 17. Under the influence of the allocation information which is now supplied via the line 22 to the multiplier 17, the multiplier first derives the individual samples, with the correct bit length, from the serial data stream which is supplied via the line 16. Subsequently, the samples are multiplied such that they are upscaled back to the correct value that the samples had before they were downscaled in the transmitter. If the scale factors stored in the memory 12 are the scale factors with which the samples in the transmitter have been scaled down, these scale factors must first be inverted (one divided by the scale factor is determined) and then presented to the multiplier 17. Obviously, these scaling factors could have been reversed upon receipt and then stored in memory 12. If the scale factors stored in the frames were already equal to the value with which the samples are to be scaled up during reception, they can be stored directly in the memory 12 and be presented directly to the multiplier 17. Obviously, before the signal processing on the samples stored in one frame begins, no memory is required to store all of these samples first. At the time of receipt of a sample via line 16, all the necessary information for the processing of this sample is already present, so that this processing can take place immediately. All this therefore takes place under the influence of control signals and clock signals which are supplied by the control unit 18 to all parts of the transmitter. By no means all control signals are indicated. This is not necessary, since it is clear to the skilled person how the receiver functions. Under the influence of the control by the control unit 18, in the multiplier 17 the samples and the associated multiplication factors are multiplied together. The samples, which have now again the correct amplitude, are fed to the reconstruction filter 18, in which the subband signals are converted back into the broadband digital signal. Further elaboration of the receiver does not seem necessary, since such receivers are generally already known, see for example the publication "Low bit rate coding of high-guality audio signals. An introduction to the MASCAM system" by G. Theile et al in EBU Technical review No. 230 of August 1988. Furthermore, it should be clear that by sending the system information the receiver can be very flexible and can decode these signals correctly for second digital signals with different system information.

Fig. 13 schematically shows yet another embodiment of the transmitter, here in the form of a recording device, for recording the broadband digital signal on a record carrier, in this case a magnetic record carrier 25. The second digital signal is supplied by encoder 6 to a writing device 27 provided with a writing head 26, via which the signal is recorded in a track on the record carrier. It is thereby possible to record the second digital signal in a single track on the record carrier, for example by means of a helical scan recorder, in which the single track is then in fact divided into adjacent, at an angle to the longitudinal direction. of this record carrier, tracks running over the record carrier. This could include an RDAT-like recording method. Another method is to split up the information and at the same time record a number of tracks lying on the record carrier next to one another and in the longitudinal direction of the record carrier. This could include an SDAT-like way of recording. A detailed description of the above two methods can be found in the aforementioned book "The art of a digital audio" by J. Watkinson.

Figure 14 schematically shows an exemplary embodiment of the receiver 5, here in the form of a reading device for reading out the record carrier 25 of the broadband digital signal, such as that by means of the device of Figure 13 in the form of the second digital signal. the record carrier is recorded. The second digital signal is read from a track on the record carrier by the read head 29 and is supplied to the receiver 5, which can for instance be constructed in the form as shown in figure 12. The reader 28 can again be in the form of RDAT-like or SDAT-like display method. Both methods are described in detail in the aforementioned book by Watkinson.

Figure 15 shows a number of other possibilities for storing the scale factors and the samples in the third frame part FD3 of a frame. Figure 15a shows the previously described storage in which the scaling factors SF for all subbands m and channels (I or II) are stored in the third frame part before the samples.

Figure 15b shows the same situation as in Figure 15a, only now the memory space for the scale factors SF I, m and SF II, m and the corresponding x samples for these two channels in the subband m is schematically indicated. In figure 15b the samples are for the two channels in the subband m are shown joined together in blocks, while normally stored in the third frame portion. The samples are y bits long. In the example discussed earlier, x equals 12 and we now take y equal to 8. Figure 15c now shows another storage. The two scale factors for the first and second channels in the subband are still present in the third frame part. Only, instead of the x samples for the two channels (left and right for a stereo signal) in the subband m (so a total of 2x samples), there are now only x samples for the subband m in the third frame part. These x samples for example, one has obtained by adding together corresponding samples in each of the two channels. In fact, a mono signal has been obtained in this subband m. The x samples in Fig. 15c each have a length of z bits. If z is equal to y, then space has been saved in the third frame part, which can be used again by samples that need to be quantized more precisely.

It is also possible to express the x samples of the mono signal in Z = 2y (= 16) bits. Such a signal processing is applied if the phase difference between the left and right signal part in a subband is not important, but where the waveform of the mono signal is important. This is especially so for the signals in higher subbands, because the ear is less phase sensitive for the frequencies in those subbands. By subsequently expressing the x samples of the mono signal in 16 bits, the waveform has been quantized more precisely, while the space occupied by these samples in the third frame part is equal to that of the example of Fig. 15b. Yet another possibility is to display the samples in Figure 15 in, for example, 12 bits. The signal description is then still more accurate than in the example of Figure 15b, while space is moreover saved in the third frame part. When the signals stored in the third frame part according to Fig. 15c are reproduced on the receiving side, a stereo effect known under the term intensity stereo is obtained. Only the intensities of the left and right signals (in the subband m) differ, with the different values for the scale factors SF I, m and SF II, m.

Figure 15d shows yet another possibility. In this case, there is only one scaling factor SF m for the two signal parts in the subband m. This is a case that may occur especially for low-frequency subbands. Yet another possibility, which is not further indicated by means of a figure, is that the x samples for channels I and II of subband m, as in figure 15b, are not provided with corresponding scale factors SF I, m and SF II, m. These scale factors are therefore not included in the same third frame part. In that case, the scale factors SF I, m and SF II, m stored in the third frame portion of a previous frame should be used to scale up the samples in the receiver.

All the options discussed with reference to Figure 15 can be applied in the transmitter in order to realize the most efficient possible data transport via the transmission medium. Thus, frames may alternately occur in the data stream as they are described with reference to Figure 15. It will be clear that, if the receiver is to be able to decode these different frames correctly, additional information about the system information can be found in the system information. construction of these frames should be included.

Figure 16 shows a further elaboration of the transmitter 1.

The figure shows how the different information can be combined into the serial data stream as shown in figures 1, 2 and 3. Figure 16 actually shows a further elaboration of the encoder 6 in the transmitter 1. The encoder contains a central control unit 30 which controls a number of components in the encoder.

The encoder includes a generator 31 included in the control unit 30, for generating the synchronization information and the system information, as discussed with reference to Figure 3, a generator 32 for determining the allocation information, a generator 33 (if present) for determining the scale factors, a generator 34 for determining the samples for a frame. Generator 35 is a generator that can generate the additional information packet IP P '+ 1. The outputs of these generators are coupled to associated inputs of switching means 40, in the form of a five-position switch, the output of which is coupled to the output 7 of encoder 6. The switching means 40 are also controlled by the control unit 30. Via the lines 41.1 to 41.4 the various generators are controlled. The operation of the transmitter will be discussed on the basis of a mono signal divided into M subband signals. These M subband signals SSB1 to SSBM are applied to terminals 45.1, 45.2, ..., 45.M. For example, blocks of 12 samples from each of the subband signals are pooled. In units 46.1 through 46.M, if any, the twelve samples in a block are scaled to the amplitude of the largest sample in the block. The M scale factors are supplied to lines 33 (if any) through lines 47.1 through 47.M. The subband signals are supplied to M quantizers 48.1 to 48M as well as to a unit 49. The unit 49 determines for each subband the number of bits with which the relevant subband signals are to be quantized. This information is supplied through lines 50.1 to 50.M to respective quantizers 48.1 to 48.M so that they quantize the 12 samples of each of the subband signals appropriately. In addition, this (allocation) information is supplied to the unit 32. The samples of the quantized subband signals are supplied via the lines 51.1 to 51.M to the unit 34. The units 32, 33 and 34 convert the allocation information, the scale factors and the samples in the correct order, in the order set out above. In addition, the control unit 30 has formed the synchronization information and the system information associated with the frame to be generated, into which the aforementioned data stored in units 32, 33 and 34 are to be housed. In the drawn position of the switching means 40, the synchronization and system information for a frame is output by the generator 31 and supplied to the output 7. Then, under the influence of the control signal from CPU 30 supplied through line 53, switch 40 switches to the second position from above, so that the output of generator 32 is coupled to the output. The allocation information is now supplied to the output 7 by the generator 32. The order of the allocation information is as described with reference to Figures 10 or 11. Then the switch 40 switches to the third position from the top. This means that the output of generator 33 is coupled to the output 7. The generator 33 now delivers the scaling factors in the correct order to the output 7. Then the switch 40 switches to the next position, so that the output of the generator 34 is coupled to the output 7. The generator 34 now delivers the samples in the various subbands, in the correct order, to the output 7. In this cycle, exactly one frame is now supplied to the output 7. Then the switch 40 switches back to the top position. A new cycle begins in which a subsequent block of 12 samples for each subband is encoded and a subsequent frame at output 7 can be generated. In some cases, for example, if the sampling frequency.

Fs equals 44.1 kHz, see figure 5, an additional information pack (the dummy slot, see figure 2) must be added. In that case the switch will switch from the position in which the generator 34 is coupled to the output 7 to the bottom position. The output of the generator 35 is now coupled to the output 7. The generator 35 now generates the additional information packet IP P '+ 1 which is supplied to the output 7. Thereafter, the switch 40 switches back to the upper position before the start of the next cycle.

It goes without saying, of course, that if one wishes to apply an error correction to the signal received by the transmitter, in order to correct in this way for errors that have arisen during the transmission in the transmitted signal, one will have to apply a certain channel coding to the second digital signal. to apply. Also, a modulation of the second digital signal is required before the second signal can be transmitted. A digital signal is thus transmitted via the transmission medium, which may not be directly recognizable as a second digital signal, but which is derived from it. It should also be noted that, for example, in case the subbands have different widths, the number of samples for the different subbands stored in one third frame portion may and probably will be different. Let us consider, for example, a division into three sub-bands, a low subband SB-j, a mid-frequency subband SB2 and a high subband SB3. For example, the high subband SB3 will have twice the bandwidth than the other two subbands. This means that twice as many samples for the subband SB3 will also be stored in the third frame part than for each of the other subbands. The order in which the samples are fed to the reconstruction filter in the receiver can then be: the first sample from SB ^, the first sample from SB3, the first sample from SB2, the second sample from SB3, the second sample from SB1f, the third sample. from SB3, the second sample from SB2, the fourth sample from SB3 ... etc. The order in which the allocation information for those subbands is then stored in the second frame part is then: first the allocation word for SB1 (then the allocation word of SB3, then the allocation word for SB2. Likewise for the scaling factors. The receiver further knows from the system information that in this case the cycle consists of groups of four samples each, each group containing one sample of SB ^, a sample of SB3 , a sample of SB2 and then another sample of SB3.

Claims (21)

1. A digital transmission system with a transmitter and a receiver for transmitting via a transmission medium and receiving a broadband digital signal with a certain sampling frequency Fs, for example a digital audio signal, the transmitter being provided with an input terminal for receiving of the broadband digital signal, which input terminal is coupled to an input of a signal source belonging to the transmitter which is adapted to generate and supply to an output a second digital signal, which is built up of successive frames, each frame being built up from a plurality of information packets, each information packet containing N bits where N is greater than 1, the receiver having a decoder having an input for receiving the second digital signal, which decoder having an output coupled to an output terminal for outputting the broadband digital signal, characterized in that, i if P in the formula

where BR is the bit rate of the second digital signal, and ns is the number of samples of the broadband digital signal, of which the corresponding information belonging to the second digital signal is contained in one frame of the second digital signal, a whole number, the number of information packets B in one frame is P, and that, if P is not an integer, the number of information packets in some of the frames is P ', where P' is the next lower on P integer, and the number of information packets in the other frames is equal to P '+ 1, such that the requirement that the average frame rate of the second digital signal is substantially equal to Fs / n <. a frame is composed of at least a first frame part, containing synchronization information and information related to the number of information packets in the frame. 2. A transmission system as claimed in Claim 1, characterized in that a frame is composed of a first frame part, a second frame part and a third frame part, the first frame part further containing system information, the second and third frame part containing signal information. Transmission system according to claim 1 or 2, characterized in that, if a frame contains P '+ 1 information packets, the first frame part contains information corresponding to P'. Transmission system as claimed in claim 2 or 3, wherein the transmitter is provided with a coder-containing signal splitting means for generating a second digital signal in the form of a number of M sub-signals in response to the broadband digital signal, wherein M is greater than 1, and comprising means for quantizing the respective sub-signals, characterized in that the second frame part of a frame contains allocation information indicating for at least some of the sub-signals the number of bits with which the samples of the, from those partial signals obtained, quantized partial signals, and that the third frame portion contains the samples of at least these quantized partial signals (if any). A transmission system according to claim 4, wherein the signal splitting means are in the form of analysis filtering means for generating a number of M sub-band signals in response to the broadband digital signal, the analysis filtering means dividing the signal band of the broadband digital signal with sampling frequency reduction in successive sub-bands with band numbers m increasing with the frequency, and the quantizing means are arranged to block-quantize the respective sub-band signals, characterized in that the allocation information in the second frame portion of a frame for at least some of the subband signals indicate the number of bits by which the samples of the quantized subband signals obtained from those subband signals are reproduced, and that the third frame portion contains the samples of at least these quantized subband signals (if any). Transmission system according to claim 5, characterized in that the third frame part additionally contains scale factors, a scale factor associated with at least one of the quantized subband signals stored in the third frame part, and that the scale factors are in front of the quantized subband signals in the third frame part. saved. Transmission system according to claim 5 or 6, wherein the receiver is provided with a decoder-containing synthesis filtering means for constructing a replica of the broadband digital signal in response to the respective quantized subband signals, said synthesis filtering means combining the subbands with sampling rate increase into the signal band of the broadband digital signal, characterized in that the samples of the subband signals (if any) are stored in an order in the third frame portion corresponding to the order in which these samples are presented to the synthesis filter means upon receipt in the receiver. Transmission system according to Claim 7, characterized in that the allocation information for the different quantized subband signals is stored in the second frame part in the same order. Transmission system according to Claim 8, characterized in that the scale factors are stored in an order in the third frame part corresponding to the order in which the allocation information for the quantized subband signals associated with those scale factors is stored in the second frame part. A transmission system according to any one of claims 5 to 9, wherein the broadband digital signal is composed of a first and a second signal part, for example a digital stereo signal, the analysis filtering means being further arranged for responding to the first and second signal parts. generating a plurality of M subband signals, each subband signal consisting of a first and a second subband signal portion, the means further arranged to quantize the respective first and second subband signal portions in a given subband, characterized in that the second frame portion of a frame contains allocation information indicating for said subband, the number of bits by which the samples are reproduced of the quantized first and second subband signal portions obtained from each of the two subband signals of said subband, and that the third frame portion contains the samples of this quantized first and second subband signal parts (if any). Transmission system according to claim 10, insofar as dependent on claim 6, characterized in that the third frame part for said subband contains two scale factors, each scale factor belonging to a subband invited from the first and second quantized subband signal part. Transmission system according to claim 10 or 11, as far as dependent on claim 7, wherein the synthesis filter means are arranged to construct a replica of the broadband digital signal built up from the first and the second signal part in response to the respective quantized subband signal parts. characterized in that the samples of the subband signal parts (if any) are stored in an order in the third frame part corresponding to the order in which the samples of these subband signal parts, upon receipt in the receiver, are presented to the synthesis filter means. Transmission system according to claim 12, characterized in that the allocation information for the different quantized subband signal parts is stored in the second frame part in the same order. Transmission system according to claim 13, characterized in that the scale factors are stored in an order in the third frame part corresponding to the order in which the allocation information for the first and second quantized subband signal parts associated with said scale factors are in the second frame part. and that the scaling factors before the quantized subband signal parts are stored in the third frame part. Transmission system according to claim 4, characterized in that the (P '+ 1) -th information pack contains no useful information. Transmission system according to any one of the preceding claims, characterized in that the frames comprise a fourth frame part, in which error detection and / or error correction information is included. Transmitter for use in a transmission system according to any one of the preceding claims. Transmitter according to claim 17, characterized in that the transmitter is in the form of a device for recording the second digital signal in a track on a record carrier. Record carrier obtained with the transmitter according to claim 18, characterized in that the second digital signal is recorded in the track. 20. Receiver for use in a transmission system according to any one of claims 1 to 15. A receiver according to claim 20, characterized in that the receiver is in the form of a device for reading the second digital signal from a track on a record carrier.