JP2004320359A - Reception processing method, receiver and terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize small power consumption of an apparatus by omitting useless processes in a process of transmission format combination identifiers and following multiplexed information processes. <P>SOLUTION: A mobile communication transmits a plurality of information with a determined transmission time interval multiplexed and inserted in the same radio frame together with transmission format combination identifiers each inserted in each radio frame, for showing a combination of data lengths within the transmission time interval about the plurality of information. In the mobile communication, the reliability of the transmission format combination identifier extracted from received signals is decided. If the reliability is decided to be high, processes of dividing multiplexed information, decoding each divided information, and detecting the error are executed. If decided to be low, processes of dividing multiplexed information, decoding each divided information and detecting the error, are stopped from execution about the radio frame. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
According to the present invention, a mobile unit that multiplexes and transmits a plurality of information in the same radio frame and inserts a transmission format combination indicator (TFCI) indicating a combination of data lengths of the information into the radio frame and transmits the TFCI. The present invention relates to a reception processing method, a reception device, and a terminal device related to processing of TFCI and multiplex information in communication.
[0002]
[Prior art]
2. Description of the Related Art In the field of mobile communication in recent years, there is a method of multiplexing (multiplexing) information having different quality of service (QoS) such as voice and packet in the same radio frame and transmitting the information over a radio line. As one of such systems, there is a W-CDMA (Wideband Code Division Multiple Access) system which is being studied in 3GPP (Third Generation Partnership Project).
[0003]
FIG. 1 shows an example of a state where information is multiplexed in the W-CDMA system. The radio frame is set to 10 msec (millisecond), and a plurality of pieces of information can be multiplexed in each radio frame as shown in FIG.
[0004]
Here, in the W-CDMA system, a transmission time interval (TTI), which is the shortest data time length that can be decoded, for each of a plurality of pieces of multiplexed information is determined in four predetermined types. It can be set by selecting from among them. These four types of TTIs that can be set are 10 msec, 20 msec, 40 msec, and 80 msec. In the example of FIG. 1, the TTI of the information A is 10 msec, the TTI of the information B is 20 msec, and the TTI of the information C is 10 msec.
[0005]
The number of data in the TTI of each information (hereinafter, the number of data in the TTI is referred to as the data length in the TTI) can be set arbitrarily.
[0006]
In the W-CDMA system, information having different data lengths in the TTI is multiplexed and transmitted as described above. Therefore, it is necessary to transmit information on the data length in the TTI for each of the multiplexed information to the receiving side. Therefore, in the W-CDMA system, as shown in FIG. 2, a transmission format combination identifier (TFCI) is inserted into radio frames of various physical channels as information indicating a combination of data lengths in a TTI of a plurality of pieces of information to be multiplexed. And transmitting. 2 (a) is a downlink DPCH (Dedicated Physical Channel), FIG. 2 (b) is a secondary CCPCH (Common Control Physical Channel), and FIG. 2 (c) is an uplink DPDCH (Dedicated Physical DataChannel / DPCCHedDPC / DPC). Control Channel), and FIG. 2D shows each structure of the radio frame of the random access message part. Since these are known structures defined in the W-CDMA system, their details will not be described in detail. In each radio frame, one frame is composed of 15 slots, and multiplex information (data) and TFCI are inserted in each slot.
[0007]
In the TFCI, the data length in the TTI of each information is indicated not by the data length itself but by the value of a transmission format (Transport Format) TF (normally, the number of the transmission format) of each information. A TFCI value is determined for a combination of transmission format values of a plurality of multiplexed information. FIG. 3 shows, for example, when two pieces of information (information 1 and information 2) having QoS are multiplexed, a value of a transmission format TF indicating a data length in a TTI of each information and a TFCI value are shown. 4 shows an example of an associated mapping table 300. TF1 and TF2 are TF values of information 1 and information 2, respectively. Here, TF1 indicates that information 1 has 64 types of data lengths in TTI from 0 to 63, and TF2 indicates that information 2 has 4 types of data lengths in TTI from 0 to 3. Is shown.
[0008]
The transmission channel values TF1 and TF2 of each information are notified to the receiving side separately by the control channel together with the mapping table 300 of FIG. 3 by the control channel. FIG. 4 shows an example of correspondence tables 401 and 402 between the TF value of each information and the data length in the TTI, in the case of the transmission format values TF1 and TF2 of the information 1 and the information 2 and the data length in the TTI. . Although the case where the number of pieces of information is 2 in the mapping table 300 and the correspondence tables 401 and 402 has been described, the number is not limited to this and may be 3 or more.
[0009]
From the above, on the receiving side of the W-CDMA system, the TFCI is extracted from the received data, and the extracted TFCI is decoded by the TFCI decoder to obtain the TFCI value. The TF value of each information can be calculated based on the mapping table 300 indicating the correspondence between the existing TFCI and the TF value. Furthermore, the TTI data length corresponding to the calculated TF value of each information can be calculated based on the correspondence tables 401 and 402 indicating the correspondence between the TF value of each information and the data length within the TTI. As a result, the received multiplexed information is divided into individual information (information 1 and information 2 in the above example), and each data can be decoded.
[0010]
In the W-CDMA system, the TFCI is 10-bit information, and 1024 combinations of TF values can be indicated for a plurality of multiplexed information. If the number of combinations of TF values for a plurality of pieces of information to be multiplexed can be represented by less than 10 bits, TFCI inserts “0” on the MSB (Most Significant Bit: most significant bit) side. To 10 bits.
[0011]
The TFCI is encoded on the transmission side for error correction. The encoding method of the TFCI bit in the 3GPP standard is as follows.
[0012]
The 10 information bits of the TFCI input to the encoder are a9, a8, a7, a6, a5, a4, a3, a2, a1, a0 (where a9 is the MSB, a0 is the LSB (Least Significant Bit: most significant bit). ), The code word bi (i = 0,..., 31) of the output of the encoder can be obtained by equation (1) in FIG. Here, Mi, n in Expression (1) is a coefficient given by the matrix table 600 in FIG.
[0013]
According to the 3GPP standard, the TFCI field provided in one radio frame shown in FIG. 2 has 30 bits, and among the 32 bits of the code word bi, b30 and b31 are deleted (that is, puncture processing). ) To 30 bits, and then insert it into the TFCI field of the radio frame shown in FIG. After that, the data of the radio frame shown in FIG. 2 is QPSK-modulated, spread-spectrum-modulated, and transmitted.
[0014]
The data of the radio frame as described above is received at a base station or a mobile station (mobile terminal), and first, a TFCI codeword is extracted from a TFCI field and decoded as described later. By referring to the tables 300, 401, and 402 (FIGS. 3 and 4) previously sent by the control channel from the value of the TFCI of the decoding result, the TTI for each of the multiplexed information is determined. The data length is detected, and each of the multiplexed information is separated and decoded based on the detection result.
[0015]
[Problems to be solved by the invention]
As described above, in order to separate and decode each of a plurality of pieces of multiplexed information, it is necessary to correctly determine a TFCI value. However, in a poor communication environment, this TFCI value may be incorrect. There is. In that case, the subsequent division of the multiplexed information using the TFCI value and the decoding processing of each divided information are useless. In particular, in a battery-driven portable terminal device or the like, the battery capacity is reduced by useless processing.
[0016]
SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to reduce the consumption of the apparatus by omitting the execution of useless processing in the processing of a transmission format combination identifier and the processing of subsequent multiplexed information. It is an object of the present invention to provide a reception processing method, a reception device, and a terminal device capable of realizing power consumption.
[0017]
[Means for Solving the Problems]
In the reception processing method according to the present invention, when multiplex transmission of a plurality of information items each having a transmission time interval defined in the same radio frame, a combination of data lengths within the transmission time interval for each of the plurality of information items is provided. This is a method for receiving a transmission format combination identifier and multiplexed information in mobile communication in which a transmission format combination identifier indicating the above is inserted into each radio frame and transmitted. In this method, a step of dividing multiplexed information from a received signal, a step of decoding each divided information, and a step of detecting an error; a step of decoding a transmission format combination identifier extracted from the received signal; Determining the reliability of the result; and, when the reliability is determined to be low, stopping the execution of the processing of dividing the multiplexed information, decoding each of the divided information, and detecting an error for the radio frame. And
[0018]
At the stage where the value of the transmission format combination identifier is obtained, if the reliability of the value is known, it is possible to determine whether to divide the multiplexed information and decode the divided information according to the reliability. If the reliability is determined to be low, the execution of useless processing is omitted by suspending the division of the multiplexed information, the decoding of the divided information, and the execution of the error detection for the radio frame. Thereby, the power consumption of the device is reduced.
[0019]
The receiving apparatus according to the present invention, when multiplexing and transmitting a plurality of information items each having a transmission time interval defined in the same radio frame, sets a combination of a data length within the transmission time interval for each of the plurality of information items. This is a receiving device that performs processing for receiving a transmission format combination identifier and multiplexed information in mobile communication in which the transmission format combination identifier shown is inserted into each radio frame and transmitted. The receiving device receives a signal including the plurality of pieces of information and the transmission format combination identifier, a decoding unit that decodes a transmission format combination identifier extracted from the reception signal, and a signal obtained by the decoding unit. Determining means for determining the reliability of the transmission format combination identifier; processing means for performing division of multiplexed information, decoding of each of the divided information, and error detection; and determining that the reliability is low, And control means for suspending the division of multiplexed information, the decoding of each of the divided information, and the execution of error detection processing for the radio frame.
[0020]
When the determination unit determines that the reliability of the transmission format combination identifier obtained by the decoding unit is low, the control unit performs division of multiplexed information, decoding of each divided information, and error detection processing for the radio frame. Abort the execution of. As a result, execution of useless processing is omitted, thereby reducing the power consumption of the device.
[0021]
The determining means includes, for example, a correlation value determining means for determining a degree of correlation between the obtained transmission format combination identifier and a plurality of the candidate values, and the correlation value determining means includes a correlation value of at least two candidate values. Satisfies a specific condition, it is determined that the reliability of the decoding result is high, and if it does not satisfy the specific condition, it is determined that the reliability is low. Normally, in a communication environment with little noise, the difference (or ratio) between the maximum value of the first published value and other values becomes large, and conversely, in an environment with much noise, the difference (or ratio) becomes small.
[0022]
Therefore, the specific condition is: (1) the maximum value of the absolute value of the correlation value of the plurality of candidate values of the transmission format combination identifier and the second largest value, and (2) the plurality of candidate values of the transmission format combination identifier. And (3) the maximum absolute value of the correlation value of the plurality of candidate values of the transmission format combination identifier and the maximum value of the absolute value of the correlation value other than the maximum value. The determination can be made based on one of the values of other correlation values, and (4) the variance or the standard deviation of the correlation values of the plurality of candidate values of the transmission format combination identifier.
[0023]
The receiving device according to the present invention can be used as a component of a terminal device.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0025]
FIG. 7 shows a configuration example of a wireless communication terminal as a mobile station in which the receiving device according to the present invention is used. The signal from the base station is processed by each receiving block shown by the RF receiving unit 113, the demodulation unit 114, and the decoding unit 115 from the antenna 111 via the duplexer 112, and is passed to the data processing unit 116. The data processing unit 116 performs various data processing required by the terminal. The user interface unit 117 connected to the data processing unit 116 is connected to an input unit 118a including operation keys and a display unit 118b including a display device, and manages an interface with a user. The received audio signal is processed by the audio processing unit 122 and output from the speaker 124 as audio. The sound input from the microphone 123 is processed by the sound processing unit 122 and input to the encoding unit 121 as a sound signal. The user interface processing unit 117, the input unit 118a, and the output unit 118b constitute a data input / output unit in the present invention, and the audio processing unit 122, the microphone 123, and the speaker 124 constitute an audio input / output unit. The signal to the base station is processed in each transmission block represented by coding section 121, modulation section 120, and RF transmission section 119, and is transmitted via duplexer 112 and antenna 111.
[0026]
Although the configuration of the base station includes some unnecessary elements, it is basically the same as the configuration of the mobile station (wireless communication terminal) and is not shown.
[0027]
FIG. 8 is a diagram showing a configuration of the receiving apparatus according to the present embodiment. This receiving device corresponds to a part of the decoding unit 115 in FIG. This apparatus includes a multiplexed information / TFCI separation unit 21 for separating multiplexed information and TFCI from a received signal, and receives multiplexed information from the multiplexed information / TFCI separation unit 21 to divide the multiplexed information and each of the divided information. A TFCI from the multiplexed information / TFCI separation unit 21 and decodes the TFCI, and detects an error in the information decoded by the data decoding unit 22. , And a control unit 24 for controlling peripheral functions.
[0028]
The multiplexed information / TFCI separation unit 21 divides the received data into a multiplexed information part and a TFCI part based on the information (transmission data format) from the control unit 24 from the received signal after spectrum despreading, Is supplied to the data decoding unit 22 and the TFCI is supplied to the TFCI decoding unit 25.
[0029]
The data decoding unit 22 divides the multiplexed information and decodes the divided information based on the information (data length in TTI, TTI, etc.) from the control unit 24. Then, the data decoding unit 22 supplies the decoded information to the error detection unit 23. The error detection unit 23 performs error detection on the information from the data decoding unit 22 and outputs the detection result.
[0030]
Prior to the multiplexing information, the control unit 24 analyzes the control information transmitted through the control channel, and transmits the transmission data format, the transmission time interval of each of the multiplexed information, the TFCI value and the TF value of each information. , And correspondence tables 401 and 402 between the TF value of each information and the data length in the TTI are detected. The control unit 24 notifies the TFCI decoding unit 25 of the number of possible TFCI values (TFCS size) known from the correspondence table between the TFCI value and the TF value of each information, and a threshold for determining reliability. Then, the TFCI is decoded.
[0031]
The TFCI decoding unit 25 executes the TFCI decoding process under the control of the control unit 24 as described above. If the reliability is high, the TFCI value of the decoding result is low, and if the reliability is low, the reliability is low. To the control unit 24.
[0032]
The control unit 24 includes a correspondence table 300 (FIG. 3) between the TFCI value from the TFCI decoding unit and the TFCI value and the TF value of each information, and a correspondence table between the TF value of each information and the data length in the TTI. From 401 and 402 (FIG. 4), the data length in the TTI of each information is obtained, and this value and the value calculated from this value are transmitted to the data decoding unit 22 to divide the multiplexed information and decode each divided information. Let it do.
[0033]
However, when notified by the TFCI decoding unit 25 that the reliability of the TFCI is low, the control unit 24 controls the data decoding unit 22 to stop the division of the multiplexed information and the decoding of the divided information. Further, it controls the error detection unit 23 to stop error detection, and forcibly makes a report that "there is an error" as an error determination result.
[0034]
When it is notified that the reliability of the TFCI is low, the division of the multiplexed information and the decoding of the divided information are stopped, as can be seen from the graph of FIG. 9, indicating the S / N ratio after code spreading. This is because if DPCH_Ec / Ioc is low and the error rate (error rate) of TFCI increases, the data block error rate increases as it is more certain that data cannot be decoded properly. The measurement conditions of this graph are as follows.
channel condition: static
TFCS size: 16
TFCI bit / frame: 30
TTI: 20ms
Data decode: Viterbi R = 1/3
Data function: 14.7%
Here, TFCS is an abbreviation of Transport Format Combination Set, and TFCS size is the number of possible values of TFCI. For example, when the TFCI can take a value from 0 to 15, the TFCI size is 16.
[0035]
In an environment such as TTI: 10 ms and TFCS size: 1024, the characteristics of the TFCI error rate deteriorate, and the characteristics may be similar to those of the data block error. However, since the maximum value of TFCS size is defined by the mobile station and is usually lower than 1024 such as 48 or 32, the two specifications are closer to each other than shown in FIG. is there.
[0036]
As an internal configuration of the TFCI decoding unit 25, a configuration as shown in FIG. 10 can be considered. In this configuration, the 30-bit TFCI codeword extracted by the multiplexed information / TFCI separation unit 21 in FIG. 8 is input to the depuncture processing unit 251. The depuncture processing unit 251 performs a process of inserting 32 bits into the end of the input TFCI codeword to make it 32 bits. The TFCI code word after inserting two bits of 0 is defined as Ri (i = 0, 1,..., 31).
[0037]
The 32-bit TFCI code word Ri is supplied to the mask release processing unit 252. The mask release processing unit 252 performs the mask release processing corresponding to the mask processing by Mi, 6 to Mi, 9 of the coefficients Mi, n of the matrix table 600 shown in FIG. That is, Mi, 6 to Mi, 9 of the coefficients Mi, n are mask codes, and the mask release processing unit 252 performs a process of removing the mask using the mask codes Mi, 6 to Mi, 9. Specifically, the processing is performed according to the following procedures (1) and (2).
[0038]
(1) Select a value that can be a candidate for the upper 4 bits (a9, a8, a7, a6) of the TFCI corresponding to the mask codes Mi, 6 to Mi, 9. For example, when the TFCI can take a value from 0 to 255, the value of the TFCI can be represented by 8 bits, and therefore the 2 most significant bits a9 and a8 of the 10-bit TFCI are “0”. . In this case, since a7 and a6 can take "0" or "1", there are four patterns.
[0039]
{Circle around (2)} Formula (2) shown in FIG. 5 is calculated, and if the value EX = “1” of the calculation result, the sign of Ri is inverted, and if EX = “0”, Ri is left as it is. This is performed for all of i = 0, 1,..., 31.
[0040]
Next, Fast Hadamard Transform (FHT) (FHT: Fast Hadamard Transform) is performed on the data whose mask has been removed by the mask release processing unit 252, and a correlation value is obtained. The first Hadamard transform is a calculation method for efficiently multiplying unmasked data by a Hadamard matrix.
[0041]
The above two processes (1) and (2) are performed on all possible patterns as candidates for the upper 4 bits (a9, a8, a7, a6) of the TFCI. In the example of FIG. 3 in which the above-mentioned TFCI can take a value of 0 to 255, four types of patterns can be taken as candidates for bits a9, a8, a7, and a6 as described above. The first Hadamard transform process is repeated four times in total. If the value of TFCI is 512 or more and all 10 bits are used, 16 patterns can be taken as candidates for the bits a9, a8, a7, and a6, so that the mask release processing and the first Hadamard transform are performed. The process is repeated a total of 16 times.
[0042]
All of the results of the above-described multiple processes of the mask release process and the first Hadamard transform process are supplied to the correlation value determination unit 254. The correlation value determination unit 254 compares the absolute values of all the correlation values output from the first Hadamard transform unit 253 a plurality of times, and detects the maximum value, thereby obtaining the transmitted TFCI value. . (However, as described above, in order to use the TFCI value thus obtained, the value needs to have high reliability.)
[0043]
Based on the TFCI value thus obtained, the mapping table 300 as shown in FIG. 3 and the tables 401 and 402 shown in FIG. As a result, the data length in the TTI of the multiplexed information is known, and the multiplexed information can be divided into respective pieces of information and decoded.
[0044]
Note that the number of repetitions of the mask release processing unit 252 and the FHT unit 253 is determined by the information on the number of possible values of the TFCI (TFCS size) from the control unit 24.
[0045]
Each processing unit in FIG. 10 may have an independent hardware configuration, or a part or all of the processing configuration in FIG. 10 may be configured by software.
[0046]
The threshold value information from the control unit 24 is used by the correlation value determination unit 254 to determine reliability, as described above. Various methods can be considered for the determination. For example, the reliability can be determined by comparing the maximum absolute value of the correlation value with the second largest value. In this case, if the second largest value exceeds 75% of the maximum value, it is determined that the reliability is low. It is also possible to compare the maximum absolute value of the correlation value with a correlation value other than the maximum value (for example, an average value). Similarly, in this case, if the average value exceeds 50% of the maximum value, it is determined that the reliability is low. It is also possible to determine the reliability by comparing the maximum value of the absolute value of the correlation value with another correlation value (for example, an average value) including the maximum value. Furthermore, it is also possible to determine the reliability using the variance and the standard deviation (positive square root of the variance) of the correlation values for all TFCIs. Other than these methods, any method can be used as long as it can confirm that the absolute value of the correlation value of a specific TFCI value is larger than the absolute value of the correlation value of another TFCI value by a predetermined degree or more. Can be used.
[0047]
FIG. 11 is a graph showing an example of the TFCI correlation value. The horizontal axis in the figure indicates the TFCI value, and the vertical axis indicates the correlation value. In this example, the true value of TFCI is 4. As can be seen from this figure, the correlation value of the true value of TFCI decreases as DPCH_Ec / Ioc, which indicates the S / N ratio after code spreading, decreases. It can be seen that for TFCI values other than the true value, even if DPCH_Ec / Ioc changes, the correlation value does not change much. Therefore, the above-described method can be used to determine the reliability of the TFCI value (decoding result) obtained by the TFCI decoding unit 25.
[0048]
Next, the operation of FIG. 8 will be described with reference to the flowchart of FIG.
[0049]
First, control information transmitted through a control channel is received (S101). The received control information includes a transmission data format, information of a mapping table 300 between TFCI and TF values of a plurality of information (FIG. 3), and a mapping table of each TF value of a plurality of information and a data length in a TTI. Information 401 and 402 (FIG. 4) and transmission time intervals of each of a plurality of pieces of information are included.
[0050]
Next, the multiplex information and the TFCI are received (S102). The TFCI decoding unit 25 performs TFCI decoding using information on the number of values (TFCS size) that the TFCI can take from the control unit 24 and obtains a correlation value for each TFCI value (S103).
[0051]
Next, the TFCI decoding unit 25 determines the reliability of the TFCI using the threshold value from the control unit 24 as described above (S104).
[0052]
If it is determined in step S104 that the reliability is high, the TFCI decoding unit 25 reports the TFCI value with the maximum absolute value of the correlation value to the control unit 24 (S105). Next, the control unit 24 uses the TFCI value, the correspondence table 300 between the TFCI value and the TF value of each information, and the correspondence tables 401 and 402 between the TF value and the data length in the TTI for each information, to determine whether the TTI of the terminated information The data length is obtained, and the necessary parameters are calculated by the data decoding unit 22 from this value (S106). Here, "terminated" indicates a state in which all pieces of information up to the last data of the transmission time interval have been received.
[0053]
Next, the control unit 24 passes the obtained parameters to the data decoding unit 22, and divides the multiplexed information and decodes the terminated information among the divided information (S107). Next, error detection is performed on the information resulting from decoding by the error detection unit 23 (S108).
[0054]
If it is determined in step S104 that the reliability is low, the TFCI decoding unit 25 reports to the control unit 24 that the reliability of the TFCI is low (S109). In response, the control unit 24 controls the data decoding unit 22 to stop division of the multiplexed information and decoding of the divided information (S110), and also controls the error detection unit 23 to stop error detection. Then, a report that "there is an error" is made as an error determination result (S111). As a result, the subsequent processing for the wireless frame is stopped (it is highly likely that correct data cannot be obtained even if the processing is continued). Such a radio frame that is not received normally can be dealt with by a conventional method. For example, in the case of packet communication, it is possible to cope with a retransmission request or the like for the packet, and in the case of voice communication, it is possible to cope with the output of conforming noise.
[0055]
After step S108 or step S111, the process proceeds to step S112, in which it is determined whether reception of all data has been completed. If reception of all data has been completed, this processing routine ends. If reception of all data has not been completed, the process returns to step S102, and the processing of the next frame is performed.
[0056]
Although the preferred embodiment of the present invention has been described above, various modifications and changes are possible. For example, in FIG. 8, the determination of the correlation value is performed by the TFCI decoding unit 25, but may be performed by another unit (for example, the control unit 24).
[0057]
【The invention's effect】
According to the present invention, in the decoding of the transmission format combination identifier, the reliability information of the decoding result is obtained, and when the reliability is low, the division of the multiplexed information and the decoding of each of the divided information are stopped. Low power consumption is possible. This is particularly advantageous (but not limiting) when the present invention is applied to a battery-powered terminal device.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining multiplex information in a 3GPP standard W-CDMA system.
FIG. 2 is a diagram for explaining a transmission data format in the 3GPP standard W-CDMA system.
FIG. 3 is a diagram illustrating an example of a mapping table of TFCI and respective TF values of multiplex information.
FIG. 4 is a diagram illustrating an example of a correspondence table between each TF value of multiplexed information and a data length in a TTI.
FIG. 5 is a diagram for explaining a method of encoding TFCI bits in the 3GPP standard.
FIG. 6 is a diagram showing a matrix table for explaining coefficients Mi, n used for encoding TFCI.
FIG. 7 is a block diagram illustrating a configuration example of a wireless communication terminal as a mobile station using the receiving device according to the present invention.
FIG. 8 is a block diagram illustrating a configuration example of a receiving device to which the present invention has been applied.
FIG. 9 is a graph showing the relationship between the TFCI and the data error rate, and the S / N ratio.
FIG. 10 is a diagram illustrating an example of the internal configuration of a TFCI decoding unit in FIG. 8;
FIG. 11 is a graph showing an example of a TFCI correlation value.
FIG. 12 is a flowchart for describing processing of received data in the embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... De puncturing processing part, 2 ... Mask release processing part, 3 ... Fast Hadamard (FHT) conversion part, 4 ... Correlation value determination part, 21 ... Multiplex information / TFCI separation part, 22 ... Data decoding part, 23 ... Error detector, 24 ... Controller, 25 ... TFCI decoder

Claims (5)

When multiplexing transmission of a plurality of pieces of information for which transmission time intervals are determined in the same radio frame, a transmission format combination identifier indicating a combination of data lengths within the transmission time interval for each of the plurality of pieces of information is assigned to each of the pieces of information. A reception processing method of a transmission format combination identifier and multiplex information in mobile communication to be inserted and transmitted in a radio frame,
Division of the multiplexed information from the received signal, decoding each of the divided information and performing each process of error detection;
Decoding the transmission format combination identifier extracted from the received signal;
Determining the reliability of the decoded result;
When it is determined that the reliability is low, for the radio frame, division of multiplex information, decoding of the divided information and stopping the execution of each process of error detection,
A reception processing method comprising: When multiplexing transmission of a plurality of pieces of information for which transmission time intervals are determined in the same radio frame, a transmission format combination identifier indicating a combination of data lengths within the transmission time interval for each of the plurality of pieces of information is assigned to each of the pieces of information. A receiving apparatus for performing a reception process of a transmission format combination identifier and multiplex information in mobile communication that transmits and inserts in a radio frame,
Receiving means for receiving a signal including the plurality of information and the transmission format combination identifier,
Decoding means for decoding the transmission format combination identifier extracted from the received signal;
Determining means for determining the reliability of the transmission format combination identifier obtained by the decoding means;
Processing means for performing division of multiplexed information, decoding of each divided information and error detection processing,
When the reliability is determined to be low, for the radio frame, division of multiplexed information, control means for stopping the execution of each process of decoding and error detection of each divided information,
A receiving device comprising: The determining means includes a correlation value determining means for determining a degree of correlation between the obtained transmission format combination identifier and a plurality of the candidate values, and the correlation value determining means determines that a correlation value of at least two candidate values is a specific value. The receiving apparatus according to claim 2, wherein when the condition is satisfied, the reliability of the decoding result is determined to be high, and when the specific condition is not satisfied, the reliability is determined to be low. The specific condition includes: (1) the maximum value of the absolute value of the correlation value of the plurality of candidate values of the transmission format combination identifier and the second largest value, and (2) the correlation of the plurality of candidate values of the transmission format combination identifier. (3) the maximum of the absolute values of the correlation values of the plurality of candidate values of the transmission format combination identifier, and other correlation values including this maximum value. 4. The receiving apparatus according to claim 3, wherein the determination is made based on one of a correlation value, and (4) a variance or a standard deviation of correlation values of the plurality of candidate values of the transmission format combination identifier. A receiving device and a transmitting device that performs wireless communication, a data processing unit that performs processing of transmission and reception data, a voice input and output unit that performs input and output of voice, a terminal device including a data input and output unit that performs input and output of data,
The receiving device,
When multiplexing transmission of a plurality of pieces of information for which transmission time intervals are determined in the same radio frame, a transmission format combination identifier indicating a combination of data lengths within the transmission time interval for each of the plurality of pieces of information is assigned to each of the pieces of information. A receiving device that performs reception processing of a transmission format combination identifier and multiplex information in mobile communication that transmits and inserts in a radio frame,
Receiving means for receiving a signal including the plurality of information and the transmission format combination identifier,
Determining means for determining the reliability of the transmission format combination identifier extracted from the received signal,
Processing means for performing division of multiplexed information, decoding of each divided information and error detection processing,
When the reliability is determined to be low, for the radio frame, division of multiplexed information, control means for stopping the execution of each process of decoding and error detection of each divided information,
A terminal device comprising:

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