JP3859477B2 - Data communication method and mobile device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a data communication method using a hybrid automatic repeat request (H-ARQ) method, andMobileAbout.
[0002]
[Prior art]
Conventionally, as a data communication system using a hybrid automatic retransmission request method, for example, there is one disclosed in Japanese Patent Laid-Open No. 8-88620. FIG. 9 is a block diagram showing the configuration of the data communication system disclosed in the publication. This conventional data communication system includes a base station device 900 and a mobile device 920.
[0003]
The base station apparatus 900 includes a blocking unit 901, an error detection data adding unit 902, an encoding unit 903, a number adding unit 904, a first storage unit 905, a first control unit 906, and a transmitting unit 907. , A duplexer 908, an antenna 909, and a receiving unit 910. On the other hand, the mobile device side 920 includes an antenna 921, a duplexer 922, a receiving unit 929, a number extracting unit 924, a second storage unit 925, a decoding unit 926, an error detecting unit 927, and a second control unit. 928 and a transmission unit 923.
[0004]
The blocking unit 901 divides the input information bit data into a predetermined number of blocks and outputs the result. Error detection data adding section 902 adds error detection data to the blocked information bit data output from blocking section 901 and outputs the result. The encoding unit 903 performs error correction encoding on the blocked information bit data to which the error detection data is added by the error detection data addition unit 902, and converts it into a plurality of frame data (eg, n-A, n-B, n-C). Divide and output.
[0005]
The number adding unit 904 adds a block number (referred to as n) and a frame number (referred to as A, B, and C) to the frame data nA, nB, and nC output from the encoding unit 903. . That is, the numbers 1-A, 1-B, and 1-C are included in the frame data when the first blocked information bit data blocked by the blocking unit 901 is framed by the encoding unit 903. The numbers 2-A, 2-B, and 2-C are added to the frame data when the second blocked information bit data is framed. The n-A, n-B, and n-C numbers are added to the frame data when the n-th blocked information bit data is framed.
[0006]
The first storage unit 905 stores frame data nA, nB, and nC to which a block number and a frame number are added. The first control unit 906 reads the frame data nA, nB, and nC stored in the first storage unit 905 in the order of block number and frame number. In addition, the first control unit 906 performs control to read the frame data n-A, nB, and nC according to the response of the second control unit 928 of the mobile device 920. The frame data nA, nB, and nC read from the first storage unit 905 are input to the transmission unit 907 and converted into radio frequency signals. Then, it is transmitted from the antenna 909 through the duplexer 908.
[0007]
When the first control unit 906 receives a NACK signal transmitted from the mobile device 920 (that is, a signal indicating that there is an error in the transmitted blocked information bit data), the first control unit 906 indicates a block indicated by the NACK signal. The frame data of the untransmitted frame number of the number is transmitted. On the other hand, when an ACK signal indicating that there is no error in the blocked information bit data is received, frame data of the next block number is transmitted.
[0008]
On the other hand, in the mobile device 920, the number extraction unit 924 extracts the block number and the frame number from the frame data n-A, n-B, n-C sent from the base station apparatus 900 side, and the frame data n Output with -A, n-B, and n-C. The second storage unit 925 stores frame data nA, nB, and nC for each block number and frame number extracted by the number extraction unit 924. The decoding unit 926 decodes the frame data nA, nB, and nC read from the second storage unit 925 at an encoding rate corresponding to the number of frames.
[0009]
The error detection unit 927 performs error detection using the error detection data of the frame data nA, nB, and nC decoded by the decoding unit 926. The second control unit 928 performs control to read the frame data n-A, n-B, and n-C stored in the second storage unit 925, and when an error is not detected by the error detection unit 927 Control is performed to transmit an ACK signal and to transmit a NACK signal when an error is detected.
[0010]
Next, the operation of the data communication system configured as described above will be described.
In the base station apparatus 900, the first control unit 906 reads out the first frame data 1-A of the first block indicated by reference numeral 1000 in FIG. 10 from the first storage unit 905, and is indicated by a solid line arrow. To the mobile device 920. The transmitted frame data 1-A is received by the receiving unit 929 of the mobile device 920. Then, the block number and the frame number are extracted from the frame data 1-A by the number extraction unit 924 of the mobile device 920. The extracted block number and frame number are stored in the second storage unit 925 as indicated by reference numeral 1001.
[0011]
The frame data 1-A stored in the second storage unit 925 is read out under the control of the second control unit 928 and input to the decoding unit 926. When the frame data 1-A is input to the decoding unit 926 and decoded, information bit data to which parity check data is added is output.
[0012]
This information bit data is input to the error detection unit 927, and error detection is performed by CRC (Cyclic Redundancy Check) calculation using parity check data. If no error is detected by this calculation, the second control unit 928 sends a 1-ACK signal indicating that there is no error in the first block data to the base station apparatus 900 as indicated by a dashed arrow 1002 in FIG. Send to. Then, after transmitting the 1-ACK signal, the frame data 1-A stored in the second storage unit 925 is erased. When this error is not detected, information bit data of the same first block that is blocked by the blocking unit 901 of the base station apparatus 900 is output from the error detection unit 927.
[0013]
When the 1-ACK signal is transmitted from the mobile device 920 and received by the base station apparatus 900, the first control unit 906 transmits the next second block frame indicated by reference numeral 1003 in FIG. 10 from the first storage unit 905. Data 2-A is read and transmitted to the mobile device 920. When this data 2-A is received by the mobile device 920, the block number and frame number are extracted by the number extraction unit 924. The extracted block number and frame number are stored in the second storage unit 925 as indicated by reference numeral 1004.
[0014]
The frame data 2-A stored in the second storage unit 925 is decoded by the decoding unit 926 and the error detection unit 927 performs error detection. If an error is detected, the second control unit 928 stores the frame data 2-A as it is, and displays a 2-NACK signal indicating that the data of the second block is incorrect as a broken-line arrow shown in FIG. As indicated by 1005, the data is transmitted toward the base station apparatus 900.
[0015]
When the 2-NACK signal is received by the base station apparatus 900, the first control unit 906 of the base station apparatus 900 transmits a different frame of the second block that is transmitted from the first storage unit 905 and indicated by reference numeral 1006 in FIG. Frame data 2-B is read out and transmitted to the mobile device 920.
[0016]
After the transmitted frame data 2-B is received by the mobile device 920, the block number and the frame number are extracted by the number extracting unit 924, and the second frame data 2-B is obtained as indicated by reference numeral 1007. Stored in the storage unit 925. The frame data 2-B stored in the second storage unit 925 is read together with the frame data 2-A already stored in the second storage unit 925 and decoded by the decoding unit 926. As a result, decoding is performed with a higher correction capability (lower coding rate) than when decoding was performed only with the previous frame data 2-A.
[0017]
Then, the error detection unit 927 performs error detection based on the parity check data added to the decoded information bit data. In this error detection, if an error is detected again, a 2-NACK signal is transmitted to the base station apparatus 900 as indicated by a dashed arrow 1008 shown in FIG. When the signal is received, the first control unit 906 of the base station apparatus 900 reads out the frame data 2-C of the second frame, which is transmitted in the first block indicated by reference numeral 1009 in FIG. Transmit to the mobile device 920. The transmitted frame data 2-C is read together with the frame data 2-A and 2-B already stored in the second storage unit 925 in the same manner as the procedure when the frame data 2-B is received, Decoding is performed by the decoding unit 926.
[0018]
Then, the error detection unit 927 performs error detection based on the parity check data added to the decoded information bit data. When no error is detected, the second control unit 928 sends a 2-ACK signal indicating that there is no error in the data of the second block to the base station apparatus 900 as indicated by a broken line arrow 1011 in FIG. The frame data 2-A, 2-B, and 2-C stored in the first storage unit 905 are deleted while being transmitted. The error detection unit 927 outputs information bit data of the same second block that is blocked by the blocking unit 901 of the base station apparatus 900.
[0019]
Thereafter, the first control unit 906 of the base station apparatus 900 sequentially receives the frame data 3 from the first storage unit 905 according to the ACK signal or NACK signal returned from the second control unit 928 of the mobile device 920 as described above. -A ... is read and transmitted to the mobile device 920.
[0020]
By the way, as described above, when an error is detected as a result of error detection on the frame data 2-A, 2-B, 2-C decoded by the decoding unit 926 of the mobile device 920, the second of the mobile device 920 is detected. The control unit 928 stores the frame data 2-A, 2-B, 2-C as it is in the second storage unit 925, and transmits a 2-NACK signal indicating that the data of the second block is incorrect to the base station Transmit to device 900. When the 2-NACK signal is received by the base station apparatus 900, the first control unit 906 reads the first frame data 2-A of the second block from the first storage unit 905 and directs it to the mobile device 920. Send.
[0021]
The transmitted frame data 2-A is received by the mobile device 920, and after its block number and frame number are extracted by the number extraction unit 924, the second storage is different from the previously stored frame data 2-A. Stored in the storage area of the unit 925. After the retransmitted frame data 2-A is stored in the second storage unit 925, it is read together with the previously stored frame data 2-A, 2-B, 2-C under the control of the second control unit 928. That is, four frame data 2-A, 2-B, 2-C, and 2-A are read out. Then, the read four frame data 2-A, 2-B, 2-C, and 2-A are input to the decoding unit 926, and decoding is performed at a lower coding rate.
[0022]
In this way, since the data transmitted this time and the same data as this data but transmitted earlier and having an error are used, the coding rate is lowered according to the number of retransmissions. As a result, the error correction capability is increased depending on the number of retransmissions, so that it is possible to suppress a rapid increase in the number of retransmissions due to deterioration of the characteristics of the communication path.
[0023]
[Problems to be solved by the invention]
However, the above-described conventional data communication system has the following problems.
That is, when all frame data in the block data with the same block number is transmitted from the base station apparatus and there is no untransmitted frame data, if there is a retransmission request from the mobile station, retransmission is performed from the frame data of the first frame number. However, the reliability of the previous frame data is poor, and if the error cannot be removed even if it is used for maximum ratio combining, the number of retransmissions will inevitably increase.
[0024]
For example, among the frame data 1-A, 1-B, and 1-C obtained by dividing one block data into three, the reliability of the frame data 1-A and 1-B is low, and these are used for the maximum ratio combining. Even if the error cannot be removed, the reliability of the frame data 1-C is high, and when the error can be removed when this is used for the maximum ratio combining, the error can be removed with 3 retransmissions. It will be possible.
[0025]
As described above, when retransmitting frame data with low reliability first, the number of retransmissions increases, leading to a decrease in throughput in the base station apparatus. In particular, when there are a large number of mobile devices that communicate with the base station apparatus, an increase in the number of retransmissions is not preferable because the time allocated to each mobile device is reduced.
[0026]
  The present invention has been made in view of the above points, and a data communication method that can be performed a minimum number of times when frame data needs to be retransmitted, andMobileThe purpose is to provide.
[0027]
[Means for Solving the Problems]
  The data communication method of the invention according to claim 1 comprises:The receiving side receives a known signal that is always transmitted from the transmitting side, and each time a data transmission request is made to the transmitting side, the downlink quality is measured from the known signal and reported to the transmitting side and held, Further, every time frame data sent from the transmission side in response to a data transmission request is received, the downlink quality is measured and held. On the other hand, if an error is detected in the decoding process of the received frame data, the data for the transmission side Each downlink quality measurement value reported to the transmission side for each transmission request and each downlink quality measurement value measured when the frame data transmitted from the transmission side is received for each data transmission request are framed. The frame corresponding to the frame number for which the difference between the measured downlink quality measurement value and the received downlink quality measurement value is the largest. Resend requests over dataIt is characterized by that.Further, the data communication method of the invention according to claim 2 is the data communication method of the invention of claim 1, wherein when an error is detected in the decoding process of the received frame data, the data communication method for each data transmission request to the transmission side Each downlink quality measurement value reported to the transmission side and each downlink quality measurement value measured when receiving the frame data sent from the transmission side for each data transmission request are compared for each frame number. A retransmission request is made for frame data corresponding to a frame number having the largest difference among frames having a smaller downlink quality measurement value than the reported downlink quality measurement value. And
[0045]
According to this method, the reception side measures when the frame data is actually transmitted, compared to the measurement value of each downlink quality reported to the transmission side at the time of the data transmission request in the frame data retransmission request. The smaller the downlink quality measurement value, the higher the possibility that the modulation scheme or transmission rate selected on the transmission side is not valid, and requests retransmission of the frame data.
Therefore, since the receiving side can secure highly reliable frame data in the frame data retransmission request, the number of retransmissions can be reduced and efficient data transmission can be achieved.
[0046]
  Claim 3In the data communication method according to the invention, the receiving side receives a known signal that is constantly transmitted from the transmitting side, and measures the downlink quality from the known signal each time a data transmission request is made to the transmitting side. Report and hold to the transmitting side, and measure and hold the downlink quality every time frame data sent from the transmitting side is received in response to a data transmission request, ReceivedWhen an error is detected in the decoding process of the received frame data, each downlink quality measurement value reported to the transmission side is compared with a predetermined reference value, and each downlink quality measurement value reported to the transmission side Are all equal to or higher than the reference value, the measured values are compared with the measured values of the downlink quality measured when the frame data transmitted from the transmitting side is received for each data transmission request for each frame number. Frame data corresponding to the smallest difference among the measured values of each downlink quality at the time of reception.ReIt is characterized by requesting transmission.
[0047]
According to this method, when all of the downlink quality measurement values reported to the transmission side at the time of data transmission request are greater than or equal to the reference value in the frame data retransmission request, the reception side actually As the difference between each downlink quality measurement value measured when the frame data is sent is the largest, the modulation method or transmission rate selected on the transmission side is likely to be invalid, and the frame data is Delete and request retransmission.
Therefore, since the receiving side can secure highly reliable frame data in the frame data retransmission request, the number of retransmissions can be reduced and efficient data transmission can be achieved.
[0048]
  Claim 4The data communication method of the invention according toClaim 3In the data communication method according to the invention, if the receiving side compares one measured value of each downlink quality reported to the transmitting side with a predetermined reference value and there is one that is less than the reference value, Delete the corresponding frame data and request retransmission, and if there are multiple items less than the reference value, the frame data corresponding to the smallest value among themReIt is characterized by requesting transmission.
[0049]
According to this method, in the frame data retransmission request, if there is one less than the reference value in the comparison between each downlink quality measurement value reported to the transmission side and the predetermined reference value in the frame data retransmission request, The corresponding frame data is deleted and a retransmission request is made. If there are a plurality of frames whose values are less than the reference value, the frame data corresponding to the smallest value is deleted and a retransmission request is made.
Therefore, since the receiving side can secure highly reliable frame data in the frame data retransmission request, the number of retransmissions can be reduced and efficient data transmission can be achieved.
[0092]
  Claim 5The mobile device according to the present invention receives and decodes one block of frame data transmitted from the base station apparatus, and when an error is detected in the decoding result, requests the base station apparatus to retransmit the frame data In a mobile station, downlink quality measuring means for measuring downlink quality by receiving a known signal constantly transmitted from the base station apparatus, and the downlink quality every time a data transmission request is made to the base station apparatus A downlink quality reporting means for reporting a measurement value of the downlink quality measured by the measuring means to the base station apparatus, and a measurement by the downlink quality measuring means every time a data transmission request is made to the base station apparatus. First downlink quality storage means for storing the measured downlink quality value, and a frame transmitted from the base station apparatus in response to a data transmission request to the base station apparatus A second downlink channel quality storing means for storing the measured value of the downlink quality in the downlink quality measuring unit each time it receives the over data,ReceivingWhen an error is detected in the decoding process of the received frame data, each downlink quality measurement value stored in the first downlink quality storage means and each downlink quality stored in the second downlink quality storage means Are measured for each frame number, and the downlink quality measurement value stored in the first downlink quality storage means and the downlink quality measurement stored in the second downlink quality storage means are read out. A frame data retransmission requesting unit that requests retransmission of frame data corresponding to a frame number having the largest difference from the value.The mobile device of the invention according to claim 6 is the mobile device of the invention according to claim 5, wherein the frame data retransmission request means detects the first downlink when an error is detected in the decoding process of the received frame data. Each downlink quality measurement value stored in the channel quality storage means and each downlink quality measurement value stored in the second downlink quality storage means are read out and compared for each frame number, and the second downlink quality measurements are compared. The difference between the measured values of the downlink channel quality stored in the channel quality storage means is lower than the measured value of the downlink channel quality stored in the first downlink quality storage means. A configuration is adopted in which retransmission of frame data corresponding to the largest frame number is requested.
[0093]
According to this configuration, in the frame data retransmission request, the mobile station compares each measured downlink quality measurement value and each received downlink quality measurement value for each frame number, and reports the measured downlink quality value. Frame data corresponding to a frame number having the largest difference between the received downlink quality measurement value and the received downlink quality measurement value is requested to be retransmitted.
Therefore, since the mobile device can secure highly reliable frame data in the frame data retransmission request, the number of retransmissions can be reduced and efficient data transmission can be performed.
[0096]
  Claim 7The mobile device according to the invention decodes the frame data transmitted from the base station device every time one block data is received, and when an error is detected in the decoding result, sends a request for retransmission of the frame data to the base station device. In the mobile station to perform, a downlink quality measuring means for measuring a downlink quality value by receiving a known signal constantly transmitted from the base station apparatus, and the downlink quality measurement each time a data transmission request is made to the base station apparatus A downlink quality reporting means for reporting the measured value of the downlink quality measured by the channel quality measuring means to the base station apparatus, and the downlink quality measuring means for each data transmission request to the base station apparatus. First downlink quality storage means for storing the measured downlink quality value, and a frame sent from the base station apparatus in response to a data transmission request to the base station apparatus. A second downlink channel quality storing means for storing the measured value of the downlink quality in the downlink quality measuring unit each time it receives a Mudeta,ReceivingWhen an error is detected in the decoding process of the received frame data, each downlink quality measurement value stored in the first downlink quality storage means is compared with a predetermined reference value, If there is, frame data corresponding to the smallest value including one caseReAnd when all of the downlink quality measurement values are equal to or greater than the reference value, the measurement values and the downlink quality measurement values stored in the second downlink quality storage means are The frame data corresponding to the frame number having the smallest difference among the measured values of the downlink quality stored in the second downlink quality storage means with the largest difference between the frame numbers.ReAnd a frame data retransmission requesting means for requesting transmission.
[0097]
According to this configuration, in the frame data retransmission request, when all the downlink quality measurement values reported to the base station apparatus at the time of data transmission request are equal to or higher than the reference value, It is highly possible that the modulation method or transmission rate selected by the base station apparatus is not as appropriate as the difference between the downlink quality measurement values measured when the frame data is transmitted to the Request retransmission of frame data.
Therefore, since the mobile device can secure highly reliable frame data in the frame data retransmission request, the number of retransmissions can be reduced and efficient data transmission can be performed.
[0124]
DETAILED DESCRIPTION OF THE INVENTION
The essence of the present invention is that the mobile station receives a known signal that is always transmitted from the base station device, so that the base station device measures the downlink quality every time it requests data transmission to the base station device. When all the frame data divided into a plurality of block data is transmitted and there is no untransmitted frame data, and the mobile device fails to decode, the downlink quality measurement value corresponding to each received frame data The first frame data for starting retransmission is determined based on the above.
[0125]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0126]
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a data communication system according to Embodiment 1 of the present invention. In this figure, parts common to those in FIG. 9 described above are denoted by the same reference numerals and description thereof is omitted.
[0127]
In the data communication system of the present embodiment, when a mobile station 110 requests a base station apparatus 100 to transmit data, the mobile station 110 receives a known signal that is constantly transmitted from the base station apparatus 100 and measures the downlink quality measured by the base station. While reporting to the apparatus 100, the measured value is held for each of the frame data n-A, n-B, and n-C. When all the frame data n-A, n-B, and n-C for one block data are received, and there is an error in the decoding result, based on the measurement value of the downlink quality that is held. The first frame data for starting retransmission is determined.
[0128]
Here, if the mobile device 110 can successfully decode all the frame data n-A, n-B, and n-C for one block data, the transmission of the current block data is completed, and the next block Data transmission starts. The data communication system according to the present embodiment increases the number of retransmissions when the mobile device 110 cannot normally decode even if it receives all the frame data n-A, n-B, and n-C for one block data. Try to keep it to a minimum.
[0129]
Further, like the conventional data communication system described above, one block data is divided into three, but the number is not necessarily limited to this number and is arbitrary.
[0130]
Further, the contents of each frame data obtained by dividing one block data into three do not necessarily have the same number of bits. For example, assuming that the information bits + CRC bits in the original block data are 100 bits, If the encoding rate is 1/3, the encoding is 300 bits, the first 1-A may be 150 bits, the next 1-B may be 100 bits, and the last 1-C may be 50 bits. May be 100 bits.
[0131]
In addition, in order to enable mobile device 110 to recognize the last frame data (nC in the case of 3 divisions), the number of divisions may be determined in advance between base station apparatus 100 and mobile device 110. The base station apparatus 100 may notify the mobile station 110 that it is the last frame data, or the mobile station 110 recognizes that the same frame data has been received in a round and is immediately before. This frame data may be recognized as the last frame data. In short, any method may be used as long as the mobile device 110 can recognize that it is the last frame data.
[0132]
Further, as downlink quality, for example, the S / N ratio (carrier power (including noise power) to interference wave power ratio) of a known signal, Eb / No of known signal (energy to interference wave per bit of the known signal) Power (including noise power)), Ec / No of known signal (energy per interference chip of known signal vs. interference power (including noise power)), etc. In the data communication system of the present embodiment, Including the data communication system of each embodiment described in the above, the downlink quality is the carrier power (including noise power) to interference wave power ratio of a known signal. A measured value of the carrier power (including noise power) to interference wave power ratio is referred to as a C / I value.
[0133]
The base station apparatus 100 includes a blocking unit 901, an error detection data adding unit 902, an encoding unit 903, a number adding unit 904, a first storage unit 905, a transmitting unit 907, and a duplexer 908. , Antenna 909, receiving unit 910, first transmission method determining unit 102, and first control unit 107. The first transmission scheme determination unit 102 determines the transmission scheme (modulation scheme and transmission rate) of the transmission signal for the mobile station 110 based on the C / I value sent from the mobile station 110 when the data transmission is requested.
[0134]
The mobile device 110 includes an antenna 921, a duplexer 922, a reception unit 929, a number extraction unit 924, a second storage unit 113, a decoding unit 926, an error detection unit 927, and a C / I measurement unit 112. The second control unit 114, the first report C / I storage unit 115, the first C / I comparison unit 116, the first retransmission frame selection unit 117, and the transmission unit 923 are configured.
[0135]
The C / I measurement unit 112 measures the C / I value from a known signal that is constantly transmitted from the base station apparatus 100. If there is an error in the received frame data based on the error detection result from the error detection unit 927, the second control unit 114 requests the base station apparatus 100 to retransmit the frame data. In this case, a frame number is specified in the retransmission request. The first report C / I storage unit 115 stores a C / I value reported to the base station apparatus 100 when a data transmission request is made.
[0136]
The first C / I comparison unit 116 compares the C / I value stored in the first report C / I storage unit 115 with a predetermined reference value, and outputs the result. The first retransmission frame selection unit 117 determines frame data to be retransmitted based on the comparison result from the first C / I comparison unit 116. When data transmission is requested to the base station apparatus 100, the second control unit 114 reports the fact and the C / I value measured from the known signal at that time to the base station apparatus 100. Further, the C / I value at this time is stored in the first report C / I storage unit 115.
[0137]
In the base station apparatus 100, when there is a data transmission request from the mobile device 110, the first control unit 107 determines whether or not transmission to the mobile device 110 is possible. Based on the determined C / I value, the first transmission method determination unit 102 determines the modulation method and transmission rate, and notifies the mobile device 110 of the determined modulation method and transmission rate. In this case, notification to the mobile device 110 is performed in the connected call. The functions of the blocking unit 901, the error detection data adding unit 902, the encoding unit 903, the number adding unit 904, and the first storage unit 905 are the same as those of the conventional one, and the description thereof is omitted.
[0138]
The C / I measuring unit 112 is a downlink quality measuring unit, the first report C / I storage unit 115 is a downlink quality storing unit, and the second control unit 114 is a downlink quality reporting unit. The determination unit 102 corresponds to a transmission method determination unit. The first C / I comparison unit 116, the first retransmission frame selection unit 117, and the second control unit 114 constitute a frame data retransmission request unit.
[0139]
Next, the operation of the data communication system configured as described above will be described.
The first control unit 107 of the base station apparatus 100 transmits the next frame data when a NACK signal is transmitted from the mobile device 110, but transmits the frame data in the order of frame numbers until the ACK signal is transmitted. . When the second control unit 114 of the mobile device 110 detects an error in the decoding result of the frame data sent from the base station device 100, the second control unit 114 notifies the base station device 100 of the NACK signal and the C / I value. In this case, the C / I value is repeatedly transmitted until the frame data addressed to itself is transmitted from the base station apparatus 100. Further, during this time, every time the C / I value is transmitted, the first report C / I storage unit 115 stores it.
[0140]
When frame data addressed to itself is sent from base station apparatus 100, second control section 114 of mobile device 110 uses the C / I value reported to base station apparatus 100 immediately before that as the report value of the current frame data. And Then, the next frame number is selected and transmitted together with the NACK signal until no error is detected in the decoding result. If an error is detected in the decoding result even if there is no untransmitted frame data, the first C / I comparison unit 116 of the mobile device 110 transmits the frame data n-A, n-B, n transmitted so far. The C / I value at the time of data transmission request corresponding to each of -C is compared with a predetermined reference value, and the result is reported to the first retransmission frame selection unit 117.
[0141]
When there is one C / I value less than a predetermined reference value among the comparison results reported by the first C / I comparison unit 116, the first retransmission frame selection unit 117 requests retransmission of the corresponding frame data. To do. When there are a plurality of C / I values less than the predetermined reference value, the one with the smallest value is selected, and the corresponding frame data is requested to be retransmitted. When requesting retransmission of frame data, the frame data of the same frame number stored in the second storage unit 113 is deleted so as not to be used for maximum ratio composition.
[0142]
On the other hand, when all the C / I values are equal to or greater than a predetermined reference value from the comparison results input from the first C / I comparison unit 116, the one having the largest value than the reference value is selected and Request retransmission of corresponding frame data. The frame data corresponding to the C / I value having the largest value than the reference value is used for the maximum ratio combining when the frame data having the same frame number is retransmitted. That is, the frame data corresponding to the C / I value having the largest value than the reference value is used for maximum ratio synthesis without being deleted.
[0143]
When receiving the frame data requested to be retransmitted from the mobile device 110, the first control unit 107 of the base station apparatus 100 reads the frame data from the first storage unit 905 and retransmits the frame data toward the mobile device 110.
[0144]
As described above, according to the data communication system of the present embodiment, the mobile device 110 receives all the frame data n-A, n-B, and n-C for one block data. When an error is detected, if one C / I value corresponding to each frame data stored in the first report C / I storage unit 115 is less than a predetermined reference value, it corresponds to that. Select the frame data, and if there are multiple frames, select the one with the smallest value and delete the frame data corresponding to the selected C / I value so that it is not used for maximum ratio combining. If the C / I value corresponding to the frame data is greater than or equal to the reference value, the largest value is selected and the corresponding frame data is requested to be retransmitted, and new frame data is retransmitted. Since so as to use the maximum ratio combining in time, it is possible to suppress a decrease in error correction capability due to the presence of significant frame data of the error, the increase in resulting in the number of retransmissions is minimized.
[0145]
(Embodiment 2)
FIG. 2 is a block diagram showing a configuration of a data communication system according to Embodiment 2 of the present invention. In this figure, components having the same operations as those in the block diagram shown in FIG.
[0146]
The data communication system of the present embodiment stores the C / I value reported from the mobile device 210 every time the base station apparatus 200 transmits frame data n-A, n-B, and n-C. A function for determining frame data to be retransmitted based on each stored C / I value when a NACK signal is sent from the mobile device 210 every time each frame data is transmitted until there is no transmission frame data. Have. That is, the base station apparatus 200 determines the frame data to be retransmitted. Incidentally, in the data communication system according to the first embodiment described above, the mobile station 110 determines the frame data to be retransmitted.
[0147]
In order to realize the above function, the data communication system of the present embodiment is different from the data communication system of Embodiment 1 in the base station apparatus 200 in the second report C / I storage unit 202 and the second retransmission. The mobile device 210 further includes a frame selection unit 203. The mobile device 210 includes a second C / I comparison unit 211 instead of the first C / I comparison unit 116 and the first retransmission frame selection unit 117 of FIG. Take the configuration.
[0148]
The second report C / I storage unit 202 corresponds to downlink quality storage means. The first control unit 107, the first storage unit 905, and the transmission unit 907 constitute a data transmission unit. The second retransmission frame selection unit 203 and the first control unit 107 constitute frame data retransmission means. The second control unit 114 corresponds to downlink quality reporting means, the first report C / I storage unit 115 corresponds to storage means, and the second C / I comparison unit 211 corresponds to comparison means.
[0149]
In the base station device 200, the second report C / I storage unit 202 stores the C / I value reported from the mobile device 210 that has issued the data transmission request. When the NACK signal is sent from the mobile device 210 until there is no untransmitted frame data in one block data, the second retransmission frame selection unit 203 receives the block data from the second report C / I storage unit 202. All C / I values corresponding to each transmitted frame data are read out, and the C / I value having the smallest value is selected. Then, the frame data corresponding to the selected C / I value is set as the next retransmission frame data.
[0150]
When the mobile device 210 receives the frame data retransmitted from the base station apparatus 200, the second C / I comparison unit 211 receives the C / I value measured at the time of requesting transmission of the frame data, the first report C / The C / I value corresponding to the received frame data of the same frame number stored in the I storage unit 115 is compared. In this comparison, when the C / I value at the time of requesting transmission of newly received frame data is larger than the C / I value corresponding to the previously received frame data of the same frame number, the difference is increased. Accordingly, it is determined whether the frame data having the same frame number received earlier is deleted and the newly received frame data is overwritten, or the frame data having the same frame number received earlier is combined with the maximum ratio.
[0151]
Thus, according to the data communication system of the present embodiment, when there is no untransmitted frame data with the same block number in base station apparatus 200 and there is a retransmission request from mobile station 210, the base station apparatus Reference numeral 200 denotes a frame corresponding to the smallest C / I value received from the mobile device 210 immediately before transmitting the frame data n-A, n-B, and n-C having the same block number. When data is selected and retransmitted to mobile device 210, and mobile device 210 receives frame data retransmitted from base station apparatus 200, C / I value corresponding to the frame data and previously received data are received. The C / I value corresponding to the frame data with the same frame number is compared, and the frame data with the same frame number received earlier is deleted and newly received according to the magnitude of the difference. It is possible to suppress the decrease in error correction capability, and as a result, the number of retransmissions can be reduced as a result of determining whether to overwrite the received frame data or to combine with the previously received frame data of the same frame number. Increase is minimized.
[0152]
(Embodiment 3)
FIG. 3 is a block diagram showing a configuration of a data communication system according to Embodiment 3 of the present invention. In this figure, parts having the same functions as those shown in FIGS. 1 and 2 are denoted by the same reference numerals and description thereof is omitted.
[0153]
The data communication system according to the present embodiment performs maximum ratio combining when the base station apparatus 300 retransmits each frame data n-A, n-B, and n-C transmitted to the mobile device 310 later. If it is determined that there is something that is not worth it, a deletion signal for deleting it is transmitted, and if it is determined that each frame data transmitted to the mobile device 310 has a certain degree of reliability, the maximum ratio combining By doing so, it has a function of retransmitting from frame data which is considered to improve the correction capability.
[0154]
In order to realize this function, the base station apparatus 300 adds a third C / I comparison unit 301, a third retransmission frame selection unit 302, and a first deletion determination unit 303 to the base station apparatus 200 of FIG. The mobile device 310 adopts a configuration in which a C / I measuring unit 311 is added to the conventional mobile device 920 of FIG.
[0155]
The second report C / I storage unit 202 corresponds to downlink quality storage means. The first control unit 107, the first storage unit 905, and the transmission unit 907 constitute a data transmission unit. The first control unit 107, the third C / I comparison unit 301, the third retransmission frame selection unit 302, and the first deletion determination unit 303 constitute a frame data retransmission unit. The C / I measuring unit 311 corresponds to downlink quality measuring means, and the second control unit 928 corresponds to downlink quality reporting means and frame data deletion means.
[0156]
In base station apparatus 300, second report C / I storage section 202 stores the C / I value reported from mobile device 310 every time frame data n-A, n-B, and n-C are transmitted. To do. When the NACK signal is returned from the mobile device 310 every time each frame data is transmitted until there is no untransmitted frame data with the same block number, the first control unit 107 next sends a third retransmission frame selection unit 302 to the next time. Instructs selection of frame data to be transmitted.
[0157]
When receiving the instruction of the next frame data to be transmitted from the first control unit 107, the third retransmission frame selection unit 302 sends the mobile station corresponding to each frame data transmitted so far to the third C / I comparison unit 301. An instruction to compare the C / I value received from 310 (stored in second report C / I storage unit 202) with a predetermined reference value is issued. Upon receiving an instruction from the third retransmission frame selection unit 302, the third C / I comparison unit 301 sequentially reads out each C / I value stored in the second report C / I storage unit 202 and obtains a predetermined reference value. The comparison is made and the result is reported to the third retransmission frame selection unit 302.
[0158]
Upon receiving a report from the third C / I comparison unit 301 and detecting one C / I value less than a predetermined reference value, the third retransmission frame selection unit 302 determines the corresponding frame data as the next retransmission frame data. To the first control unit 107 and the first deletion determination unit 303. When there are a plurality of C / I values less than the predetermined reference value, the one with the smallest value is selected, and the corresponding frame data is set as the next retransmission frame data and the first control unit 107 and the first one. Report to the deletion determination unit 303. If all the C / I values are equal to or greater than a predetermined reference value, the one having the largest value is selected and the corresponding frame data (ie, when the maximum ratio is combined on the mobile device 310 side). Frame data that is considered to have improved error correction capability) is reported to the first control unit 107 as the next retransmission frame data.
[0159]
The first deletion determination unit 303 receives the report from the third retransmission frame selection unit 302 and deletes the frame data corresponding to the minimum C / I value that is less than a predetermined reference value and received by the mobile device 310. Insert a delete signal on the currently connected call. That is, the mobile device 310 sends a deletion signal that causes the mobile device 310 to delete the frame data of the same frame number received by the mobile device 310 before the mobile device 310 synthesizes the frame data to be retransmitted from the maximum ratio. Send. More specifically, in the frame data received by the mobile device 310, a deletion signal is transmitted for frame data not worthy of maximum ratio combining when retransmitted later. The second control unit 928 of the mobile device 310 deletes the corresponding frame data stored in the second storage unit 925 by receiving this deletion signal.
[0160]
Thus, according to the data communication system of the present embodiment, when there is no untransmitted frame data with the same block number in base station apparatus 300 and there is a retransmission request from mobile station 310, the base station apparatus 300 determines whether each C / I value received from the mobile device 310 satisfies a predetermined reference value every time frame data n-A, n-B, and n-C having the same block number are transmitted. If there is one that does not satisfy, the corresponding frame data is selected. If there are a plurality of items that do not satisfy, the smallest value is selected, and the selected C / I value is selected. The corresponding frame data is retransmitted, and a delete signal for deleting the frame data received by the mobile device 310 with the same frame number as the retransmitted frame data is transmitted. When the corresponding C / I value satisfies the reference value, the largest value among them is selected, and the corresponding frame data is retransmitted. As a result, an increase in the number of retransmissions can be minimized.
[0161]
(Embodiment 4)
FIG. 4 is a block diagram showing a configuration of a data communication system according to Embodiment 4 of the present invention. In this figure, components having the same operations as those in the block diagram shown in FIG.
[0162]
In the data communication system according to the present embodiment, the mobile device 410 makes a C / I value (hereinafter referred to as a reported C / I value) reported to the base station device 400 when it makes a data transmission request to the base station device 400. And the C / I value measured when the frame data n-A, n-B, and n-C are transmitted from the base station apparatus 400 and are received (hereinafter referred to as the received C / I value). Has a function of determining frame data to be retransmitted based on the difference. That is, when the difference between the reported C / I value and the received C / I value is large, especially when the received C / I value is smaller, the modulation scheme or transmission rate selected on the base station apparatus 400 side may not be appropriate. The frame data is retransmitted on the assumption that it is highly likely.
[0163]
In order to realize this function, the mobile device 410 stores the reception C / I value at the time when the frame data n-A, n-B, and n-C transmitted from the base station apparatus 400 are received. / I storage unit 411, report C / I value stored in first report C / I storage unit 115, and reception C / I value stored in reception C / I storage unit 411, respectively, and next retransmission request A configuration is adopted in which a fourth retransmission frame selection unit 412 for selecting frame data to be added is added.
[0164]
The first report C / I storage unit 115 corresponds to the first downlink quality storage unit, and the reception C / I storage unit 411 corresponds to the second downlink quality storage unit. The fourth retransmission frame selection unit 412 and the second control unit 928 constitute frame data retransmission request means.
[0165]
The second control unit 928 of the mobile device 410 stores the report C / I value reported when data transmission is requested to the base station apparatus 400 in the first report C / I storage unit 115 and requests data transmission. Control is performed to store the received C / I value measured when the frame data nA, nB, and nC transmitted from the base station apparatus 400 are received in the received C / I storage unit 411. The second control unit 928 selects the fourth retransmission frame when there is an error in the decoding result in the decoding unit 926 and a retransmission request is made to the base station device 400, and there is no untransmitted frame data in the base station device 400. The unit 412 is instructed to select frame data requested at the next retransmission.
[0166]
When receiving a frame data selection instruction from second control unit 928, fourth retransmission frame selection unit 412 receives report C / I corresponding to each frame data from first report C / I storage unit 115 and reception C / I storage unit 411. The I value and the received C / I value are read out, the same frame numbers are compared, and if there is frame data whose received C / I value is smaller than the report C / I value, the frame data is reported to the base station apparatus 400. The frame data is requested to be retransmitted. Base station apparatus 400 performs retransmission from the frame data requested to be retransmitted.
[0167]
Thus, according to the data communication system of the present embodiment, when there is no untransmitted frame data with the same block number in base station apparatus 400 and mobile station 410 receives a retransmission request, mobile station 410 Compares each reported C / I value with each received C / I value for each frame number, and the difference between the reported C / I value and the received C / I value is the largest and the received C / I value is small. Since the frame data corresponding to the frame number is requested to be retransmitted, it is possible to suppress a decrease in error correction capability, and as a result, an increase in the number of retransmissions can be minimized.
[0168]
(Embodiment 5)
FIG. 5 is a block diagram showing a configuration of a data communication system according to Embodiment 5 of the present invention. In this figure, components having the same operations as those in the block diagrams shown in FIGS. 1 and 4 are denoted by the same reference numerals as those in FIGS. 1 and 4 and description thereof is omitted.
[0169]
In the data communication system of the present embodiment, the C / I values corresponding to the frame data n-A, n-B, and n-C reported when the mobile device 510 makes a data transmission request to the base station apparatus 500 (that is, Report C / I value) is compared with a predetermined reference value. If there is one less than the reference value, the corresponding frame data is selected. If the received C / I value is small even if all of the reported C / I values are equal to or larger than the reference value, the frame data corresponding to the small one is selected, the selected frame data is deleted, and the retransmission is requested. It has a function of deleting the corresponding frame data and requesting retransmission.
[0170]
In order to realize this function, the mobile device 510 uses the report C / I value stored in the first report C / I storage unit 115 and the reception C / I value stored in the reception C / I storage unit 411. A configuration is adopted in which a fourth C / I comparison unit 511 for comparison and a fifth retransmission frame selection unit 512 for determining frame data to be requested for retransmission from the comparison result of the fourth C / I comparison unit 511 are added.
[0171]
The first report C / I storage unit 115 corresponds to the first downlink quality storage unit, and the reception C / I storage unit 411 corresponds to the second downlink quality storage unit. The second control unit 928, the fourth C / I comparison unit 511, and the fifth retransmission frame selection unit 512 constitute frame data retransmission request means.
[0172]
When there is an error in the decoding result in the decoding unit 926 of the mobile device 510 and a retransmission request is made to the base station device 500, and there is no untransmitted frame data in the base station device 500, the second control of the mobile device 510 The unit 928 instructs the fifth retransmission frame selection unit 512 to determine frame data to be requested for retransmission to the base station device 500 next time. When receiving the frame data selection instruction from the second control unit 928, the fifth retransmission frame selection unit 512 instructs the fourth C / I comparison unit 511 to compare the reported C / I value with the received C / I value. put out.
[0173]
The fourth C / I comparison unit 511 reads out all the frame data n-A, n-B, n-C having the same block number from the first report C / I value storage unit 115 and compares them with a predetermined reference value. If there is one less than the reference value, select the frame data corresponding to it, and if there are multiple items less than the reference value, select the frame data corresponding to the smallest value among them. The selected frame data is deleted, and information requesting retransmission is input to the fifth retransmission frame selection unit 512.
[0174]
When the C / I values corresponding to all the frame data n-A, n-B, and n-C are equal to or larger than the reference value, all the frame data having the same block number are received from the reception C / I storage unit 411. n-A, n-B, and n-C are read out and compared with the reported C / I value for each same frame number, and if there is a large difference and a small received C / I value, it corresponds to it. The frame data (the frame data corresponding to the smallest received C / I value when there are a plurality of frames) is deleted, and information for requesting retransmission is input to the fifth retransmission frame selection unit 512. If there is almost no difference from each report C / I value, information for requesting retransmission of frame data corresponding to the largest received C / I value is input to fifth retransmission frame selection section 512.
[0175]
The fifth retransmission frame selection unit 512 outputs the frame number of the frame data requested for retransmission based on the information input from the fourth C / I comparison unit 511, and is stored in the second storage unit 925 when necessary. The corresponding frame data is deleted. When receiving the retransmission request from the mobile device 510, the first control unit 107 of the base station device 500 reads out the corresponding frame data from the first storage unit 905 and retransmits it.
[0176]
As described above, according to the data communication system of the present embodiment, it corresponds to each frame data n-A, n-B, and n-C reported when mobile device 510 requests base station apparatus 500 to transmit data. The reported C / I value is compared with a predetermined reference value. If there is one that is less than the reference value, the corresponding frame data is selected. When frame data corresponding to a small value is selected, the selected frame data is deleted and a retransmission request is made, and the received C / I value is small even if all the reported C / I values are equal to or greater than the reference value Since the transmission method (modulation method or transmission rate) selected by the base station device 500 is likely to be invalid, the frame data is deleted and a re-transmission is requested. It becomes possible, an increase of the resulting number of retransmissions is minimized.
[0177]
(Embodiment 6)
FIG. 6 is a block diagram showing a configuration of a data communication system according to Embodiment 6 of the present invention. In this figure, components having the same operations as those in the block diagrams shown in FIGS. 1 and 2 are denoted by the same reference numerals as those in FIGS. 1 and 2 and description thereof is omitted.
In the data communication system according to the present embodiment, when there is no untransmitted frame data and base station apparatus 600 has a retransmission request from mobile device 610, each frame data n-A, n-B, n- It has a function of determining frame data to be retransmitted based on a transmission power value for a call connected when C is transmitted.
[0178]
In order to realize this function, the base station apparatus 600 replaces the first transmission scheme determination unit 102, the second report C / I storage unit 202, and the second retransmission frame selection unit 203 in FIG. A configuration including a determination unit 601, a transmission power storage unit 602, and a sixth retransmission frame selection unit 603 is adopted.
[0179]
The transmission power storage 602 corresponds to transmission power storage means, the reception C / I storage unit 115 corresponds to storage means, and the second C / I comparison unit 211 corresponds to comparison means. The first control unit 107 and the sixth retransmission frame selection unit 603 constitute frame data retransmission means.
[0180]
The second transmission power method determination unit 601 moves the retransmission target based on the transmission power value of each mobile device for a call that is already connected to transmit control information to the mobile device 610 that has issued the data transmission request. The selection of the device, the modulation method and the transmission rate at the time of transmission are determined, and the transmission power value of the mobile device is stored in the transmission power storage unit 602 when the frame data is transmitted. The sixth retransmission frame selection section 603 receives a retransmission request from the retransmission target mobile unit 610 when there is no untransmitted frame data to the retransmission target mobile unit, that is, when all frame data of the same block number is transmitted. The transmission power value for the call at the time of transmission of the frame data n-A, n-B, and n-C is read from the transmission power storage unit 602, the maximum one is found out of them, and the retransmission is performed from the corresponding frame data. I do.
[0181]
Specifically, since the transmission power value of the base station device increases when the mobile device is located far away from the base station device or when the propagation environment is bad, each frame data n-A is transmitted to the mobile device. , N-B and n-C, the transmission power value for the call at the time of transmission is read out to find the maximum one, and retransmission is performed from the corresponding frame data.
[0182]
On the other hand, in mobile unit 610, for frame data retransmitted immediately after there is no untransmitted frame data from base station apparatus 600, received corresponding to the same frame number previously extracted by number extracting unit 924 is received. The second C / I comparison unit 211 compares the C / I value stored in the reception C / I storage unit 115 with the reference value to determine whether the frame data is used for maximum ratio combining or is deleted. Determine based on.
[0183]
Thus, according to the data communication system of the present embodiment, base station apparatus 600 stores the transmission power value for the connected call at the time of each frame data transmission, and each frame data n-A, While reading the transmission power value for the call at the time of transmission of n-B and n-C, the largest one is found out, and retransmission is performed from the corresponding frame data, that is, the least reliable frame data. Since it is determined whether or not the maximum ratio combining is performed for the frame data, it is possible to suppress a decrease in error correction capability, and as a result, an increase in the number of retransmissions can be minimized.
[0184]
(Embodiment 7)
FIG. 7 is a block diagram showing a configuration of a data communication system according to Embodiment 7 of the present invention. In this figure, components having the same operations as those in the block diagrams shown in FIGS. 1, 4 and 6 are denoted by the same reference numerals as those in FIGS. 1, 4 and 6, and description thereof is omitted.
[0185]
In the data communication system according to the present embodiment, when base station apparatus 700 transmits frame data n-A, n-B, and n-C to mobile device 710, connection for transmitting a control signal is performed. The transmission power value for the middle call is held, and when there is no untransmitted frame data and there is a re-transmission request from the mobile device 710, it corresponds to each frame data n-A, n-B, n-C. The stored transmission power value is read out, compared with a predetermined reference value, and frame data to be retransmitted is determined based on the result.
[0186]
In order to realize this function, the base station apparatus 700 adopts a configuration in which a transmission power comparison unit 701, a seventh retransmission frame selection unit 702, and a second deletion determination unit 703 are added to the configuration of FIG. The device 710 has a configuration substantially the same as that in FIG. 9 (the mobile device 710 has this function although it does not have a function to delete frame data in FIG. 9).
[0187]
The first control unit 107, the transmission power comparison unit 701, the seventh retransmission frame selection unit 702, and the second deletion determination unit 703 constitute a frame data retransmission unit. The second transmission method determination unit 601 corresponds to a transmission method determination unit. The second control unit 928 corresponds to a frame data deleting unit.
[0188]
The first control unit 107 of the base station apparatus 700 selects frame data to be retransmitted to the seventh retransmission frame selection unit 702 when there is no untransmitted frame data and there is a retransmission request from the mobile device 710. Give instructions to do. Upon receiving this instruction, the seventh retransmission frame selection unit 702 sets the transmission power value and the base station apparatus 700 for the call that was being connected at the time of transmission of each frame data already transmitted to the transmission power comparison unit 701. An instruction to compare with the predetermined reference value is issued. Upon receiving the instruction, the transmission power comparison unit 701 reads the transmission power value corresponding to each frame data n-A, n-B, n-C from the transmission power storage unit 602 and compares it with the reference value. The result is reported to the seventh retransmission frame selection unit 702 and the second deletion determination unit 703.
[0189]
If there is a transmission power value equal to or higher than the reference value from the comparison result received from the transmission power comparison unit 701, the seventh retransmission frame selection unit 702 selects the frame data corresponding to the largest value among them. Report to the first control unit 107. The first control unit 107 reads the reported frame data from the first storage unit 905 and retransmits it. When there is frame data corresponding to the largest transmission power value that is equal to or larger than the reference value, the second deletion determination unit 703 uses the maximum power ratio combination for the frame data when there is frame data corresponding to the largest transmission power value that is equal to or greater than the reference value. Send a delete signal to prevent use.
[0190]
Thus, according to the data communication system of the present embodiment, base station apparatus 700 stores the transmission power value for the connected call at the time of each frame data transmission, and each frame data n-A, If there is a transmission power value equal to or higher than the reference value among the transmission power values for the n-B and n-C transmissions, the frame data corresponding to the largest value is retransmitted and the frame is transmitted. Since the mobile station 710 transmits a deletion signal for deleting the frame data received by the mobile unit 710 with the same frame number as that of the data, it is possible to suppress a decrease in error correction capability, resulting in the number of retransmissions as a result. Increase is minimized.
[0191]
(Embodiment 8)
FIG. 8 is a block diagram showing a configuration of a data communication system according to Embodiment 8 of the present invention. In this figure, components having the same operations as those in the block diagram shown in FIG.
[0192]
In the data communication system according to the present embodiment, mobile device 810 independently decodes a plurality of frame data n-A, n-B, and n-C divided by encoding unit 903 of base station apparatus 800. A function capable of obtaining reliability by decoding each frame data n-A, n-B, and n-C and determining frame data to be retransmitted based on the reliability. It is.
[0193]
In order to realize this function, the mobile device 810 adopts a configuration in which a reliability information calculation unit 801, a reliability information comparison unit 802, and an eighth retransmission frame selection unit 803 are added to the same configuration as that in FIG. .
[0194]
The reliability information calculation unit 801 corresponds to reliability information calculation means. The reliability information comparison unit 802 and the eighth retransmission frame selection unit 803 constitute frame data retransmission request means.
[0195]
When there is an error in the detection result of error detector 927 and there is no untransmitted frame data in base station apparatus 800, second controller 114 of mobile device 810 sends each frame data n to reliability information calculator 801. Instruct to calculate the reliability for each of -A, n-B, and n-C. When the reliability information calculation unit 801 receives the instruction, the reliability information calculation unit 801 reads each frame data n-A, n-B, n-C from the second storage unit 925 to the decoding unit 926 and independently decodes each frame data n-A, n-B, n-C. Likelihood information for each decoded bit is output. Then, the likelihood information for each decoded bit is added and input to the reliability information comparison unit 802 as the reliability of each of the frame data nA, nB, and nC.
[0196]
The reliability information comparison unit 802 compares the reliability from the reliability information calculation unit 801 with a predetermined reference value, and reports the result to the eighth retransmission frame selection unit 803. The eighth retransmission frame selection unit 803 selects frame data corresponding to one of the comparison results that is less than the reference value, and if there are a plurality of items that are less than the reference value, The frame data corresponding to the smallest value is selected, the selected frame data is requested to be retransmitted, and the frame data of the same frame number stored in the second storage unit 925 is erased. On the other hand, when all the reliability corresponding to each frame data is equal to or higher than the reference value, a retransmission request for the frame data having the highest reliability is made.
[0197]
Thus, according to the data communication system of the present embodiment, mobile station 810 transmits all frame data n-A, n-B, and n-C in the block data having the same block number from base station apparatus 800. If there is no untransmitted frame data and an error is detected in the decoding process of the received frame data, each received frame data n-A, n-B, n-C is independently decoded. The frame corresponding to the reliability less than a certain reference value is obtained by adding the likelihood information of the decoded bits obtained at that time to the reliability of each of the frame data n-A, n-B, and n-C. The data is deleted and retransmitted, and if all the reliability corresponding to each frame data n-A, n-B, and n-C is equal to or higher than the reference value, the data with the largest value is used. Since the retransmission request from the frame data, it is possible to suppress a decrease in error correction capability, increasing as a result, the number of retransmissions is minimized.
[0198]
In the data communication system of each of the above embodiments, three frame data n-A, n-B, and n-C are generated from one block data. However, this number is not limited and the number of divisions Is optional.
[0199]
【The invention's effect】
As described above, according to the present invention, it is possible to provide a data communication system capable of efficient data transmission that can reduce the number of retransmissions.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a data communication system according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of a data communication system according to a second embodiment of the present invention.
FIG. 3 is a block diagram showing a configuration of a data communication system according to a third embodiment of the present invention.
FIG. 4 is a block diagram showing a configuration of a data communication system according to a fourth embodiment of the present invention.
FIG. 5 is a block diagram showing a configuration of a data communication system according to a fifth embodiment of the present invention.
FIG. 6 is a block diagram showing a configuration of a data communication system according to a sixth embodiment of the present invention.
FIG. 7 is a block diagram showing a configuration of a data communication system according to a seventh embodiment of the present invention.
FIG. 8 is a block diagram showing a configuration of a data communication system according to an eighth embodiment of the present invention.
FIG. 9 is a block diagram showing the configuration of a conventional data communication system
FIG. 10 is a diagram for explaining the operation of a conventional data communication system;
[Explanation of symbols]
100, 200, 300, 400, 500, 600, 700, 800 Base station apparatus
110, 210, 310, 410, 510, 610, 710, 810
102 1st transmission system determination part
103, 107 first control unit
112, 311 C / I measuring section
113 2nd memory | storage part
114 Second control unit
115 First Report C / I Storage Unit
116 1st C / I comparison part
117 First retransmission frame selection unit
202 Second report C / I storage unit
203 Second retransmission frame selector
211 2nd C / I comparison part
301 3rd C / I comparator
302 Third retransmission frame selection unit
303 first deletion determination unit
411 Reception C / I storage unit
412 Fourth retransmission frame selection unit
511 4th C / I comparison part
512 fifth retransmission frame selection unit
601 Second transmission method determination unit
602 Transmission power storage unit
603 Sixth retransmission frame selection unit
701 Transmission power comparison unit
702 Seventh retransmission frame selection unit
703 Second deletion determination unit
801 Reliability information calculation unit
802 Reliability Information Comparison Unit
803 Eighth retransmission frame selection unit
901 Blocking unit
902 Error detection data adding unit
903 Coding unit
904 Numbering part
905 First storage unit
907, 923 transmitter
908, 922 Duplexer
909, 921 Antenna
928 Second control unit
910, 929 receiver
924 number extraction unit
925 second storage unit
926 decryption unit
927 Error detection unit
928 Second control unit

Claims (7)

The receiving side receives a known signal that is always transmitted from the transmitting side, and each time a data transmission request is made to the transmitting side, the downlink quality is measured from the known signal and reported to the transmitting side and held, while holding the measured downlink channel quality for each of receiving frame data transmitted from said transmitting side further by a data transmission request, when an error is detected in the decoding process of the received Shinzumi frame data for the sender Each downlink quality measurement value reported to the transmission side for each data transmission request, and each downlink quality measurement value measured when the frame data sent from the transmission side is received for each data transmission request The frame corresponding to the frame number for which the difference between the measured downlink quality measurement value and the received downlink quality measurement value is the largest for each frame number. Data communication method characterized by retransmission request for over data. When an error is detected in the decoding process of the received frame data, each downlink quality measurement value reported to the transmission side for each data transmission request to the transmission side and the data sent from the transmission side for each data transmission request Each downlink quality measurement value measured when receiving the received frame data is compared for each frame number, and the received downlink quality measurement value is smaller than the reported downlink quality measurement value. 2. The data communication method according to claim 1, further comprising: requesting retransmission of frame data corresponding to a frame number having the largest difference. The receiving side receives a known signal that is always transmitted from the transmitting side, and each time a data transmission request is made to the transmitting side, the downlink quality is measured from the known signal and reported to the transmitting side and held, while retaining further measures downlink channel quality for each of receiving frame data transmitted from the transmitting side by the data transmission request, when an error is detected in the decoding process of the received Shinzumi frame data, to the transmitting side Compare each downlink quality measurement value reported to a predetermined reference value, and if all the downlink quality measurement values reported to the transmission side are equal to or greater than the reference value, those measurement values and data transmission Each frame number is compared with the measured value of the downlink quality measured when the frame data sent from the transmission side is received for each request, and the difference between them is the largest and Data communication method characterized by retransmission request frame data corresponding to the small one of the most value among the measured values of channel quality Ri. The receiving side deletes the corresponding frame data and resends if there is one that is less than the reference value in the comparison between the measured value of each downlink quality reported to the transmitting side and a predetermined reference value. requesting, if a plurality is of less than the reference value, according to claim 3 data communication method wherein a re-transmission request frame data corresponding to the small one of the most value among them. When receiving frame data sent from the base station apparatus for one block data and decoding it, and detecting an error in the decoding result, in the mobile device that makes a retransmission request of the frame data to the base station apparatus,
Downlink quality measuring means for measuring downlink quality by receiving a known signal constantly transmitted from the base station device,
Downlink quality reporting means for reporting a downlink quality measurement value measured by the downlink quality measurement means to the base station apparatus every time a data transmission request is made to the base station apparatus;
First downlink quality storage means for storing a measurement value of downlink quality measured by the downlink quality measurement means each time a data transmission request is made to the base station apparatus;
A second downlink quality that stores a measurement value of the downlink quality measured by the downlink quality measuring means every time frame data sent from the base station device is received in response to a data transmission request to the base station device Storage means;
If an error is detected in the decoding process of the received Shinzumi frame data, each downlink stored in the measured value of the downlink quality stored in the first downlink quality storage means and the second downlink channel quality storage means The quality measurement values are read out and compared for each frame number, and the downlink quality measurement values stored in the first downlink quality storage means and the downlink quality values stored in the second downlink quality storage means are compared. Frame data retransmission request means for requesting retransmission of frame data corresponding to a frame number having the largest difference from the measured value;
A mobile device comprising: When the frame data retransmission request means detects an error in the decoding process of the received frame data, each downlink quality measurement value stored in the first downlink quality storage means and the second downlink quality storage means The downlink quality measurements stored in the second downlink quality storage means are read out and compared for each frame number, and the downlink quality measurement value stored in the second downlink quality storage means is the first downlink. 6. The frame data corresponding to the frame number having the largest difference is requested to be retransmitted from frame data lower than the measured value of downlink channel quality stored in the quality storage means. Mobile machine. When the frame data transmitted from the base station apparatus is decoded every time one block data is received, and an error is detected in the decoding result, in the mobile device that requests retransmission of the frame data to the base station apparatus,
Downlink quality measuring means for measuring a downlink quality value by receiving a known signal constantly transmitted from the base station device,
Downlink quality reporting means for reporting a downlink quality measurement value measured by the downlink quality measurement means to the base station apparatus every time a data transmission request is made to the base station apparatus;
First downlink quality storage means for storing a measurement value of downlink quality measured by the downlink quality measurement means each time a data transmission request is made to the base station apparatus;
A second downlink quality that stores a measurement value of the downlink quality measured by the downlink quality measuring means every time frame data sent from the base station device is received in response to a data transmission request to the base station device Storage means;
If an error is detected in the decoding process of the received Shinzumi frame data, compares the measured value with a predetermined reference value for each downlink quality stored in the first downlink quality storage means, of less than the reference value If there is, then retransmission request frame data corresponding to the most value of the small one among them including the case of one, wherein when all the measured values of the downlink quality is equal to or larger than the reference value, of which The measured value and the measured value of each downlink quality stored in the second downlink quality storage means are compared for each frame number, and the difference between them is the largest and stored in the second downlink quality storage means and frame data retransmission request means for retransmission request frame data corresponding to the small frame number of the most value among the measurement values of the downlink quality,
A mobile device comprising:

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