In a digital communication, a channel coding (also referred to as error correction coding) is used for controlling errors in data over unreliable or noisy communication channels, and therefore, channel coding has become an essential part in digital communication. The aim of channel coding is to protect the information against disturbances during transmission. Thereby redundancy is added for error correction and for error detection, i.e., redundancy is added to a sequence of data packets, e.g., frames of an audio/video coder, that are sent over an error-prone channel to allow for a certain amount of transmission error correction at the receiver side. The error correction capability correlates with the redundancy rate, meaning that a higher error correction capability usually comes with a higher amount of redundancy.
In the context of audio data frames three effects have to be considered:
Hence, channel coding is therefore very attractive for audio data as it may increase the audio quality by
However, the positive effects are only observed in the presence of errors while the negative impact of the reduced data rate is present at all times. Furthermore, the signal strength of wireless networks such as the DECT (Digital Enhanced Cordless Telecommunication) system usually varies during the duration of a connection, i.e., for a phone call where the speaker moves around while speaking or due to external temporal disturbances. It is therefore suboptimal to apply a fixed forward error correction (FEC) scheme over the course of a connection. Instead, it is rather desirable to have a flexible channel coder providing a multitude of FEC modes varying from low protection and high data rate to high protection and low data rate (assuming the total rate, i.e., sum of data rate and redundancy rate, to be fixed).
From the audio codec perspective, such a switchable system does not impose a big challenge, as modern audio codecs usually support on the fly bitrate switching for speech and audio signals. But it imposes the technical problem of signaling the FEC mode on a frame basis. For easy integration into existing systems, the FEC mode should be signaled in-band. If this is done explicitly, this also reduces the data rate. Furthermore, the mode signaling will also be exposed to transmission errors and will not be protected by the error correcting codes as the channel decoder involves the knowledge of the mode before being able to decode the encoded data. It would therefore be useful to protect the FEC mode separately in order to avoid having an Achilles' heel to the FEC scheme, which again decreases the data rate for the audio frame.
A well-known channel coder for audio data is the EP (Error Protection) tool specified in MPEG-4 Part 3 (Information technology—Coding of audio-visual objects—Part 3: Audio Standard, International Organization for Standardization, Geneva, CH 2009). It features a multitude of protection classes ranging from error detection to the FEC schemes of different strengths. It also features flexible frame architectures and unequal error protection (UEP). The basic idea of UEP is to divide the frame into sub-frames according to the bit error sensitivities, and to protect these sub-frames with appropriate strength of FEC and/or cyclic redundancy check (CRC). In order to apply UEP to audio frames, information, at least a) number of classes, b) number of bits each class contains, c) the CRC code to be applied for each class, which can be presented as a number of CRC bits, and d) the FEC code to be applied for each class as frame configuration parameters is useful. As explained above, UEP involves both out-of-bands signaling of the basic configuration as well as a significant amount of configuration parameters that are signaled in-band. The in-band configuration parameters are furthermore protected separately from the data as they are needed prior to data decoding.
According to an embodiment, a channel encoder for encoding a frame may have: a multi-mode redundancy encoder for redundancy encoding the frame in accordance with a certain coding mode from a set of different coding modes, wherein the multi-mode redundancy encoder is configured to be capable of encoding the frame using each coding mode in the set, wherein the coding modes are different from each other with respect to an amount of redundancy added to the frame, wherein the multi-mode redundancy encoder is configured to output a coded frame having at least one code word; and a colorator for applying a coloration sequence to the at least one code word; wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one of coloration sequence, wherein the colorator is configured to select the specific coloration sequence in accordance with the certain coding mode, wherein the channel encoder may further have: a data splitter for splitting the frame into a plurality of data words, wherein the multi-mode redundancy encoder is configured to encode each of the plurality of data words according to the certain coding mode to acquire a plurality of code words, wherein the colorator is configured to apply the specific coloration sequence to each code word in a predefined number of the code words or in a predefined subset of the plurality of code words.
According to another embodiment, a channel decoder for channel decoding at least one transmitted code word may have: a colorator for applying at least one coloration sequence to the at least one transmitted code word or to an error corrected at least one transmitted code word to acquire at least one colored code word, wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, and wherein the at least one coloration sequence is associated to a certain decoding mode as a specific coloration sequence; a redundancy decoder for redundancy decoding the at least one colored code word to acquire a decoded output code word; and a decoding mode detector for generating a decoding mode indicator indicating the certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word, wherein the decoding mode indicator is associated to the at least one coloration sequence as the specific coloration sequence used for the coloration of the transmitted code word, wherein the colorator is configured to use, in addition to the coloration sequence, at least a further coloration sequence, or wherein the channel decoder is configured to bypass the colorator in a further decoding mode without any coloration; wherein the redundancy decoder is configured to redundancy decode an additional at least one colored code word colored using the further coloration sequence, to acquire a further decoded code word, the further colored code word which acquired from the transmitted code word using the further coloration sequence, or the transmission code word without coloration to acquire an even further decoded code word, and wherein the redundancy decoder is configured to output a reliability measure for the decoded code word, a further reliability measure for the further decoded code word or an even further reliability measure for the even further code word, wherein the decoding mode detector is configured to determine, based on the reliability measures, the decoding mode indicator, and wherein the redundancy decoder is configured to receive the decoding mode indicator and to output as the decoded output code word, either the decoded code word, the further decoded code word, or the even further decoded code word, wherein the colorator is configured to perform the coloration operation with the same coloration sequence to a predetermined number of the transmitted code words to acquire a predetermined number of the colored code words, and to perform the further coloration operation with the same further coloration sequence to a further predetermined number of the transmitted code words to acquire a predetermined number of the further colored code words, wherein the redundancy decoder is configured to determine the reliability measure deriving the predetermined number of the decoded code word, the further reliability measure deriving the predetermined number of the further decoded code word, or the even further reliability measure deriving the predetermined number of the decoded code word.
According to yet another embodiment, a channel decoder for channel decoding at least one transmitted code word may have: a colorator for applying at least one coloration sequence to the at least one transmitted code word or to an error corrected at least one transmitted code word to acquire at least one colored code word, wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, and wherein the at least one coloration sequence is associated to a certain decoding mode as a specific coloration sequence; a redundancy decoder for redundancy decoding the at least one colored code word to acquire a decoded output code word; and a decoding mode detector for generating a decoding mode indicator indicating the certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word, wherein the decoding mode indicator is associated to the at least one coloration sequence as the specific coloration sequence used for the coloration of the transmitted code word, wherein the decoding mode detector is configured to store a candidate list indicating a predetermined number of candidate decoding modes, wherein one candidate decoding mode is indicated without any coloration sequence and the other respective candidate decoding modes are indicated in association with a coloration sequence, and to select one candidate decoding mode as a certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word to be used, wherein the decoding mode detector is configured to perform a first decoding mode operation and a second decoding mode operation, wherein the decoding mode detector for performing the first decoding mode operation is configured to estimate the certain decoding mode being the candidate decoding mode without coloration sequence, to calculate syndromes of the code word, to check whether the calculated syndromes have value zero, when the calculated syndromes have value zero, to calculate a hash value of the transmitted code word, to compare the calculated hash value and a hash value included in the transmitted code word, and when the calculated hash value is equal to the included hash value, to generate the decoding mode indicator to indicate the candidate coding mode without coloration sequence as the certain decoding mode, or when the calculated hash value is different from the included hash value, to exclude the candidate decoding mode without coloration sequence from the candidate list, and to proceed further with the second decoding mode operation.
According to still another embodiment, a method for encoding a frame may have the steps of: multi-mode redundancy encoding the frame in accordance with a certain coding mode from a set of different coding modes, wherein the coding modes are different from each other with respect to an amount of redundancy added to the frame, outputting at least one code word; applying a coloration sequence to the at least one code word; wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, wherein a colorator is configured to select the specific coloration sequence in accordance with the certain coding mode, and splitting the frame into a plurality of data words, wherein the multi-mode redundancy encoder is configured to encode each of the plurality of data words according to the certain coding mode to acquire a plurality of code words, wherein the specific coloration sequence is applied to each code word in a predefined number of the code words or in a predefined subset of the plurality of code words.
According to still another embodiment, a method for channel decoding at least one transmitted code word may have the steps of: applying at least one coloration sequence to the at least one transmitted code word to acquire at least one colored code word, wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, wherein the at least one coloration sequence is associated to a certain decoding mode, redundancy decoding the at least one colored code word to acquire a decoded output code word, generating a decoding mode indicator indicating a certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word, wherein the decoding mode indicator is associated to the at least one coloration sequence used for the coloration of the colored code word, using, in addition to the coloration sequence, at least a further coloration sequence, or wherein the channel decoder is configured to bypass the colorator in a further decoding mode without any coloration; redundancy decoding an additional at least one colored code word colored using the further coloration sequence, to acquire a further decoded code word, the further colored code word which acquired from the transmitted code word using the further coloration sequence, or the transmission code word without coloration to acquire an even further decoded code word, outputting a reliability measure for the decoded code word, a further reliability measure for the further decoded code word or an even further reliability measure for the even further code word, determining the decoding mode indicator based on the reliability measures, and outputting as the decoded output code word, either the decoded code word, the further decoded code word, or the even further decoded code word based on the reliability measure.
According to another embodiment, a method for channel decoding at least one transmitted code word may have the steps of: applying at least one coloration sequence to the at least one transmitted code word to acquire at least one colored code word, wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, wherein the at least one coloration sequence is associated to a certain decoding mode, redundancy decoding the at least one colored code word to acquire a decoded output code word, generating a decoding mode indicator indicating a certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word, wherein the decoding mode indicator is associated to the at least one coloration sequence used for the coloration of the colored code word, storing a candidate list indicating a predetermined number of candidate decoding modes, wherein one candidate decoding mode is indicated without any coloration sequence and the other respective candidate decoding modes are indicated in association with a coloration sequence, and to select one candidate decoding mode as a certain decoding mode to be used by the redundancy decoder to acquire the decoded output code word to be used, wherein determining process includes a first decoding mode operation and a second decoding mode operation, wherein a first decoding mode operation includes: estimating the certain decoding mode being the candidate decoding mode without coloration sequence, calculating syndromes of the code word, checking whether the calculated syndromes have value zero, and when the calculated syndromes have value zero, calculating a hash value of the transmitted code word, comparing the calculated hash value and a hash value included in the transmitted code word, wherein the determining process includes: receiving a result of the comparison between the calculated hash value and the included hash value, when the calculated hash value is equal to the included hash value, generating the decoding mode indicator to indicate the candidate coding mode without coloration sequence as the certain decoding mode, or when the calculated hash value is different from the included hash value, excluding the candidate decoding mode without coloration sequence from the candidate list, and to proceed further with the second decoding mode operation.
According to yet another embodiment, a non-transitory digital storage medium may have a computer program stored thereon to perform any of the inventive methods, when said computer program is run by a computer.
Still another embodiment may have a data stream generated by any of the inventive methods.
According to the present invention, a channel encoder comprises a colorator for applying a coloration sequence to at least one code word, i.e., the code word includes information/indication of the coding mode. Therefore, transmission bits used for indicating the coding mode to a channel decoder is not necessary, and hence, the transmission rate is improved and it is possible to transmit the code word efficiently. In addition, the information/indication of the coding mode is included in the code word by applying the coloration sequence which is selected in accordance with the coding mode, and hence, it is possible to provide error resilient mode signaling.
According to the present invention, a channel decoder receives at least one transmitted code word, i.e., the code word including the information/indication of the coding mode (decoding mode). That is, the information/indication of the coding mode is distributed in the code word by applying the coloration sequence, and therefore, the information/indication of the coding mode is received at the channel decoder in the error resilient way. In addition, the channel decoder comprises a decoding mode detector for generating a decoding mode indicator indicating the certain decoding mode to be used for redundancy decoding, and the decoding mode indicator is associated to the at least one coloration sequence as the specific coloration sequence used for the coloration of the transmitted code word. Therefore, it is possible to detect the decoding mode by determining the specific coloration sequence, i.e., the channel decoder is able to determine the decoding mode without separately receiving specific information of the decoding mode. Hence, data transmission ratio is improved.
In accordance with embodiments of the present application, a channel encoder for encoding a frame, comprising: a multi-mode redundancy encoder for redundancy encoding the frame in accordance with a certain coding mode from a set of different coding modes, wherein the coding modes are different from each other with respect to an amount of redundancy added to the frame, wherein the multi-mode redundancy encoder is configured to output a coded frame including at least one code word; and a colorator for applying a coloration sequence to the at least one code word; wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one of coloration sequence, wherein the specific coloration sequence is selected in accordance with the certain coding mode.
In accordance with embodiments of the present application, the channel coding may be changed each frame based on an indication of a mode selection. The indication includes mode selection and coloration sequence to be applied or indication of bypassing the coloration sequence.
In accordance with embodiments of the present application, the channel encoder further comprises a data splitter for splitting the frame into a plurality of data words, wherein the multi-mode redundancy encoder is configured to encode each of the plurality of data words according to the certain coding mode to obtain a plurality of code words, wherein the colorator is configured to apply the specific coloration sequence to each code word in a predefined subset of the plurality of code words. That is, the redundancy rate can be different for different data words, i.e., redundancy rate can be different for each data word. In addition, a length of the data word included in the code word is changed based on the calculated number of the code words and also based on the code word index.
In accordance with embodiments of the present application, a channel decoder for channel decoding at least one transmitted code word, comprising: a colorator for applying at least one coloration sequence to the at least one transmitted code word or to at least one error corrected transmitted code word to obtain at least one colored code word, wherein the coloration sequence is such that at least one bit of the code word is changed by the application of the at least one coloration sequence, and wherein the at least one coloration sequence is associated to a certain decoding mode as a specific coloration sequence; a redundancy decoder for redundancy decoding the at least one colored code word to obtain a decoded output code word; and a decoding mode detector for generating a decoding mode indicator indicating the certain decoding mode to be used by the redundancy decoder to obtain the decoded output code word, wherein the decoding mode indicator is associated to the at least one coloration sequence as the specific coloration sequence used for the coloration of the transmitted code word. That is, to a plurality of transmitted code words are applied different coloration sequences (de-coloration) and (de)colored words are decoded by using different decoding modes and one of the used decoding modes is selected as a certain decoding mode based on the test result.
In accordance with embodiments of the present application, the redundancy decoder comprises a bit number reducer for reducing the bit number of the colored code word and an error corrector for correcting an error of the colored word, or the channel decoder further comprises an error corrector for correcting an error of the transmitted code word. That is, in case there is an error in the transmitted code words, the error correction process is operated in a part of the decoding process at the redundancy decoder, or error correction process is operated before applying the (de)coloration independently from the redundancy decoder.
In accordance with embodiments of the present application, the colorator is configured to use, in addition to the coloration sequence, at least a further coloration sequence, or wherein the channel decoder is configured to bypass the colorator in a further decoding mode without any coloration, e.g., the coloration sequence has only zero as values; wherein the redundancy decoder is configured to redundancy decode an additional at least one colored code word colored using the further coloration sequence, to obtain a further decoded code word, the further colored code word which obtained from the transmitted code word using the further coloration sequence, or the transmission code word without coloration to obtain an even further decoded code word, and wherein the redundancy decoder is configured to output a reliability measure for the decoded code word, a further reliability measure for the further decoded code word or an even further reliability measure for the even further code word, e.g., the reliability measure is calculated for each decoded code word using a different coloration sequence and decoding mode, wherein the decoding mode detector is configured to determine, based on the reliability measures, the decoding mode indicator, and wherein the redundancy decoder is configured to receive the decoding mode indicator and to output as the decoded output code word, either the decoded code word, the further decoded code word, or the even further decoded code word. That is, in case there is an error in the transmitted code word, then, the reliability measure, e.g., risk value (reliability measure) is calculated and the decoded mode used for the decoded code word having the smallest risk value is selected as the certain decoding mode.
In accordance with embodiments of the present application, the decoding mode detector is configured to store a candidate list indicating a predetermined number of candidate decoding modes, wherein one candidate decoding mode may be indicated without any coloration sequence or all candidate decoding modes are associated with a coloration sequence, and to select one candidate decoding mode as a certain decoding mode to be used by the redundancy decoder to obtain the decoded output code word to be used, wherein the decoding mode detector is configured to perform a first decoding mode operation and a second decoding mode operation, wherein the decoding mode detector for performing the first decoding mode operation is configured to estimate the certain decoding mode being the candidate decoding mode without coloration sequence, i.e., before the hash is evaluated whether the first code word is un-colored, to calculate syndromes of the code word, to check whether the calculated syndromes have value zero, and when the calculated syndromes have value zero, to calculate a hash value of the transmitted code word, to compare the calculated hash value and a hash value included in the transmitted code word, when the calculated hash value is equal to the included hash value, to generate the decoding mode indicator to indicate the candidate coding mode without coloration sequence as the certain decoding mode, or when the calculated hash value is different from the included hash value, to exclude the candidate decoding mode without coloration sequence from the candidate list, and to proceed further with the second decoding mode operation. That is, the decoding mode detector performs two operations, e.g., the decoding mode detector comprises a first decoding mode detector for performing the first decoding mode operation and a second decoding mode detector for performing the second decoding mode operation, and in case the certain decoding mode is not selected in the first decoding mode operation, the selection process proceeds further with the second decoding mode operation. Therefore, if there is no error in the transmitted code words and the mode associated with no coloration sequence was used at the encoder, it is not necessary to proceed further, and hence, the certain decoding mode is efficiently selected.
In accordance with embodiments of the present application, in the second decoding mode operation, an error of the transmitted code word is detected by using a syndrome, an error symbol is calculated using an error locator polynomial, and the error symbol is corrected. During the procedure, in case the detected errors are not correctable, then the decoding mode associated with the coloration sequence applied to the transmitted word including the uncorrectable error is excluded from the candidate list. In addition, in case the error locator polynomial for the transmitted word having the correctable error is not able to be determined, then, the further decoding mode is excluded from the candidate list. That is, the listed candidate decoding modes are excluded step by step and the remaining decoding mode on the list is selected as the certain decoding mode at the end. Hence, the certain decoding mode is reliably selected when considering the risk of error occurrence.
In advantageous embodiments of the present application, the FEC mode is signaled by modifying well-known linear codes in such a way that the redundancy rate is efficient while the decoder is able to determine the FEC mode by partial trial decoding. This zero byte implicit signaling is deterministic if no transmission errors occur and otherwise finds the correct mode with high probability, i.e., the frame loss due to signaling errors is negligible compared to the frame loss due to uncorrectable frames. More specifically, it is concerned with a (FEC) scheme that provides a multitude of Nmode modes for encoding data sequences into code sequences of a given length Ntarget. Here, for simplicity binary sequences are assumed, but a similar scheme would also apply to the general case where data symbols are elements in any field, for example, finite Galois field.
Embodiments of the present invention will be detailed subsequently referring to the appended drawings, in which:
Equal or equivalent elements or elements with equal or equivalent functionality are denoted in the following description by equal or equivalent reference numerals.
In the following description, a plurality of details is set forth to provide a more thorough explanation of embodiments of the present application. However, it will be apparent to one skilled in the art that embodiments of the present application may be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form rather than in detail in order to avoid obscuring embodiments of the present application. In addition, features of the different embodiments described hereinafter may be combined with each other, unless specifically noted otherwise.
In a further embodiment, for example, a frame of an audio data is provided to the channel encoder 2. In case the controller 8 is not included in the channel encoder 2 (as shown in
The channel encoder 2 in
The implicit mode signaling is based on the fact that it can be tested efficiently whether a given word c∈0 lies in k. However, since the codes are linear, the intersections m∩n are not empty. In particular, many families of codes, such as primitive narrow-sense BCH codes or Reed-Solomon codes with the same base field, will even produce inclusions between the different codes when ordered according Hamming distance, i.e.,
N
It may therefore happen that a code word cm obtained by encoding a data word in mode m also lies in n for an n≠m, whence it is generally not possible to determine the mode based on such a test alone. This problem is solved by applying a mode dependent transformation
Tm: 0→0 (2)
after encoding. These transformations are designed such that Tm(m)∩Tn(n)=Ø for m≠n which resolves the aforementioned ambiguity. Since the transformations do not change the length of the code words, this method effectively signals the mode of the channel coder with zero bits.
In the present embodiment these transformations are given by calculating the bit-wise XOR of the encoded code word c and a signaling sequence sigm∈0. So when encoding in mode m the channel encoder outputs the colored code word
{tilde over (c)}:=c⊕sigm. (3)
Receiving {tilde over (c)} and being ignorant of the representation in (3), the decoder can then test efficiently whether
{tilde over (c)}⊕sigk∈k. (4)
Since sigm⊕sigm is the zero sequence, the decoder will be able to verify that
{tilde over (c)}⊕sigm=c⊕sigm⊕sigm=c (5)
lies in m. Furthermore, on the condition
the signaling sequences sigk can be chosen such that
sigk⊕sigl∉1∪2∪ . . . ∪N
for k≠l allowing for deterministic mode detection at the decoder if no transmission errors occur. Hence, it is not necessary to separately transmit the data to indicate the certain coding mode and the parameters to the channel decoder.
As shown in
The channel decoder 20 receives transmitted code words transmitted from the channel encoder 2. Then, a predetermined number of transmitted code words are used/tested for generating the decoding mode indicator at the decoding mode detector 26 as explained below. The decoding mode detector 26 has information regarding decoding modes which could be used by the channel encoder 2, e.g., a list of candidate decoding modes.
As indicated at S6, if errors are detected, a reliability measure (a risk value) is calculated at the decoding mode detector 26 (S7). That is, in case the transmitted errors are occurred, the errors are detected and attempted to be corrected by calculating and using syndromes at the error corrector 24b and the result of the error correction is provided to the decoding mode detector 26 from the error corrector 24b. In case the error corrector 24b is independent, as shown in
Then, in case all the candidate decoding modes on the list are tested (S8), it proceeds further to S10 as described above. If there is a remaining candidate decoding mode on the list (S8), S2 to S7 are repeated until the entire candidate decoding modes are tested. In case the certain decoding mode is not determined (S12), although all of the candidate decoding modes are tested, the frame, which consists of the transmitted code word used/tested for determining the certain decoding mode, is registers as a bad frame.
At the channel decoder 20 in
Although it is not depicted in
The decoder determines/calculates/computes the risk value (reliability measure) of the decoding mode based on the number of the corrected symbols during a decoding operation of the colored code word. If a predetermined number of code words are colored, e.g., 6 code words are colored, then, the risk value (reliability measure) for decoding mode mfec=2 is calculated based on the number of the corrected symbols during a decoding operation of the 6 colored code words. In the same manner, the risk value (further reliability measure) for decoding mode mfec=3 is calculated based on the number of the corrected symbols during a decoding operation of the 6 colored code words, or the risk value (even further reliability measure) for decoding mode mfec=1 is calculated based on the number of the corrected symbols during a decoding operation of the 6 code words without coloration.
When the certain decoding mode is selected, then, the decoding mode indicator is provided from the mode selector 25 to the switch 27. The switch 27 switches the connection to the decoder to obtain the decoded output code word based on the decoding mode indicator. That is, for example, if the decoding mode mfec=3 is indicated as the certain decoding mode, then the switch 27 connects to the decoder 243 to obtain the decoded output code word.
In case transmission errors occurred, the decoder 20 receives
{tilde over (c)}⊕ε (8)
with an error sequence ε. This can lead to ambiguities in the sense that
{tilde over (c)}⊕ε⊕sigk∈k(c) (9)
for different k, where k(c) denotes the sets of all sequences that can be corrected by the FEC scheme (for example, at the error corrector 24b shown in
sigm⊕sigk⊕ε (10)
as a random guess and estimate the mode from a list of candidate modes according to a risk value, i.e., the reliability measure. This risk value is derived from decoding statistics such as the number of corrected symbols and reflects the likelihood that the decoder input is a random guess in 0 (i.e. a sequence of fair coin tosses).
This way, the risk of selecting the wrong mode is limited by the risk of erroneously decoding a code word that has been damaged beyond the error correction capability of the underlying code. In cases where this risk is considered too large, a hash value may be added as an option to the data before encoding and taken into account in the mode detection procedure. While this, similarly to an explicit signaling, reduces the data rate, it improves mode selection risk and wrong decoding risk alike. Therefore, the proposed FEC scheme is very well-suited for the application, where undetected corrupted frames usually lead to stronger degradations than detected and concealed corrupted frames.
Further details regarding the channel encoder 2 and the channel decoder 20 according to the present application are explained below.
Channel Encoder
The envisioned channel encoder operates on bytes and utilizes Reed-Solomon codes over GF(16) to construct a family of linear codes. It takes as input the target size in bytes denoted Ns, also referred to as slot size, a mode number mfec between 1 and 4 and an input sequence of data bytes a (k), k=0, 1, . . . , Np−1, which are interpreted in the following as integers between 0 and 255. The input size Np is derived from the parameters Ns and mfec as will be specified later. In the following, the target size is assumed to be at least 40 bytes.
Data Pre-Processing
In the pre-processing step, a hash value of Nhash bytes is calculated on the input data, e.g. a CRC (Cycle Redundancy Check) hash, where Nhash=Nhash(Ns, mfec) is a number depending only on the slot size Ns and the FEC mode mfec. In the advantageous embodiment, the number is given by
The hash value is used for data validation, as the error detection of the Reed-Solomon codes is not very strong.
Let the hash bytes be denoted h(k), k=0, 1, . . . , Nhash−1 and let rem(n,m) denote the remainder in the long division of n by m. Hash and data are concatenated and split into a sequence of numbers from 0 to 15 (in the following referred to as unit4 numbers), e.g. according to
a2(2k):=rem(h(k),16) (12)
and
a2(2k+1):=[h(k)/16] (13)
for k=0, 1, . . . , Nhash−1, and
a2(2k):=rem(a(k−Nhash),16) (14)
and
a2(2k+1):=└a(k−Nhash)/16┘. (15)
for k=Nhash, Nhash+1, . . . , Np+Nhash−1.
The input data extended with the calculated hash, i.e., the frame including the hash value is split into a plurality of data words. The number of the data words is calculated, for example, based on a target size for the frame and code word index.
Reed-Solomon Encoding
(Reference to “Error Correction Coding: Mathematical Methods and Algorithms”, Todd K. Moon, 2005.)
The linear codes are constructed from a multitude of Reed-Solomon codes over GF(16) with Hamming distances 1, 3, 5 and 7. The number of code words is calculated from the slot size as
and the length of code word i in data symbols is given by
where i ranges from 0 to Ncw−1. The condition Ncw≥40 implies that Li∈{13,14,15}. The Hamming distances for the different code words are mode and code word dependent and are given by
The data array is split into Ncw data words according to
Di(k):=a2(Si+k), k=0,1, . . . Li−δi((mfec)), (19)
where the sequence of split points is inductively defined by S0:=0 and Si+1:=Si+Li−δi(mfec)+1.
This constraints the input length to
which depends on Ns and mfec alone.
Subsequently, the data words Di are encoded into RS(Li, Li−δi(mfec)+1) codes Ci. Reed-Solomon encoding depends on a generator for the base field and a generator for the unit group of that base field (see e.g. “Error Correction Coding: Mathematical Methods and Algorithms”, Todd K. Moon, 2005) as well as a data-to-symbol mapping. In the following, the field GF(16) is assumed to be generated by x4+x+1 and the unit group generator α is assumed to be the residual class of x in GF(16)=GF(2)/(x4+x+1). Furthermore, the data-to-symbol mapping (mapping unit4 numbers to elements of GF(16)) is taken to be
n[n]:=bit0(n)+bit1(n)α+bit2(n)α2+bit3(n)α3, (21)
where bitk(n) denotes the k-th bit in the binary representation of n given by
The code word Ci is then the uniquely determined sequence satisfying
Ci(δi(mfec)−1+k)=Di(k) (23)
for k=0, 1, . . . , Li−δi(mfec) and also satisfying that the polynomial
Σk=0L
is divisible by the RS generator polynomial
Πk=1δ
As explained above, the data words are encoded and the code words are output as also indicated in
In the next step, mode signaling is performed by coloration of code words according to
for k=0, 1, . . . Li, where sigk is one of the following sequences:
In this embodiment, the number of code words (data words) is 6 if Ns=40. If the number of code words is large, it is not necessary to color all code words in order to robustly signal the FEC mode. In this case, coloration can be limited to a pre-defined subset of code words, e.g., the first 6 code words as indicated above by i<6. However, the number of code words may be changed dependent on parameters, i.e., target size, code word index, length of the code word and so on. Furthermore, figures of the coloration sequence are not limited to the above-mentioned examples and may be different figures.
The function bitxor(n,m) is defined on natural numbers and denotes the outcome of a bit-wise XOR on the binary representations of n and m, i.e.
bitxor(n,m):=Σk=0∞ck2k, (27)
where
The sequences are chosen to maximize separation of the different codes with respect to Hamming distance. Denoting by
vk:=([sigk(0)],[sigk(1)], . . . ,[sigk(Li−1)])
the corresponding vectors in GF(16)L
The probabilities of ck⊕vk⊕vl being decodable in l(15) with a prescribed number of symbol corrections when ck is drawn random uniformly from k(15) are given in Table 1. They provide an upper boundary for the corresponding probabilities for smaller values of Li.
The colored code words are shown in
Code Word Multiplexing
The colored code words are interleaved by the multiplexer 14. That is, a bit from a colored code word is placed in a different code word in a further bit of at least one different code word to obtain a frame.
That is, the code word lengths Li are chosen such that the elements of the colored code words {tilde over (C)}i can be fully interleaved, defining a multiplexed code word
c(k):={tilde over (C)}rem(k,N
for k=0, 1, . . . , 2Ns−1, which is converted to the output sequence
aout(k):=c(2k)+16c(2k+1) (30)
for k=0, 1, . . . , Ns−1. Interleaving increases the protection strength if bit errors are not equally distributed over the frame, e.g., when error bursts occur. Note that code word coloration could have also been described at this stage by calculating the bit-wise XOR of the final output and the corresponding sequences derived from sigm.
Channel Decoder
The channel decoder 20 receives as input a sequence of bytes ain and the slot size Ns in bytes. Again, bytes are interpreted as numbers between 0 and 255.
Code Word De-Multiplexing
The de-multiplexer 60 extracts interleaved code words at the decoder 20, i.e., the frame configurator 61 computes the number of code words, Ncw, and the code word lengths, Li, from the input size Ns as specified in the section of “Reed-Solomon Encoding” and extracts the code words Ci according to the arrangements described in the section “Code Word Multiplexing”.
Mode Detection
Straight forward mode detection according to the channel decoder 20 shown in
using trial decoding for all possible modes, and, on success, validate the decoded data by re-calculating the hashes of the transmitted code words (i.e., decoded frame) as explained above (data pre-processing). If this procedure succeeds for multiple modes, then a risk value can be attached to the mode classes as follows: let nm(i), i=0, 1, . . . , Ncw−1 denote the number of symbols that have been corrected in code word Ci,m during RS-decoding. For the Reed-Solomon codes RS(Li, Li−2t) in question (the Hamming distance being 2t+1 and thus the number of correctable symbols being t), the probability to pick a random word w of n symbols in GF(16)n that can be corrected into a RS(n,n−2t) code word by modifying τ≤t symbols, is given by
r(n,t,τ):=16−2t(τn)15τ. (32)
Consequently, the risk value for mode m may be taken to be
and mfec would be chosen such that ρm
The proposed mode decision takes a slightly different path. Instead of aiming for a full decoding for all possible modes, the mode detector takes a parallel approach, narrowing down the list of candidate modes step by step and reaching a final decision after processing the first 6 code words. This approach has the advantage of being less computationally complex on average.
The first decoding mode operation is performed by testing whether the certain decoding mode is mode 1. At first, syndromes of the code word are calculated and when the calculated syndromes vanish, i.e., calculated syndrome without value, (S30), a hash value is calculated and evaluated (S31). That is, if the decoding mode is mode 1, there should be no error and therefore, the syndrome has value zero. When the calculated syndrome has a value, the first decoding mode operation is terminated and proceeds to the second coding mode operation (S38). When calculated hash value is not equal to the included hash value (received hash value) in the code word (S34), the first decoding mode operation is terminated and proceeds to the second decoding mode operation (S38). When the hash values are the same (S34), the first decoding mode detector 30 generates the decoding mode indicator (S36) and the controller 34 performs to precede further steps to output the decoding data (S82).
Then, as depicted in
First Mode Detection Operation (Stage 1)
[Ci](x):=Σk=0L
Selection of FEC mode 1 depends on two conditions. Firstly, the first two syndromes need to vanish, i.e.
[C0](α)=[C0](α2)=0, (35)
and secondly, the re-calculated hash value needs to match the received hash value. If both conditions are satisfied, the decoding indicator is generated to indicate that the mode 1 is the certain decoding mode and the data is decoded according to the data arrangements at the encoder. If at least one of these conditions is violated, mode 1 is excluded from the list of candidate modes and mode detection enters stage 2.
That is, as shown in
Second Mode Detection Operation (Stage 2)
The calculated risk value is sent to the mode selector and the error position calculator 1 as risk_value_1. The error position calculator n, i.e., the error position calculator 1 for mode 2, calculates error positions in mode n+1, i.e., mode 2 by factorizing Λi,n+1. If factorization fails, or if an error position is out of bounds, or if the risk value is above the predetermined threshold, the mode 2 is excluded from the candidate list (blacklisted). The error symbol calculator n, i.e., the error symbol calculator 1 for mode 2, calculates error symbols in mode 2 (n+1) from σi,n+1 and error position err_posi,n+1.
As shown in
Then, the switch switches between inputs according to mfec (output is irrelevant if no mode is selected). At the error corrector, if is_mode_1, i.e., mfec=1 then output=input, since no error occurs. Otherwise the error corrector corrects symbols indicated by err_posi,mfec by XORing with err_symbi,mfec. Detailed processes are explained as below.
In the stage 2, the list of candidate modes is further reduced in several steps. The procedure to select the certain decoding mode terminates as soon as a valid mode has been found or if no valid mode remains on the candidate list. In the latter case decoding is stopped and the frame is marked as a bad frame.
Stage 2 only considers the code words C0 to C5 for mode detection. In this embodiment, the number of the code words is six, however, this number may be different, for example, dependent on circumstances of transmitting channel, transmitting environments, useful protection strength, and/or performance of codec.
First, the syndromes
σi,m(k):=[Ci,m](αk) (36)
of the colored code words are calculated for i=0, 1, . . . , 5, m=2, 3, 4 and k=1, 2, . . . , δi(m)−1, i.e., for the first at least six transmitted code words. It is noteworthy that
[Ci,m](αk)=[Ci](αk)+sigk(αk) (37)
where sigk(ak) may be tabulated. That is, the syndromes of the colored code words Ci,m may be computed efficiently by coloring the syndromes of the code words Ci. So considering all modes does not increase worst case complexity of syndrome calculation.
If an m exists, such that σi,m(k)=0 for k=1, 2, . . . , δi(m)−1, then mode m is selected. Note that this is typically the case if no transmission errors occurred and that by the selection of sigk such an m is typically unique.
Otherwise, transmission errors have occurred and mode detection proceeds to calculating error locator polynomials for the remaining modes. At this stage, these are polynomials
Λi,m(x):=1+λi,m(1)x+ . . . +λi,m(di,m)xd
where
and where the coefficients are a unique solution to
σi,m(n)+Σk=1d
for n=di,m+1, di,m+2, . . . , δi(m)−1. Such a polynomial does not necessarily exist if code word i is not correctable in mode m and if a code word is encountered for which no such Λi,m can be found, mode m is excluded from the list of candidate modes.
Otherwise, i.e., such Λi,m is found, a risk value is calculated for all remaining modes m according to
The code word length 14 is hereby used as an estimate for the real risk
since Li varies from 13 to 15 for the slot sizes in question. The modes for which ρm is larger than a given threshold are excluded from further processing. It is noted that the threshold is, for example, 6×10−8, however, this value may be varied dependent on the useful transmitting quality and other useful criteria.
For the remaining modes (at this stage usually only one mode remains) the error locater polynomials are factorized in GF(16)[x]. Factorization is said to be successful if the polynomial splits into distinct linear factors of the following kind:
Λi,m
If this is the case, then Ci,m
On successful mode detection, error correction of the code words Ci,m
If mfec>1 the decoded data is validated by re-calculating the hash value and compared to the hash value included in the transmitted code words at the post processor 68. If validation is successful, the decoded data is output according to the data arrangement at the encoder. Otherwise, a bad frame is signaled to the channel encoder 2.
When the decoding mode is selected, the decoding mode indicator indicating the certain decoding mode is generated and sent to the de-colorator 22, the RS decoder 24 and the post processor 68 as shown in
In accordance with the embodiments of the present application, the channel encoder indicates the coding mode by applying the coloration sequence to the code word of the frame. Therefore, it is not necessary to separately transmit the data to indicate the certain coding mode and useful parameters, and hence, data transmission rate is improved. In addition, the information/indication of the coding mode is included in the code word by applying the coloration sequence which is selected in accordance with the coding mode, and hence, it is possible to provide error resilient mode signaling. Furthermore, the information/indication of the coding mode is distributed in the code word by applying the coloration sequence, and therefore, the information/indication of the coding mode is received at the channel decoder in an error resilient way. In addition, the channel decoder is able to determine the decoding mode without separately receiving specific information about the decoding mode and parameters to determine the decoding mode. Hence, data transmission ratio of the channel is effectively improved.
In accordance with the embodiments of the present application, the channel decoder performs a test decoding to examine whether an error has occurred or not for detecting the decoding mode. Therefore, in case no transmission error has occurred, a reliable decoding mode is determined in a simple calculation.
In accordance with the embodiments of the present application, in case the transmission error has occurred, the channel decoder performs error correction for a predetermined number of code words as a test and calculates the risk value of errors (reliability measure). Therefore, without receiving specific information and parameters from the channel encoder, it is possible to determine appropriate decoding mode by testing the predetermined number of code words and considering the reliability measure.
In accordance with the embodiments of the present application, the decoding mode indicator comprises a decoding mode detector for detecting the decoding mode by testing the predetermined number of code words to deduce the candidate of the decoding mode in the decoding mode candidate list. The candidates in the candidate list is excluded or blacklisted based on occurred errors, and the certain decoding mode is finally selected from the remaining decoding mode candidates in the candidate list considering the reliability measure (risk value). Then the decoding mode indicator includes risk value of the selected decoding mode and in case the risk of error is larger than a predetermined threshold, the frame is registered as a bad frame. Therefore, it is possible to select reliable and appropriate decoding mode by testing only the predetermined number of code words.
Further embodiments are subsequently described.
Application Layer Forward Error Correction
1. Channel Coder
1.1 Functions and Definitions
1.2 General Channel Coder Parameters
1.2.1 FEC Mode
The FEC mode m is a number from 1 to 4, where m=1 provides only basic error protection and m=2, 3, 4 provides increasing error correction capability. At the channel encoder the FEC mode is denoted by mfec and at the channel decoder it is denoted nfec.
1.2.2 Slot Size
The slot size Ns specifies the size of the channel encoded frame in octets. Ns may take all integer values from 40 to 300, covering nominal bitrates from 32 to 240 kbps at a frame rate of 100 Hz.
1.2.3 CMR
The coding mode request CMR is a two-bit symbol represented by numbers from 0 to 3.
1.2.4 Joint Channel Coding Flag
The joint channel coding flag jcc_flag takes values 0 and 1 and indicates that the input data contains data from multiple audio channels.
1.3 Derived Channel Coder Parameters
1.3.1 Number of Code Words
The parameter Ncw specifies the number of code words that are used to encode the data frame. It is derived from the slot size by
1.3.2 Code Word Lengths
The parameter Li is defined for i=0 . . . Ncw−1 and specifies the length of the ith code word in semi-octets. It is derived from the slot size Ns as
1.3.3 Hamming Distances
The parameter di,m specifies the hamming distance of code word i in FEC mode m. It is given by
and for m>1 by
di,m:=2m−1 for i=0 . . . Ncw−1.
1.3.4 Number of Partial Concealment Code Words
The parameter Npccw specifies the number of partial concealment code words and is derived from slot size Ns and FEC mode m by
1.3.5 Size of Partial Concealment Block
The parameter Npc specifies the size of the partial concealment block in semi-octets and is derived from slot size Ns and FEC mode m by
Npc:=Σi=N
1.3.6 CRC Hash Sizes
The numbers NCRC1 and NCRC2, which correspond to sizes of CRC hash values, are derived from slot size and FEC mode m by
1.3.7 Payload Size
The payload size Np specifies the data size in a channel encoded frame of size Ns encoded in FEC mode m in octets, which is given by
1.4 Algorithmic Description of the Channel Encoder
1.4.1 Input/Output
The channel encoder takes as input the slot size Ns, the FEC mode mfec, the coding mode request CMR, a data sequence, for example, adat(0 . . . Np−1) of octets and a joint channel coding flag jcc_flag and returns a sequence of octets acc(0 . . . Ns−1). Octets are interpreted as numbers from 0 to 255 according to the specified endianness.
1.4.2 Data Pre-Processing
The data sequence is first split into a sequence an(0 . . . 2Np−1) of semi-octets with reversed ordering, where an(2k) holds the upper half of adat(Np−1−k) and an(2k+1) holds the lower half. In formulas this is
Next, CRC hash values are calculated on the bit-expansions of the sequences
an1(0 . . . 2Np−Npc−1):=an(0 . . . 2Np−Npc−1)
and
an2(0 . . . Npc−1):=an(2Np−Npc. . . 2Np−1).
Note that Npc might be zero in which case an2 is the empty sequence. The bit-expansion of a semi-octet sequence a (0 . . . N−1) is defined by the sequence b(0 . . . 4N−1), where
b(4k+j):=bitj(a(k))),
with k ranging from 0 to N−1 and j ranging from 0 to 3 and bitj is the function returning the jth bit according to the specified endianness.
The first CRC hash sequence, calculated on an extension of an1, has length 8NCRC1−2 and the binary generator polynomials are given by
p14(x)=1+x2+x6+x9+x10+x14
and
p22(x)=1+x3+x5+x8+x9+x10+x11+x16+x19+x22.
The second CRC hash sequence, calculated on an2, has length 8NCRC2 and the binary generator polynomial is given by
p16(x)=1+x+x3+x5+x6+x7+x9+x13+x15+x16.
The CRC hash sequence of length k on a binary data sequence b(0 . . . N−1) for a given binary generator polynomial p(x) of degree k is defined as usual to be the binary sequence r(0 . . . k−1) such that the binary polynomial
is divisible by p(x).
Let bn1 denote the bit-expansion of an1 and let bn2 denote the bit-expansion of an2. Then the sequence rn1(0 . . . 8NCRC1−3) is set to be the hash sequence of length 8NCRC1−2 calculated on the concatenated sequence
bn1ext=(bit0(CMR),bit1(CMR),bn1(0) . . . bn1(8Np−4Npc−1)).
Furthermore, rn2(0 . . . 8NCRC2−1) is set to be the second hash sequence of length 8NCRC2 calculated on bn2. Note that rn2 is the empty sequence if NCRC2=0.
The first pre-processed data sequence bpp0(0 . . . 8(Np+NCRC1+NCRC2)−1) is then defined by
bpp0(0 . . . 8NCRC1−3):=rn1(0 . . . 8NCRC1−3)
bpp0(8NCRC1−2):=bit0(CMR)
bpp0(8NCRC1−1):=bit1(CMR)
bpp0(8NCRC1 . . . 8(NCRC1+NCRC2)−1):=rn2(0 . . . 8NCRC2−1)
bpp0(8NCRC1+NCRC2) . . . 8(Np+NCRC1+NCRC2)−4Npc−1):=bn1(0 . . . 8Np−4Npc−1)
and
bpp0(8(NCRC1+NCRC2+NP)−4Npc. . . 8(NCRC1+NCRC2+Np)−1):=bn2(0 . . . 4Npc−1).
The final pre-processed data sequence is given by swapping the CMR bits at positions 8NCRC1−2 and 8NCRC1−1 with bits at positions k:=4(7−d0,m
bpp(NCRC1−2):=bpp0(k)
bpp(NCRC1−1):=bpp0(k+2)
bpp(k):=bpp0(NCRC1−2)
bpp(k+2):=bpp0(NCRC1−1)
and
bpp(n):=bpp0(n)
for n different from 8NCRC1−2, 8NCRC1−1, k, and k+2. Swapping of these bits ensures that the CMR bits are stored in an FEC mode independent bit positions located in the middle of the channel encoded bitstream.
The bit-sequence bpp is converted into a semi-octet sequence app(0 . . . 2(NCRC1+NCRC2+Np)) by reversing the bit-expansion, i.e.
app(k):=bpp(4k)+2bpp(4k+1)+4bpp(4k+2)+8bpp(4k+3).
Note that it is not necessary to actually carry out the bit-expansions described in this clause as CRC hashes can be computed efficiently on data blocks.
1.4.3 Reed-Solomon Encoding
For Reed-Solomon (RS) encoding the pre-processed data sequence app from clause 1.4.2 is split into Ncw sequences Di, also referred to as data words, according to
Di(0 . . . Li−di,m
where i ranges from 0 to Ncw−1 and where the split points Si are inductively defined by S0=0 and Si+1=Si+Li−di,m
The RS codes are constructed over GF(16)=GF(2)/(x4+x+1), where the residue class of x in GF(2)/(x4+x+1) is chosen as unit group generator, denoted as usual by α. Semi-octets are mapped to elements of GF(16) using the data-to-symbol mapping
n→[n]:=bit0(n)α0+bit1(n)α1+bit2(n)α2+bit3(n)α3.
The mapping is one-to-one and the inverse mapping is denoted β→β, such that [β]=β.
With this notation the Reed-Solomon generator polynomials for Hamming distances 3, 5, and 7 are given by
q3(y):=[8]+[6]y+[1]y2,
q5(y):=[7]+[8]y+[12]y2+[13]y3+[1]y4,
and
q7(Y):=[12]+[10]y+[12]y2+[3]y3+[9]y4+[7]y5+[1]y6.
For i ranging from 0 to Ncw−1 the RS redundancy sequences Ri(0 . . . di,m
is divisible by qd
Ci(0 . . . di,m
and
Ci(di,m
Note that if di,m
1.4.4 Mode Signaling
The FEC mode mfec is not explicitly transmitted but rather signalled implicitly by coloring the first 6 code words by mode dependent coloration sequences, i.e.
where bitxor(a, b) denotes the bit-wise XOR operation on two semi-octets. The signaling sequences sigm are given by
Note that code word coloration leaves the CMR bits at bit positions 30 and 32 of C0 unchanged.
1.4.5 Code Word Multiplexing
The sequences CCi are multiplexed into a sequence of octets first by interleaving the semi-octets according to
ail(Ncwk+i):=CCi(k),
where i ranges from 0 to Ncw−1 and k ranges from 0 to Li−1, and then by pairing consecutive semi-octets according to
acc(k):=ail(2k)+16ail(2k+1)
where k ranges from 0 to Ns−1.
1.5 Algorithmic Description of the Channel Decoder
1.5.1 Input/Output
The channel decoder takes as input the slot size Ns and a sequence zcc(0 . . . Ns−1) of octets and a joint channel coding flag jcc_flag and returns the payload size Np, a sequence of decoded octets zdat(0 . . . Np−1), a bad frame indicator bfi taking values 0, 1, and 2, a CMR estimate XNI taking values from 0 to 11, a number error_report taking values from −1 to 480 (indicating the number of corrected bits if bfi=0), and a bit position indicator fbcwbp for partial concealment.
The values Np and zdat(0 . . . Np−1) are only specified if bfi≠1, and the value of the bit position indicator fbcwbp is only specified if bfi=2.
1.5.2 Code Word De-Multiplexing
From the slot size Ns the derived parameters Ncw and Li are calculated according to clauses 1.3.1 and 1.3.2. The input sequence zcc(0 . . . Ns−1) is then split into a sequence zil(0 . . . 2Ns−1) of semi-octets according to
for k=0 . . . Ns−1, and code words XXi are extracted according to the data arrangements of clause 1.4.5, i.e.
XXi(k):=zil(k Ncw+i),
where i ranges from 0 to Ncw−1 and k ranges from 0 to Li−1.
1.5.3 Mode Detection
Mode detection aims at recovering the FEC mode mfec by analysing the code words XXi, where i ranges from 0 to 5. The detected mode is denoted nfec and takes values from 0 to 4, where 0 indicates that no mode has been detected. Once a mode has been detected all derived codec parameters such as the payload size, number of partial concealment code words, etc. are defined according to this mode. The mode is chosen from a list of candidate modes, initially containing FEC modes 1 to 4, which is then narrowed down step by step.
1.5.3.1 Stage 1
Stage 1 tries to determine whether the frame was encoded in FEC mode 1. To this end, the first two syndromes of code word 0 are calculated, where the kth syndrome of code word XXi is defined to be the GF(16) symbol defined by
Mode 1 is selected if the following two conditions are satisfied:
If these conditions are satisfied, error_report and bfi are set to 0 and the channel decoder outputs the data zdat(0 . . . Np−1) as generated in clause 1.5.7. Otherwise, mode detection enters stage 2 and mode 1 is removed from the candidate list.
1.5.3.2 Stage 2
Stage 2 tries to determine whether the frame was encoded in FEC modes 2, 3, or 4. To this end, the syndromes Sk(i) are calculated for i=0 . . . 5 and k=1 . . . 6.
If for one m∈{2,3,4} the conditions
are satisfied for i=0 . . . 5 and k=1 . . . di,m−1, that is all syndromes colored according to mode m vanish, then nfec:=m is selected and the channel coder proceeds to clause 1.5.6. Note that such an m is typically unique so the modes may be tested in any order.
If no such m can be found then mode detection calculates the error locator polynomials Λi,m(y) for i=0 . . . 5 and m=2 . . . 4. This is done according to clause 1.5.5.1.1 with
and
the colored syndromes according to mode m, for k=1 . . . 2t.
All modes m for which Λi,m(y)=[0] for at least one i from 0 to 5 are excluded from further consideration.
For the remaining modes a risk value is computed. The risk value rsk(m) for mode m is based on the degrees of the error locator polynomials Λi,m (y) and is computed as mantissa exponent pair
(μm,∈m):=(((((μ0,m,∈0,m)*(μ1,m,∈1,m))*(μ2,m,∈2,m))*(μ3,m,∈3,m)*(μ4,m,∈4,m))*(μ5,m,∈5,m),
where the mantissa exponent pairs (μi,m, ∈i,m) are specified in Table 2, and where the multiplication of two mantissa exponent pairs is defined as follows: Given two pairs (μ, ∈) and (μ′, ∈′), where 0≤μ, μ′<215, the product (μ, ∈)*(μ′, ∈′) is defined to be the pair (μ″, ∈″) given by
Such a mantissa exponent pair (μ, ∈) corresponds to the number μ*2∈−14.
All modes m for which the corresponding risk value rks(m) lies above a slot size dependent threshold risk_thresh are removed from the list of candidate modes. The risk threshold is defined to be
The remaining modes with risk value smaller than or equal to risk_thresh are enumerated as mj,j=1 . . . n, such that for every j=1 . . . n−1 either rsk(mj)<rsk(mj+1), or rsk(mj)=rsk(mj+1) and mj<mj+1 holds.
Starting from mode m1, the error positions nm
In case no mode is detected, i.e. nfec=0, error_report is set to −1, CMR detection is carried out according to clause 1.5.4 with M={1, 2, 3, 4} before the channel decoder exits with bfi=1.
1.5.4 CMR Estimation when Frame is not Decodable
In case the frame is not decodable the CMR is estimated by analyzing the first code word XX0 and the corresponding error locator polynomials Λ0,m for all modes m∈M, where M is a given set of candidate modes.
First all modes are removed from M for which either
The set of remaining modes is denoted M1.
If M1 is empty the CMR estimate XNI is set to
XNI=bit2(XX0(7))+2 bit0(XX0(8))+8,
where the summand 8 indicates that this value is not validated.
If M1 is not empty then let m denote the element of M1 for which the risk value exponent ∈0,m is minimal (note that such a mode typically exists since ∈0, 1 and ∈0,2 cannot both have value −8 by design of the signalling sequences). Then, error correction is performed on XX0 according to clause 1.5.5 with nfec=m and the CMR estimate is derived from the corrected code word XX0c as either
XNI=bit2(XX0c(7))+2 bit0(XX0c(8))+4
if ∈0,m≥−16, where the summand 4 indicates that the CMR was validated with medium high confidence, or
XNI=bit2(XX0c(7))+2 bit0(XX0c(8))
if ∈0,m≤−16 indicating that the CMR value was validated with high confidence.
1.5.5 Error Correction
Full error correction is carried out only upon successful mode detection. In this case the error positions for nn
The code words XXi with i≤5 are corrected by calculating the error symbols ∈i,k according to clause 1.5.5.3 with
Sk(i) being defined as in clause 1.5.3.2, and
vk=nn
The corrected code words are then defined by
where <.> is the inverse data-to-symbol mapping specified in clause 1.4.3.
For the remaining code words with index i>5 error correction is performed by carrying out the usual steps:
for with.
If error correction fails for an index i<Ncw−Npccw, i.e. one of the steps 3, 4 or 5 failed, the bad frame indicator bfi is set to 1, error_report is calculated as specified below and channel decoding is terminated.
For indices i≥Ncw−Npccw a sequence T(Ncw−Npccw . . . Ncw−1) is defined as follows. If error correction fails for an index i≥Ncw−Npccw or if the risk value exponent ∈i,m as specified in Table is larger than −16 the value T(i) is set to 0, indicating that the data in code word XXi is not reliable without further validation. If error correction fails, the corrected code word XXic is nevertheless defined to be XXi but the first bad frame indicator bfi0 is set to 2.
The value of error_report is set as follows. If error correction failed for an index i<Ncw−Npccw then let i1 denote the smalles index for which it failed and set I={0, . . . , i1−1}. Otherwise let I denote the set of all indices 0<i<Ncw for which error correction succeeded. The value of error_report is then calculated as
that is the total number of bits corrected in code words XXi with i∈I.
If Ns=40 the number of bit correction is artificially reduced to increase error detection. If all code words have been corrected successfully first bad frame indicator is set depending on a mode dependent error threshold emaxm given by
If error_report≤emaxn
If Ns>40 and all code words have been corrected successfully, then first bad frame indicator bfi0 is set to 0.
1.5.5.1.1 Calculation of Error Locator Polynomials
The error locator polynomial is calculated from a sequence σk, k=1 . . . 2t, of symbols in GF(16), where t is a number from 1 to 3.
If σk=[0] for k=1 . . . 2t, the error locator polynomial Λ(y) is set to [1].
Otherwise, the determinants of matrices Ml are calculated for l=1 . . . t, where
M1:=(σ1)
If all determinants are [0] for l=1 . . . t the error locator polynomial Λ(y) is set to [0], which is a non-valid error locator polynomial in the sense of 1.5.5.2.
Otherwise, take τ to be the largest index from 1 to t such that det(Mτ)≠0. Then the coefficients of the error locator polynomial are computed as
where the inverse matrices are given by
If Λτ=[0], the error locator polynomial is set to [0].
Otherwise, if τ=t, the error locator polynomial is set to
Λ(y)[1]+λ1y+ . . . +λtyt
and if τ<t it is further tested whether
holds for n=0 . . . 2(t−τ)−1. If all these equalities hold, then the error locator polynomial is set to
Λ(y):=[1]+λ1y+ . . . +λτyτ.
Otherwise, it is set to [0].
1.5.5.2 Calculation of Error Positions
Error positions are calculated from the error locator polynomial
Λ(y):=[1]+λ1y+ . . . +Λtyd.
The error locator polynomial is said to be valid, if it admits a representation
in which case the error positions are given by nk for k=0 . . . d−1. Otherwise, the list of error positions is empty.
The values nk can be determined by testing Λ(α−n)=0 for n=0 . . . Li−1. Alternatively, tabulation of error locations indexed by λi is possible and might be considerably faster.
1.5.5.3 Calculation of Error Symbols
Error symbols are calculated from syndromes σ1, . . . , σd and error positions v0, . . . , vd-1 by solving the linear system
over GF(16), where Ad(v0, . . . , vd-1) are the Vandermonde matrices
The matrix inverses are given by
1.5.6 De-Coloration and RS Decoding
De-coloration according to the detected FEC mode nfec is done by applying the corresponding signaling sequence from clause 1.4.4, giving rise to de-colorated code words
Then, redundancy decoding is applied according to mode nfec producing the data words
Wi(0 . . . Li−di,n
which are combined into the data sequence zpp(0 . . . Np−1), with Np as specified in clause 1.3.7 with m=nfec, according to
zpp(Si. . . Si+Li−di,n
for i=0 . . . Ncw−1, where the split points Si are as defined in clause 1.4.3. This yields a sequence of length 2(Np+NCRC1+NCRC2). After RS redundancy decoding the FEC decoder proceeds to clause 1.5.7 Data Post-Processing.
1.5.7 Data Post-Processing
Data post-processing consists of hash removal and validation, and CMR extraction. The sequence zpp from clause 1.5.6 is expanded into the corresponding bit sequence ypp from which the sequence ypp0 is derived by reversing the bit swap from clause 1.4.2, i.e. swapping bits at positions 8NCRC1−2 and k:=4(7−d0,n
The sequence ypp0 is then split into sequences in1, in2, Yn1ext, and yn2, corresponding to sequences rn1, rn2, bn1ext, and bn2 from clause 1.4.2, given by
in1(0 . . . 8NCRC1−3):=ypp0(0 . . . 8NCRC1−3),
in2(0 . . . 8NCRC2−1):=ypp0(8NCRC1. . . 8(NCRC1+NCRC2)−1),
yn1ext(0 . . . 1):=ypp0(8NCRC1−3 . . . 8NCRC1−1),
yn1ext(2 . . . 8Np−4Npc+1):=ypp0(8(NCRC1+NCRC2) . . . 8(NCRC1+NCRC2+Np)−4Npc−1,
and
yn2(0 . . . 4Npc−1):=ypp0(8(NCRC1+NCRC2+NP)−4Npc. . . 8(NCRC1+NCRC2+Np).
The two cyclic redundancy checks (CRC) are carried out on yn1ext and yn2 are carried out by re-calculating the hash sequences specified in clause 1.4.2.
If the calculated 8NCRC1−2 bit redundancy sequence for yn1ext specified in clause 1.4.2 does not match in1 the bad frame indicator bfi is set to one and the CMR is estimated according to clause 1.5.4 with M={nfec}. Otherwise, the CMR estimate is set to
XNI=yn1ext(0)+2yn1ext(1).
If the first CRC is passed and if bfi0≠2, the second CRC is carried out calculating the 8NCRC2 hash sequence for yn2 as specified in clause 1.4.2. If the result does not match the sequence in2 the bad frame indicator bfi is set to 2, indicating the loss of partial concealment data. If the first CRC is passed and bfi0=2 then bfi is set to 2 without carrying out the second CRC.
If both CRCs are passed, the bad frame indicator bfi is set to 0, indicating that the decoded data is valid.
If bfi=2, the position fbcwbp of the first potentially corrupted bit in the partial concealment block is determined from the sequence T(Ncw−Npccw . . . Ncw−1) from clause 1.5.5 in the following way.
If no index i exists such that Ncw−Npccw≤i<Ncw and such that T(i)=1 or if T(Ncw−1)=0 then fbcwbp is set to 0. Otherwise, let i0 denote the largest index such that T(i)=1 for i0≤i<Ncw. Then fbcwbp is calculated as
If bfi≠1 the output data is zdat is generated by reversing the pre-processing steps from clause 1.4.2 by setting
yn1(0 . . . 8Np−4Npc−1)yn1ext(2 . . . 8Np−4Npc+1),
zn1(k)=yn1(4k)+2yn1(4k+1)+4yn1(4k+2)+8yn1(4k+2)
for k=0 . . . 2Np−Npc−1,
zn2(k)=yn2(4k)+2yn2(4k+1)+4yn2(4k+2)+8yn2(4k+2)
for k=0 . . . Npc−1,
zn(0 . . . 2Np−Npc−1):=zn1,
zn(2Np−Npc. . . 2Np−1):=zn2,
and
zdat(k):=zn(2Np−2k−1)+16zn(2Np−2k−2)
for k=0 . . . Np−1.
Although some aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus. Some or all of the method steps may be executed by (or using) a hardware apparatus, like for example, a microprocessor, a programmable computer or an electronic circuit. In some embodiments, one or more of the most important method steps may be executed by such an apparatus.
The inventive data stream can be stored on a digital storage medium or can be transmitted on a transmission medium such as a wireless transmission medium or a wired transmission medium such as the Internet.
Depending on certain implementation requirements, embodiments of the application can be implemented in hardware or in software. The implementation can be performed using a digital storage medium, for example a floppy disk, a DVD, a Blu-Ray, a CD, a ROM, a PROM, an EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed. Therefore, the digital storage medium may be computer readable.
Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.
Generally, embodiments of the present application can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer. The program code may, for example, be stored on a machine readable carrier.
Other embodiments comprise a computer program for performing one of the methods described herein, stored on a machine readable carrier.
In other words, an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.
A further embodiment of the inventive methods is, therefore, a data carrier (or a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein. The data carrier, the digital storage medium or the recorded medium are typically tangible and/or non-transitionary.
A further embodiment of the inventive method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein. The data stream or the sequence of signals may, for example, be configured to be transferred via a data communication connection, for example via the internet.
A further embodiment comprises a processing means, for example a computer, or a programmable logic device, configured to or adapted to perform one of the methods described herein.
A further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.
A further embodiment according to the invention comprises an apparatus or a system configured to transfer (for example, electronically or optically) a computer program for performing one of the methods described herein to a receiver. The receiver may, for example, be a computer, a mobile device, a memory device or the like. The apparatus or system may, for example, comprise a file server for transferring the computer program to the receiver.
In some embodiments, a programmable logic device (for example a field programmable gate array) may be used to perform some or all of the functionalities of the methods described herein. In some embodiments, a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein. Generally, the methods are advantageously performed by any hardware apparatus.
The apparatus described herein may be implemented using a hardware apparatus, or using a computer, or using a combination of a hardware apparatus and a computer.
The apparatus described herein, or any components of the apparatus described herein, may be implemented at least partially in hardware and/or in software.
While this invention has been described in terms of several embodiments, there are alterations, permutations, and equivalents which fall within the scope of this invention. It should also be noted that there are many alternative ways of implementing the methods and compositions of the present invention. It is therefore intended that the following appended claims be interpreted as including all such alterations, permutations and equivalents as fall within the true spirit and scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
19156997 | Feb 2019 | EP | regional |
19157036 | Feb 2019 | EP | regional |
19157042 | Feb 2019 | EP | regional |
19157047 | Feb 2019 | EP | regional |
PCT/EP2019/065172 | Jun 2019 | WO | international |
PCT/EP2019/065205 | Jun 2019 | WO | international |
PCT/EP2019/065209 | Jun 2019 | WO | international |
This application is a continuation of copending U.S. patent application Ser. No. 17/402,285 filed Aug. 13, 2021, which claims priority to International Application No. PCT/EP2020/053614, filed Feb. 12, 2020, which is incorporated herein by reference in its entirety, and additionally claims priority from European Applications Nos. EP 19156997.9, filed Feb. 13, 2019, EP 19157036.5, filed Feb. 13, 2019, EP 19157042.3, filed Feb. 13, 2019, EP 19157047.2, filed Feb. 13, 2019, International Application Nos. PCT/EP2019/065205, filed Jun. 11, 2019, PCT/EP2019/065209, filed Jun. 11, 2019, and PCT/EP2019/065172, filed Jun. 11, 2019, all of which are incorporated herein by reference in their entirety. The present application is concerned with multi-mode channel coding.
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20230274750 A1 | Aug 2023 | US |
Number | Date | Country | |
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Parent | 17402285 | Aug 2021 | US |
Child | 18312853 | US | |
Parent | PCT/EP2020/053614 | Feb 2020 | WO |
Child | 17402285 | US |