JP2002217876A - Decoding device and decoding method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the determining accuracy of a data rate and to reduce processing quantity and power consumption, which are required for data rate determination. SOLUTION: An encoding part 105 re-encodes decoding data stored in a decoding data storage part 104. A data conversion part 106 converts data of '0' outputted from the encoding part 105 into '1' and data of '1' into '-1', by adjusting them to data conversion performed on the opposite side of communication. A product-sum operation part 107 multiplies data outputted from the data conversion part 106 by demodulation data (soft determination value) stored in a demodulation data storage part 101 and adds them by the quantity of ITTI. The sum-product result is stored for the respective data rates. A data rate determining part 108 determines the data rate corresponding to the sum- product result which becomes the maximal value among the sum-product results as the data rate of demodulation data.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a decoding device and a decoding method, and more particularly to a decoding device for performing a blind data rate determination.

[0002]

2. Description of the Related Art In a third generation mobile communication system using the CDMA system, a data rate is set to TTI (Tran).
It has been proposed to perform variable rate transmission in which the transmission is variable in units of a transmission time interval. At this time, the decoding device on the receiver side uses TFCI (Transport Format C
It has been proposed to perform a so-called blind data rate determination without using data rate identification information such as ombination indicator).

[0003] The TTI is a value defined for each transport channel and is 1, 2, 4, or 8
Take one of the values in the frame. On the transmitter side,
The error-corrected encoded data is divided into frames for one TTI and transmitted. Therefore, the TTI is:
It is a unit for error correction decoding of data.

[0004] Conventionally, as a decoding apparatus for performing a blind data rate determination, there is a decoding apparatus described in Japanese Patent Application Laid-Open No. 7-46146. In this decoding apparatus, a hard decision result (hard decision symbol) for an input symbol and a symbol obtained by re-encoding data after Viterbi decoding (re-encoding The data rate is determined in accordance with the result of comparison with the symbol. That is, in the conventional decoding device,
The number of times that the value of the hard-decision symbol and the value of the re-encoded symbol do not match (the number of symbol errors) is counted for each candidate data rate, and the data rate with the smallest number of symbol errors normalized at each data rate Is determined as the data rate of the received data.

[0005]

However, in the above-mentioned conventional decoding apparatus, the data rate is determined in accordance with the number of symbol errors, so that the following problem arises.

In the variable rate transmission of voice data proposed in the third generation mobile communication system using the CDMA system, the difference between transmission rates is very small (several bits to several tens bits per block). Differences). For this reason, in the above-described conventional decoding apparatus, the number of normalized symbol errors becomes equal at a plurality of transmission rates due to errors of only a few bits occurring in the propagation path, and the data rate cannot be determined. May occur.

[0007] Further, in a mobile communication system, it is expected that the amplitude fluctuation of a radio signal will increase due to the effect of fading. Since the hard decision result is more likely to be erroneous for a symbol having a smaller amplitude (lower likelihood) due to the influence of fading, the data rate is determined using the hard decision symbol as in the above-described conventional decoding apparatus. Then, the erroneous determination rate of the data rate may increase. If the data rate is determined incorrectly, the data will be decoded at the incorrect data rate,
All the data of the TTI for which the data rate is erroneously determined may be erroneously decoded, and the error rate characteristic of the received data is significantly deteriorated.

Further, in the above-mentioned conventional decoding apparatus, since all the data after Viterbi decoding are re-encoded irrespective of the encoding method, the processing amount and the power consumption required for the data rate determination become large. Therefore, when the above-mentioned conventional decoding device is mounted on a battery or a communication terminal driven by a battery, there is a problem that the use time of the communication terminal is shortened.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and provides a decoding apparatus and a decoding apparatus capable of improving the accuracy of data rate determination and reducing the processing amount and power consumption required for data rate determination. The purpose of the present invention is to provide a conversion method.

[0010]

The decoding device of the present invention comprises:
Decoding means for decoding the demodulated data of the soft decision value before and after decoding at a plurality of candidate data rates, and using the decoded data decoded by the decoding means and the demodulated data to determine the likelihood of the data rate. The present invention employs a configuration including a likelihood calculating unit that calculates a degree for each data rate, and a determining unit that determines a data rate having the highest likelihood as a data rate of the demodulated data.

[0011] In the decoding apparatus according to the present invention, the likelihood calculating means includes:
An encoding unit that re-encodes the decoded data; a conversion unit that converts the re-encoded data in accordance with the data conversion performed on the communication partner side; and a conversion unit that converts the value of the converted data and the value of the demodulated data. After performing the product-sum operation, a product-sum operation unit that obtains the likelihood of the data rate by normalizing the product-sum result at the data rate at the time of decoding is adopted.

According to these configurations, the likelihood of each data rate is determined using the soft decision value and the decoded data, and the data rate having the highest likelihood is determined as the correct data rate. Since the data rate can be determined in consideration of the degree, the probability that the data rate is erroneously determined can be significantly reduced.

[0013] In the decoding apparatus according to the present invention, the demodulated data is a systematic code composed of an information part and an encoded part, and the likelihood calculating means extracts an information part from the demodulated data; A conversion unit for converting the data value according to the data conversion performed on the communication partner side, and performing a product-sum operation of the converted data value and the value of the information portion, and then decoding the product-sum result at a data rate at the time of decoding. And a product-sum operation unit that obtains the likelihood of the data rate by normalizing with.

According to this configuration, when the demodulated data is a systematic code, the data rate is determined according to the product-sum result of the information portion extracted from the demodulated data and the decoded data that is not re-encoded. Since the re-encoding processing that increases the number of data becomes unnecessary, it is possible to reduce the processing amount and the power consumption required for the data rate determination.

[0015] The decoding apparatus of the present invention includes detection means for detecting whether or not there is an error in the decoded data using an error detection code, and the likelihood calculation means and the judgment means determine whether the error is detected by the detection means. A configuration is employed in which processing is performed only on undetected decoded data.

According to this configuration, the decoded data in which the error is detected by the error detection is not subjected to the data rate determination processing, so that the candidate data rates can be narrowed down before the data rate determination processing is performed. The processing amount and power consumption required for data rate determination can be reduced.

The decoding apparatus according to the present invention comprises a detecting means for detecting whether or not there is an error in the decoded data by using an error detecting code. When an error is detected in the decoded data at all the data rates, the processing is performed on the decoded data in which the error is detected.

According to this configuration, even when an error is detected at all candidate data rates, the most probable data rate is determined using decoded data in which the error is detected. In communication in which an error is allowed to some extent (for example, voice communication), it is possible to prevent a period during which data cannot be reproduced.

The decoding apparatus according to the present invention comprises a detecting means for detecting whether or not there is an error in the decoded data using an error detecting code, and a likelihood obtained from the decoded data from which no error is detected by the detecting means. Comparing means for comparing a maximum value with a threshold value, wherein the likelihood calculating means and the determining means decode at a plurality of candidate data rates when the maximum value is equal to or less than the threshold value. A configuration is adopted in which processing is performed on all of the decoded data that has been processed.

According to this configuration, when the reliability of the error detection is low, the data rate is determined by including the decoded data in which the error has been detected as an object. The data rate can be determined. In addition, only when the reliability of error detection is low, decoded data in which an error has been detected is also included in the data rate determination target. Therefore, data rate determination is performed from the beginning on all candidate data rate decoded data. The average processing amount and the average power consumption required for the data rate determination can be significantly reduced as compared with the case of performing.

The decoding apparatus according to the present invention employs a configuration in which the comparing means lowers the threshold value as the reception quality of the demodulated data is better.

According to this configuration, since the threshold value is adaptively changed according to the reception quality, it is possible to set an optimal threshold value according to the reliability of error detection.

In the decoding apparatus according to the present invention, when a plurality of transport blocks are included in a decoding unit, the detecting means detects an error only in the last transport block among the plurality of transport blocks. Do
When an error is detected in the last transport block, a configuration is adopted in which all the decoded data of the decoding unit has an error.

In the case where error correction decoding is performed based on the Viterbi algorithm, the data at the end of the data sequence of the decoding unit has a characteristic that the decoding accuracy is higher than the data at the head, so that this characteristic is obtained. According to the configuration
The reliability of the error determination can be improved. Further, since it is sufficient to perform error detection only on the last transport block, the number of times of error detection can be reduced.

According to the decoding apparatus of the present invention, when a plurality of transport blocks are included in a decoding unit, the detecting means detects an error in at least half of the plurality of transport blocks. A configuration is adopted in which all decoded data in the decoding unit has an error.

Third generation mobile communication standard (3GPP)
In the error detection (CRC) defined in the above, if even one bit of the data included in the transport block is erroneous, an error is detected in the transport block, and conversely, if most bits are erroneous. In addition, since an error may not be detected in the transport block in some cases, according to this configuration, the reliability of error determination can be improved.

According to the decoding apparatus of the present invention, when a plurality of transport blocks are included in a decoding unit, the detecting means detects an error in at least half of the plurality of transport blocks, and When an error is detected in the transport block, the decoding unit adopts a configuration in which all of the decoded data in the decoding unit has an error.

According to this configuration, when error correction decoding is performed based on the Viterbi algorithm, the reliability of error determination can be further improved.

The base station apparatus according to the present invention employs a configuration in which any one of the above-described decoding apparatuses is mounted. Further, a communication terminal device of the present invention employs a configuration in which any one of the above-described decoding devices is mounted.

According to these configurations, in the base station apparatus and the communication terminal apparatus, the error rate characteristics are improved by improving the data rate determination accuracy, so that the data communication quality, voice quality, and the like can be improved.

The decoding method of the present invention uses the decoded data obtained by decoding the demodulated data of the soft decision value after demodulation and before decoding at a plurality of candidate data rates and the demodulated data to determine the likelihood of the data rate. Degree is determined for each data rate,
The data rate with the highest likelihood is determined as the data rate of the demodulated data.

According to this method, the likelihood of each data rate is obtained using the soft decision value and the decoded data, and the data rate having the highest likelihood is determined as the correct data rate. Can be considered in consideration of the data rate, so that the probability that the data rate is erroneously determined can be significantly reduced.

[0033]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present inventors have paid attention to the fact that demodulated data after demodulation and before decoding are soft decision values, and use this soft decision value to determine the likelihood of each candidate data rate. The inventors have found that the present invention can be performed, and have led to the present invention.

That is, the gist of the present invention is to determine the likelihood of each data rate using demodulated data and decoded data obtained by decoding the demodulated data at a plurality of candidate data rates. By determining the data rate as the correct data rate of the demodulated data, the data rate is determined in consideration of the likelihood of the demodulated data.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1) FIG. 1 is a block diagram showing a configuration of a decoding apparatus according to Embodiment 1 of the present invention. The decoding device shown in FIG. 1 is mounted on a communication terminal device such as a mobile phone used in a mobile communication system, for example. This communication terminal device is, for example, a CD.
Wireless communication is performed by the MA method.

In this embodiment, the data transmitted from the communication partner is such that the data of '0' or '1' is error-correction-coded at a predetermined coding rate and a predetermined constraint length (here, The data is assumed to be data that has been subjected to convolutional coding, interleaving and the like, spread, modulated, converted to “1” or “−1”, and transmitted. The data rate of the data to be transmitted is such that one of the M data rates is selected in TTI units before the error correction coding of the data.

In the decoding apparatus shown in FIG. 1, demodulated data storage section 101 stores demodulated data in TTI units. Note that the demodulated data referred to here is despread, RAKE
Since it is data after a series of demodulation processes such as combining and deinterleaving and before error correction decoding, -X to X (X: the maximum value that can be taken by data that has been processed immediately before error correction decoding) The soft decision value data is within the range. Also, X
Is determined by the device configuration at the preceding stage of the demodulated data storage unit 101.

The error correction decoding section 102 converts the demodulated data stored in the demodulated data storage section 101 into M
At each of the different data rates, error correction decoding is performed based on, for example, the Viterbi algorithm. Then, when the decoding for one TTI is completed, the error correction decoding unit 102
The decoded data for one TTI is combined with information indicating a data rate at the time of decoding (hereinafter, referred to as data rate information) as a CR.
Output to C section 103.

The CRC section 103 performs error detection in units of TTI for each of M types of decoded data using an error detection code such as a CRC code added to the decoded data for each transport block. Do. Then, CRC section 103 outputs 1TT for which no error was detected.
Only the decoded data for the I-th part is converted to data rate information and CR
The result is output to the decoded data storage unit 104 together with the C result (that is, “0” indicating that no error was detected).

Here, one TTI (that is, a decoding unit)
If a plurality of transport blocks are included in the TTI, the CRC unit 103 performs the error detection on one or more predetermined transport blocks among the plurality of transport blocks included in one TTI according to the error detection result. An error determination is performed on the decoded data for one TTI.

That is, the CRC section 103 has 1) 1TT
Error detection is performed only on the last transport block out of a plurality of transport blocks included in I. If an error is detected on the last transport block, all the decoded data for one TTI has an error. And 2) If an error is detected in more than half of a plurality of transport blocks included in one TTI, all the decoded data corresponding to the one TTI is determined to have an error. 3) When an error is detected in more than half of a plurality of transport blocks included in one TTI and an error is detected in the last transport block, all the decoded data corresponding to the one TTI is regarded as having an error.

When the error correction decoding section 102 performs error correction decoding based on the Viterbi algorithm, it is preferable to use the above-mentioned method 1). In the Viterbi algorithm, 1TT
This is because the data at the end of the data sequence for I has a characteristic that the decoding accuracy is higher than the data at the head. That is, the reliability of the error detection result for the decoded data at the end is higher. Therefore, in this case, the reliability of the error determination can be improved by performing the error determination on the decoded data for one TTI using the error detection result for the last transport block. In this case, it is sufficient to perform error detection only on the last transport block, so that the number of times of error detection can be reduced.

The third generation mobile communication standard (3G
In the error detection (CRC) defined in (PP), if even one bit of data included in a transport block is incorrect, an error is detected in the transport block, and most bits are conversely detected. In the case of an error, an error may not be detected in the transport block. Therefore, by performing error determination on decoded data for one TTI according to the error detection results of a plurality of transport blocks as in the method 2), the reliability of error determination can be improved. Also, as in the above method 3), the above 1) and 2)
When the error correction decoding unit 102 performs error correction decoding based on the Viterbi algorithm, the reliability of error determination can be further improved.

The decoded data storage unit 104 stores the CRC
3 for each data rate, the data rate information of the decoded data and CR
It is stored together with the C result in TTI units. Also, the decoded data storage unit 104 includes a data rate determination unit 108 described later.
Outputs the decoded data for one TTI corresponding to the data rate determined together with the CRC result.

Encoding section 105 re-encodes the decoded data stored in decoded data storage section 104 at the same coding rate and constraint length as the convolutional coding performed on the communication partner side. At this time, the encoding unit 105 re-encodes each decoded data at the data rate indicated by the data rate information. The re-encoded '0' or '1' data is
Data conversion unit 1 together with data rate information in TTI units
06 is output.

The data conversion unit 106 is adapted to encode data in accordance with data modulation performed on the communication partner side (data of “0” is converted to “1” and data of “1” is converted to “−1”). The data of “0” output from 105 is converted into “1”, and the data of “1” is converted into “−1”. The product-sum operation unit 107
Data output from data conversion section 106 and demodulated data (soft decision value) stored in demodulated data storage section 101
And then add 1 TTI, and store the product-sum result for each data rate.

The data rate determination section 108 detects the maximum value of the sum of products obtained from the sum of products calculated by the sum of products calculation section 107, and determines the data rate corresponding to the maximum value of the sum of products to the demodulated data. Is determined as the data rate. Then, the data rate determination unit 108 outputs a data rate control signal indicating the determined data rate to the decoded data storage unit 10.
4 is output.

Next, the operation of the decoding apparatus having the above configuration will be described. The error correction decoding unit 102 performs error correction decoding on the data stored in the demodulated data storage unit 101 at all M types of candidate data rates. Each of the error-corrected decoded data of the M data rates is output to the CRC section 103 together with data rate information in TTI units, and error detection is performed. Then, among the decoded data of the M data rates, only the decoded data of the N data rates (N ≦ M) without error are stored in the decoded data storage unit 104 together with the data rate information and the CRC result, and Certain decrypted data is discarded.

Here, in the present embodiment, first, the result of decoding the demodulated data at each data rate (however,
It is assumed that the data for which no error is detected by error detection) is correct decoded data. Next, the data rate is determined assuming that the most probable data assumed as correct decoded data is decoded at the correct data rate.

As described above, the demodulated data is -X
The soft decision value is in the range of ~ X. At this time, the probability that the demodulated data is correctly decoded depends on whether the soft decision value is -X or X
, And becomes smaller as it approaches 0.
That is, the probability that the demodulated data is correctly decoded increases as the absolute value of the soft decision value increases. Thus, in the present embodiment, the likelihood (degree of certainty) of the data rate is calculated using the soft decision value, and the data rate of the demodulated data is determined based on the height of the likelihood.

That is, in the encoding unit 105, the decoded data of the M data rates stored in the decoded data storage unit 104 is re-encoded at the data rate indicated by the data rate information of each decoded data. Re-encoding is performed, for example, in descending order of data rate. The re-coded '0' or '1' data is output to the data conversion unit 106 together with data rate information in TTI units.

In the data converter 106, the data "0" is converted to "1" and the data "1" is converted to "-1". The converted data is output to the product-sum operation unit 107 together with data rate information in TTI units.

In the product-sum operation unit 107, the data conversion unit 10
6 (hereinafter referred to as converted data)
And the demodulated data (soft decision value) stored in the demodulated data storage unit 101 are multiplied by the corresponding symbols, and then added by the number of symbols corresponding to each data rate.

Since the number of symbols included in one TTI for each data rate is predetermined, the product-sum operation unit 10
In 7, the product-sum result added for the number of symbols corresponding to each data rate is divided by the number of symbols to be normalized at each data rate. The normalized product-sum result is calculated by the product-sum operation unit 107 corresponding to the data rate.
Is stored in the internal memory.

Here, if the sign (positive or negative) of the converted data and the sign (positive or negative) of the demodulated data match, their product becomes a positive value, and if they differ, the value of the product becomes It will be a negative value. The magnitude of the absolute value of the product is proportional to the magnitude of the absolute value of the soft decision value. Therefore, the normalized product-sum result becomes a larger value as the number of symbols in which the sign of the soft decision value and the sign of the converted data match increases, and
The larger the absolute value of the soft decision value when the codes match, the larger the value. That is, the normalized product-sum result corresponds to relative energy of likelihood between decoded data decoded at each data rate.

Since the likelihood of the data rate can be regarded as higher as the value of the normalized product-sum result is larger, the data rate determining unit 108 determines the maximum value of the product-sum results stored in the memory of the product-sum operation unit 107. A product-sum result that is a value is detected, and a data rate corresponding to the maximum value is determined as a data rate of demodulated data. Then, a data rate control signal indicating the determined data rate is transmitted to the decoded data storage unit 10.
4 is output.

Then, decoded data storage section 104 outputs decoded data for one TTI corresponding to the data rate determined by determination section 108 together with the CRC result.

As described above, according to the present embodiment, the likelihood of each data rate is obtained using the soft decision value and the decoded data, and the data rate having the highest likelihood is determined as the correct data rate. Since the data rate can be determined in consideration of the likelihood of the demodulated data, the probability that the data rate is erroneously determined can be significantly reduced.

Further, decoded data in which an error is detected by error detection such as CRC is discarded, and is not subjected to data rate determination processing such as re-encoding or product-sum operation. For this reason,
Before performing the data rate determination process, candidate data rates can be narrowed down, so that the average processing amount and average power consumption required for data rate determination can be reduced.

In this embodiment, a case has been described where data transmitted from a communication partner is convolutionally encoded data. However, even when data transmitted from the communication partner is encoded by an encoding method other than the convolutional coding, the error correction decoding unit 102 performs decoding by a decoding method corresponding to the encoding method of the communication partner. Then, the encoding unit 105 performs the re-encoding using the encoding method of the communication partner, so that the data rate can be determined in the same manner as described above. For example, when the data transmitted from the communication partner is turbo-coded, the error correction decoding unit 102 performs turbo decoding, and the coding unit 105 performs re-encoding with turbo code. Similarly, data rate determination can be performed.

In this embodiment, the product-sum operation unit 10
The normalization process performed by 7 has been described as a process of dividing the sum of products obtained by adding the number of symbols corresponding to each data rate by the number of symbols. However, the least common multiple is calculated between the number of symbols corresponding to each data rate, the least common multiple is divided by the number of symbols corresponding to each data rate, and the result of the division is added by the number of symbols corresponding to each data rate. It is also possible to perform normalization processing by multiplying the sum result. Also, find the greatest common divisor between the number of symbols corresponding to each data rate, divide the number of symbols corresponding to each data rate by the greatest common divisor, and add the result of the division by the number of symbols corresponding to each data rate. It is also possible to perform a normalization process by dividing the product-sum result.

In this embodiment, the product-sum operation unit 10
The product sum 7 may be configured to multiply the product sum result by a constant and then normalize the result by multiplying the product sum result by a predetermined coefficient or performing a shift operation on the product sum result. In this way, by multiplying the product-sum result by a constant, even when the product-sum result has a very small value, it is possible to prevent underflow from occurring in the normalized product-sum result.

(Embodiment 2) In the present embodiment, a case will be described where demodulated data is data that has been subjected to systematic encoding (for example, turbo encoding).

When the demodulated data is a systematic code such as a turbo code, the demodulated data is composed of information bits and coded bits, which can be easily separated. That is, the bits in the demodulated data are distinguished into information bits to be decoded as decoded data and coded bits added to correct errors in the information bits.

Therefore, in the present embodiment, the data rate is determined according to the product-sum result of the information bits extracted from the demodulated data and the decoded data that is not re-encoded.
By doing so, when the demodulated data is a systematic code, the data rate can be determined without performing re-encoding processing on the decoded data. Can be shortened.

FIG. 2 is a block diagram showing a configuration of a decoding apparatus according to Embodiment 2 of the present invention. As shown in this figure, the decoding device according to the present embodiment is different from the decoding device shown in FIG.
05 is omitted and an information bit extracting unit 201 for extracting information bits from demodulated data is provided. Note that FIG.
In FIG. 7, the same parts as those in FIG. 1 are denoted by the same reference numerals as in FIG. 1, and detailed description thereof will be omitted.

In FIG. 2, demodulated data input to demodulated data storage section 101 is a systematic code such as a turbo code. In the information bit extraction unit 201, the demodulated data storage unit 1
Only information bits are extracted from the demodulated data stored in 01 and output to the product-sum operation unit 107. The data conversion unit 104 converts the data “0” stored in the decoded data storage unit 104 into “1” and the data “1” into “−1” and outputs the converted data to the product-sum operation unit 107. You.

In the product-sum operation unit 107, the data conversion unit 10
6 and the information bits output from the information bit extraction unit 201 are obtained for each of N types of candidate data rates. The product-sum result is normalized as in the first embodiment.

The data rate determination section 108 detects the product sum result having the maximum value among the product sum results, and determines the data rate corresponding to the product sum result of the maximum value as the data rate of the demodulated data. Then, a data rate control signal indicating the determined data rate is output to decoded data storage section 104.

As described above, according to the present embodiment, when the demodulated data is a systematic code, the data rate is determined according to the product sum of the information bits extracted from the demodulated data and the decoded data that is not re-encoded. This eliminates the need for re-encoding processing that requires an extremely large amount of computation. Therefore, compared to the first embodiment, it is possible to further reduce the processing amount and the power consumption required for the data rate determination.

(Embodiment 3) In Embodiment 1 described above,
Because the data rate is determined only for decoded data for which no error is detected,
If an error is detected at any of the M types of candidate data rates, the data rate of the demodulated data will not be determined.

Here, if the voice communication (that is, the demodulated data is voice data), the voice data is reproduced according to the data rate determined by the decoding device. For this reason,
If the data rate is not determined, the audio data for one TTI cannot be reproduced, and a silent section will occur.

When demodulated data is voice data, even if an error is detected at all of the M types of candidate data rates, if the degree of the error is relatively small, the most probable data is detected. As long as the rate can be determined, audio can be reproduced to some extent correctly by an audio decoding method such as AMR (Adaptive Multi Rate).

Therefore, in the present embodiment, even when an error is detected in decoded data at all candidate data rates, the data determination processing is performed on the decoded data in which the error is detected, thereby making it possible to obtain the most data. Judgment of a probable data rate.

FIG. 3 is a block diagram showing a configuration of a decoding apparatus according to Embodiment 3 of the present invention. As shown in this figure, in the decoding apparatus according to the present embodiment, as compared with the decoding apparatus shown in FIG. It further includes an error counter 301 for counting the number of decoded data. In FIG. 3, the same portions as those in FIG. 1 are denoted by the same reference numerals as those in FIG. 1, and detailed description thereof will be omitted.

In FIG. 3, CRC section 103 performs error detection in units of TTI for each of M types of decoded data using an error detection code such as a CRC code added to the decoded data. . Then, CRC section 103 converts the decoded data for one TTI into data rate information and a CRC result (that is, “0” indicating that no error was detected, or “1” indicating that an error was detected). At the same time, it outputs to the decoded data storage unit 104 and the error number counting unit 301.

The error number counting section 301 counts the number of decoded data in which an error has been detected by the CRC section 103 according to the CRC result. That is, the error number counting section 301
The number of times “1” is output from the CRC result output from the unit 103 is counted.

When the number of errors reaches the number M of data rate candidates, the error number counting section 301 encodes all decoded data of M types of data rates as candidates into the decoded data storage section 104. Is instructed to output to the conversion unit 104. That is, when an error is detected in all of the M types of candidate data rates, the subsequent data rate determination processing is performed on all decoded data having an error.

Thus, even when an error is detected in all of the M types of candidate data rates, the most probable data rate among the M types of candidate data rates is determined. In other words, it is possible to prevent the data rate of the demodulated data from being determined.

On the other hand, when the number of times becomes smaller than the number M of data rate candidates, the error number counting section 301 discards the decoded data in which the error is detected, Is output to the encoding unit 104 only for decoded data for which no is detected. That is, if even one of the candidate decoded data of the M data rates is correct, the subsequent data rate determination processing is performed in the same manner as in the first embodiment.

As described above, according to the present embodiment, even when errors are detected in decoded data at all candidate data rates, it is most reliable to use the decoded data in which those errors are detected. Since it is possible to determine a likely data rate, it is possible to prevent occurrence of a period during which data cannot be reproduced in communication (for example, voice communication) in which errors in decoded data are allowed to some extent.

In the present embodiment, error counter 301 may count the number of times “0” is output from the CRC result output from CRC unit 103. In this case, if the number of errors is 0, the error number counting section 301 outputs to the decoding data storage section 104 all the decoded data of M types of candidate data rates to the encoding section 104. And if the number of times is one or more, instructs the decoded data storage unit 104 to discard decoded data with errors and to output only decoded data without errors to the encoding unit 104. I do.

(Embodiment 4) In the CRC performed by the CRC section 103, if even one bit of the decoded data is erroneous, an error is detected in the decoded data, and conversely, most bits of the decoded data are erroneous. In some cases, no error is detected in the decoded data. That is, the degree of error may be higher in decoded data in which no error is detected than in decoded data in which an error is detected.

In such a case, when the data rate is determined only for the decoded data in which no error is detected as in the first embodiment, the data rate of the decoded data having a high degree of error becomes equal to the data rate of the demodulated data. May be determined. As a result, the decrypted data storage unit 1
From 04, decoded data of an erroneous data rate with a high degree of error is output.

If the decoded data in which no error is detected has a higher degree of error than the decoded data in which the error is detected, the product-sum result (likelihood) calculated by the product-sum operation unit 107 Is larger in decoded data in which an error is detected.

Therefore, in the present embodiment, the decoded data in which an error has been detected is also included in the data rate determination target to determine the data rate.

Further, as the degree of error in the decoded data increases, the product-sum result (likelihood) calculated by the product-sum operation unit 107 becomes smaller. Furthermore, it is extremely rare that no error is detected in decoded data having a high degree of error by the CRC performed by the CRC unit 103 (CRC
About once every 100,000 times).

Therefore, in the present embodiment, a predetermined threshold value is set for the product-sum result (likelihood) in order to determine whether or not the decoded data has a high degree of error but in which no error is detected. Only when the product-sum result of decoded data in which no error is detected does not exceed the predetermined threshold value, decoded data in which an error is detected is included in the data rate determination target.

FIG. 4 is a block diagram showing a configuration of a decoding apparatus according to Embodiment 4 of the present invention. As shown in this figure, the decoding apparatus according to the present embodiment is different from the decoding apparatus shown in FIG. 1 in that the maximum value of the product-sum result detected by data rate determining section 108 and a predetermined threshold value Are further provided. In FIG. 4, the same portions as those in FIG. 1 are denoted by the same reference numerals as those in FIG. 1, and detailed description thereof will be omitted.

In FIG. 4, CRC section 103 performs error detection for each of M types of decoded data in TTI units using an error detection code such as a CRC code added to the decoded data. . Then, CRC section 103 converts the decoded data for one TTI into data rate information and a CRC result (that is, “0” indicating that no error was detected, or “1” indicating that an error was detected). At the same time, the data is output to the decoded data storage unit 104. That is, the decoded data storage unit 104 stores all the candidate decoded data of the M data rates regardless of the presence or absence of an error.

[0092] The encoding section 105 first performs a CRC operation on the decoded data stored in the decoded data storage section 104.
The decoded data for which no error has been detected in section 103 is re-encoded and output to data conversion section 106. The operations of the data conversion unit 106 and the product-sum operation unit 107 are the same as in the first embodiment. That is, first, the product-sum result obtained from the decoded data in which no error is detected is stored in the memory in the product-sum operation unit 107. Data rate judgment unit 1
In 08, the maximum value of the product-sum result is detected, and the maximum value is output to the comparison unit 401.

The comparing section 401 is composed of the data rate determining section 10
The maximum value detected in step 8 is compared with a predetermined threshold value, and if the maximum value exceeds the predetermined threshold value, it is determined that the CRC result is correct. That is, when the maximum value exceeds the predetermined threshold value, comparing section 401 determines that the reliability of the CRC is high and the decoded data for which no error has been detected in CRC section 103 has no actual error. Then, comparing section 108 outputs a signal indicating that the maximum value has exceeded the threshold value to data rate determining section 108. According to this signal, data rate determining section 108 determines the data rate corresponding to the maximum value as the data rate of the demodulated data, and outputs a data rate control signal indicating the determined data rate to decoded data storage section 104. .

That is, when the maximum value of the product-sum result obtained from the decoded data in which no error is detected exceeds a predetermined threshold value, that is, when the reliability of the CRC is high, the same as in the first embodiment. The data rate is determined only for decoded data for which no error has been detected.

On the other hand, when the maximum value of the product-sum result obtained from the decoded data in which no error is detected is equal to or smaller than a predetermined threshold value, that is, when the reliability of the CRC is low, the comparing section 401 The decoded data corresponding to the maximum value is
It is determined that the data is decoded data in which no error is detected despite the high degree of error. Then, in this case, the data rate is determined by including the decoded data in which the error has been detected as the data rate determination target.

That is, when the maximum value of the product-sum result obtained from the decoded data in which no error is detected is equal to or smaller than a predetermined threshold, the comparing section 401 sends the decoded data to the encoding section 105. An instruction is given to re-encode decoded data in which an error is detected by the CRC unit 103 among the decoded data stored in the storage unit 104. In accordance with this instruction, encoding section 105 re-encodes the decoded data in which an error has been detected, and outputs the decoded data to data conversion section 106. The operations of the data conversion unit 106 and the product-sum operation unit 107 are the same as in the first embodiment. Thereby, the product-sum operation unit 10
The memory in 7 stores, in addition to the product-sum result obtained from the decoded data in which no error is detected, the product-sum result obtained from the decoded data in which the error is detected.

Therefore, data rate determining section 108
The maximum value of the product-sum result is detected again for decoded data in which an error has been detected in addition to decoded data in which no error has been detected. Thus, only when the product-sum result of the decoded data for which no error is detected does not exceed the predetermined threshold value, the decoded data for which the error is detected is also included in the data rate determination target.

[0098] Then, data rate determining section 108 determines the data rate corresponding to the maximum value as it is as the data rate of the demodulated data, and outputs a data rate control signal indicating the determined data rate to decoded data storage section 104. . In other words, when the data rate is determined for decoded data in which an error has been detected in addition to decoded data in which no error has been detected, all product-sum results are equal to or less than the threshold value and the data rate is not determined. In order to prevent this, comparison is not performed by the comparison unit 401.

As described above, according to the present embodiment, CR
If the reliability of C is low, the data rate is determined by including decoded data in which an error is detected by CRC as a target.
An accurate data rate can be determined even when there is an error in the CRC result.

Further, according to the present embodiment, an error is detected only when the product-sum result of decoded data for which no error is detected does not exceed a predetermined threshold, that is, when the reliability of CRC is low. Since the decoded data is also included in the data rate determination target, the processing amount and power consumption required for the data rate determination are significantly greater than the data rate determination for all candidate data rates from the beginning. Can be reduced.

Note that the lower the threshold is set, the higher the probability that the data rate is determined for only decoded data for which no error is detected, and conversely, the higher the threshold is set, the more the error is detected. The probability that the data rate is determined including the decoded data is increased. Also, C
If the reliability of RC is high, it is sufficient to determine the data rate only for decoded data in which no error is detected. Therefore, the higher the reliability of the CRC, the lower the threshold is set to emphasize the CRC result, and the lower the reliability of the CRC, the higher the threshold is set to emphasize the product-sum result (likelihood). Good to do.

(Embodiment 5) In general, the better the signal reception quality, the lower the bit error rate. Also, as the bit error rate becomes lower, C
The probability that an error will not be detected by RC is reduced. That is, the lower the bit error rate, the higher the reliability of the CRC. Further, the optimum value of the threshold value set in comparison section 401 differs depending on the reliability of CRC. That is,
The optimum value of the threshold value depends on the reception quality of the signal.

Therefore, in the present embodiment, the threshold value set in comparison section 401 is changed according to the signal reception quality. FIG. 5 is a block diagram showing a configuration of a decoding device according to Embodiment 5 of the present invention. As shown in this figure, the decoding apparatus according to the present embodiment further includes a reception quality measuring section 501 for measuring the reception quality of demodulated data, as compared with the decoding apparatus shown in FIG. In FIG. 5, the same components as those in FIG. 4 are denoted by the same reference numerals as those in FIG.

In FIG. 5, reception quality measuring section 501 has
Measure the reception quality of the demodulated data. Here, a case where SIR (Signal to Interference Ratio) is measured as the reception quality will be described. The reception quality measuring unit 501
A signal indicating the measured SIR is output to comparison section 401.

[0105] Comparison section 401 changes the threshold value set in comparison section 401 according to the SIR measured by reception quality measurement section 501. That is, the comparing unit 401
The higher the IR (ie, the better the reception quality), the lower the threshold. Thereby, the reception quality, that is, C
An optimal threshold value is set according to the reliability of RC.

Although the case has been described with the present embodiment where SIR is used as the reception quality, the method of measuring the reception quality is not particularly limited.

As described above, according to the present embodiment, the threshold value is adaptively changed according to the reception quality.
An optimum threshold value can be set according to the reliability of C. That is, by setting the threshold value lower as the CRC reliability increases, the processing amount and power consumption required for data rate determination can be reduced. Also, C
By setting the threshold higher as the reliability of RC is lower, it is possible to make a data rate determination that emphasizes the product-sum result (likelihood). That is, even when the reliability of the CRC changes over time, an accurate data rate can be determined with the least amount of processing.

Note that the present invention is not limited to the above embodiments. The above embodiments can be implemented in appropriate combinations. For example, the third, fourth, or fifth embodiment can be implemented in combination with the second embodiment.

[0109] The decoding apparatus according to Embodiments 1 to 5 can be mounted on a base station apparatus used in a wireless communication system or a communication terminal apparatus that communicates with the base station apparatus. When mounted, the error rate characteristics are improved by improving the data rate determination accuracy in the base station apparatus and the communication terminal apparatus, so that the data communication quality, voice quality, and the like can be improved.

[0110]

As described above, according to the present invention,
The accuracy of data rate determination can be improved, and the processing amount and power consumption required for data rate determination can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a decoding device according to Embodiment 1 of the present invention.

FIG. 2 is a block diagram showing a configuration of a decoding device according to Embodiment 2 of the present invention.

FIG. 3 is a block diagram showing a configuration of a decoding device according to Embodiment 3 of the present invention.

FIG. 4 is a block diagram showing a configuration of a decoding device according to Embodiment 4 of the present invention.

FIG. 5 is a block diagram showing a configuration of a decoding device according to Embodiment 5 of the present invention.

[Explanation of symbols]

 Reference Signs List 101 Demodulated data storage unit 102 Error correction decoding unit 103 CRC unit 104 Decoded data storage unit 105 Encoding unit 106 Data conversion unit 107 Product-sum operation unit 108 Data rate judgment unit 201 Information bit extraction unit 301 Error count counting unit 401 Comparison unit 501 Receive quality measurement unit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5J065 AA01 AB01 AC02 AD04 AD10 AE06 AF02 AH15 AH21 5K014 AA01 BA10 FA11 GA01 HA10 5K022 EE01 EE31

Claims (13)

[Claims] 1. A decoding means for decoding demodulated data of a soft decision value after demodulation and before decoding at a plurality of candidate data rates, and using decoded data decoded by the decoding means and the demodulated data. Decoding comprising: likelihood calculating means for calculating the likelihood of the data rate for each data rate; and determining means for determining the data rate having the highest likelihood as the data rate of the demodulated data. Device. 2. A likelihood calculating means includes: an encoding unit for re-encoding decoded data; a converting unit for converting re-encoded data in accordance with data conversion performed on a communication partner side; A product-sum operation unit for performing a product-sum operation on the data value of the data and the demodulated data value and then normalizing the product-sum result at the data rate at the time of decoding to obtain a likelihood of the data rate. The decoding device according to claim 1, wherein: 3. The demodulated data is a systematic code composed of an information part and a coded part. The likelihood calculating means includes an extraction unit for extracting the information part from the demodulated data, and a decoded data transmitted from the communication partner. A conversion unit that performs conversion in accordance with the converted data conversion, and after performing a product-sum operation of the converted data value and the value of the information portion, normalizing the product-sum result at a data rate at the time of decoding. The decoding apparatus according to claim 1, further comprising: a product-sum operation unit for calculating a likelihood of a data rate. And detecting means for detecting whether or not there is an error in the decoded data using an error detection code, wherein the likelihood calculating means and the determining means determine only the decoded data for which no error is detected by the detecting means. 4. The decoding apparatus according to claim 1, wherein the decoding is performed as a target. 5. A detecting means for detecting whether or not there is an error in decoded data by using an error detecting code, wherein the likelihood calculating means and the judging means detect all data rates which are candidates by the detecting means. 4. The decoding apparatus according to claim 1, wherein, when an error is detected in the decoded data, processing is performed on the decoded data in which the error is detected. 6. A detecting means for detecting whether there is an error in decoded data using an error detecting code, a maximum likelihood value and a threshold value obtained from decoded data from which no error is detected by said detecting means, Comparison means for comparing the likelihood calculation means and the likelihood calculation means and the determination means, when the maximum value is equal to or less than the threshold value, all the decoded data decoded at a plurality of candidate data rates. 4. The decoding apparatus according to claim 1, wherein the decoding is performed as a target. 7. The decoding apparatus according to claim 6, wherein the comparing means sets the threshold value lower as the reception quality of the demodulated data is better. 8. When a plurality of transport blocks are included in a decoding unit, the detecting means performs error detection only on the last transport block among the plurality of transport blocks, 8. The decoding apparatus according to claim 4, wherein when an error is detected in a transport block, all of the decoded data in the decoding unit is determined to have an error. 9. When a plurality of transport blocks are included in a decoding unit, and when an error is detected in at least half of the plurality of transport blocks, the detecting unit decodes the decoded data of the decoding unit. 8. The decoding device according to claim 4, wherein all of the errors are determined to be erroneous. 10. When a plurality of transport blocks are included in a decoding unit, an error is detected in at least half of the plurality of transport blocks, and an error is detected in a last transport block. 8. The decoding device according to claim 4, wherein when is detected, all of the decoded data in the decoding unit is determined to have an error. 11. A base station device comprising the decoding device according to claim 1. 12. A communication terminal device equipped with the decoding device according to any one of claims 1 to 10. 13. The likelihood of the data rate is determined for each data rate using decoded data obtained by decoding demodulated data of a soft decision value before and after decoding at a plurality of candidate data rates and the demodulated data. And determining the data rate with the highest likelihood as the data rate of the demodulated data.