JP3481542B2 - Error correction transmitting circuit and receiving circuit in wireless communication system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless communication system that performs communication while coexisting with an interference wave transmitted with a large transmission power at the same frequency, and particularly, the influence of interference between the two. The present invention relates to an error correction transmitting circuit and a receiving circuit in a wireless communication system, which performs error correction coding to transmit and receive a signal with suppressed deterioration of channel quality when performing time segregation while suppressing.

[0002]

2. Description of the Related Art In a wireless communication system, an error correction method is generally applied to correct an error occurring in a wireless transmission section. In this error correction method, data to be transmitted is encoded according to a specific encoding method and then transmitted. For example, in convolutional coding that has a high improvement effect on random errors, the encoder outputs 2-bit convolutional-coded transmission data each time one bit to be transmitted is input. In this case, the coding rate becomes 1/2. On the other hand, on the receiving side, the demodulated data is decoded. Viterbi decoding is generally applied to error-correcting codes that have been subjected to convolutional coding. In Viterbi decoding, hard decision or soft decision is performed on the demodulated signal symbol output from the detection circuit, and the decision value is output. The most likely transmission data is estimated using this judgment value, and the estimated data is output. Errors are corrected in the operation of estimating the most probable data.

In order to enhance the effect of this error correction, a method of randomizing an error by interleaving the output signal of the encoder can be considered. Error correction methods such as convolutional coding and Viterbi decoding are introduced in the TDMA communication, by Heiichi Yamamoto and Shuzo Kato, pages 103-135, 1989, published by the Institute of Electronics, Information and Communication Engineers. In the error correction method, since transmission is performed by adding redundant bits to the bit to be transmitted, the transmission power is increased as compared with before the error correction is performed, but the error can be reduced by performing the error correction. High quality wireless communication can be realized.
Further, since it has a characteristic that it is possible to reduce the transmission power under a constant required error rate, it has been often used in a wireless communication system with many errors on the transmission path.

As an example of the conventional error correction system, an example of the configuration of a transmission circuit is shown in FIG. 5 and an example of the configuration of a reception circuit is shown in FIG. 6 (references: system outline, Morikura et al., NTTR & D, vo).
l. 48, Aug. Issued in 1999).

In the transmission circuit shown in FIG. 5, the transmission data (a) is input to the error correction coding circuit 61 and the error correction code (b) is output. In the interleave circuit 62, the error correction code (b) is interleaved, and an operation for improving resistance to random errors is performed. The interleaved signal (c) is input to the modulation circuit 63, modulated according to a predetermined modulation method, and transmitted as a modulated signal (d). Further, in the receiving circuit shown in FIG. 6, the received signal (m) is input to the detection circuit 64,
The demodulation symbol (n) is output. In the soft decision circuit 65,
A soft decision is performed on the demodulated symbol (n) and a soft decision value (p) is output. The deinterleave circuit 66 deinterleaves the soft decision value (p) and outputs a deinterleave signal (q). Error correction decoding circuit 6
In 7, error correction decoding is performed using the deinterleaved signal (q), and data (r) is output.

As described above, in the conventional error correction transmission / reception circuits shown in FIGS. 5 and 6, error correction coding is performed on the transmission side and error correction decoding is performed on the reception side, so that on the wireless transmission path. It is possible to correct the generated error and perform high quality wireless communication.

[0007]

As described above, since the wireless communication system using the error correction system can correct the error generated on the wireless transmission line, a high quality wireless communication system is constructed. it can. However, when an interference wave with a very high transmission power is added to the transmission frequency, even if the error correction code is used, it will be greatly affected. For example, there is a problem that continuous burst errors occur in a section where interference is added. This problem is not limited to the access method in which signals are continuously transmitted, but also CSMA / CA (Carrier Sense Multiple Access / Collis) used in packet communication.
Ion Avoidance) Even when transmission is performed intermittently, such as in a communication system, the same problem occurs.

[0008] The CSMA / CA communication system is a system for transmitting packets, and is a best-effort type wireless access system for observing a desired transmission frequency for each transmission packet and measuring whether or not it can be used before transmission. Used frequently.

In the CSMA / CA communication system, a desired transmission frequency can be observed before transmission, and a packet can be transmitted unless another station is transmitting. Immediately after the packet transmission of a certain wireless station is completed and the wireless channel is changed from busy (in use) to idle (empty), the collision probability of simultaneous packet transmission by a plurality of wireless stations whose transmission is suspended becomes high. In order to reduce this, each wireless station stops transmission for a random time, and transmits a packet after confirming that the channel is idle after the lapse of this random time.

When the packet time length to be transmitted is long, or when the interference wave is a pulse signal, CSMA / CA
The communication system is significantly affected. In the CSMA / CA communication method, a packet is transmitted when it is determined that the transmission frequency is vacant, but since the interfering station transmits a pulse signal at a cycle with an arbitrary transmission interval, a packet with a long time length is transmitted. When the packet is transmitted, it is determined that the channel is empty, and a pulse of an interference wave is transmitted during the transmission period during which the packet is being transmitted, which causes a problem of collision with the packet.

When collisions occur, burst errors occur frequently, and even if an error correction code is used, the effect is significant. Also, in this case, the packet does not reach the partner station, so the retransmission function of the upper layer operates, which causes additional problems such as a decrease in throughput. Interfering station seen from the CSMA / CA communication method side. The problem of being interfered arises.

On the contrary, from the standpoint of the station transmitting the interference wave, when transmitting by the intermittent pulse signal, the packet is transmitted based on the CSMA / CA communication system and the collision occurs. If this happens, this pulse signal will not be received in the correct form by the other station, and the packet signal becomes an interference wave for the interfering station. Therefore, CSMA /
As seen from the CA communication system side, there arises a problem of interference that causes deterioration of characteristics on the interfering station side. As one example that must be taken into consideration when such a communication method for performing continuous or intermittent communication and an interference wave coexist at the same frequency, there are a base station and a fixed subscriber station outdoors. Fixed wireless access (FWA) can be considered.
Outdoors, various interference waves exist, and the cycle of the transmission signal and the transmission interval also fluctuate. Therefore, it is desired to apply the CSMA / CA communication method that can control the transmission timing according to the transmission path environment.

In FWA, CS is also used as an access method.
The application of the MA / CA communication method is being studied. However, as described above, when an interference wave that transmits a pulse signal is added at an arbitrary transmission interval, mutual influences are large. One of the interference sources is a weather radar. The transmission power of the meteorological radar is very large, about 250 kW (about 8
4 dBm). Moreover, the weather radar uses a parabolic antenna having a sharp directivity while rotating it at a constant cycle, and transmits a pulse having a time length of several microseconds to the target several hundreds of times per second, and the reflected wave. The target is accurately captured by receiving and averaging. In this way, the radar wave has a large transmission power and is transmitted so that intermittent pulse waves form a swarm, so that the effects of both interference and interference are significant.

As described above, conventionally, when an interference wave of large transmission power exists at the same frequency with which a communication station wants to communicate,
There is a problem that high-quality communication cannot be performed because the number of bit errors due to interference waves increases and it is difficult to reduce even if error correction codes are used. In addition, when the communication station and the interfering station use the same frequency, it is also a problem that the interfering station side suppresses the influence of the interference.

The present invention has been made in view of the above circumstances, and is a transmitting station used in an access system such as CSMA / CA or a communication system for continuous transmission and an interfering station represented by a weather radar. The difference in transmission power between
Further, the interference wave is periodically transmitted because it is transmitted from the rotating antenna, and the fact that the interference wave is transmitted as a pulse signal is used to (1) detect the transmission period of the interference liquid. (However, when the interference wave arrives at the communication station as a group of pulse signals, the transmission period of the group is used as the transmission period.) (2) When it is determined that the interference wave is transmitted, the transmission is stopped. (3) If it is determined that the interference wave is transmitted, reduce the coding rate of the error correction code, and (4) measure the reception sensitivity of the interference wave and increase the error correction code as the reception sensitivity increases. Even if an error correction code is used even if an error correction code is used when an interference wave is added, it occurs on the wireless transmission line by reducing the coding rate of It becomes difficult to reduce bit errors Provided is an error correction transmission circuit in a wireless communication system, which solves the problem and also stops the transmission when it is determined that an interference wave is transmitted, thereby solving the problem of interference given to the interference station side. The purpose is to

When the period during which the interference wave pulse is transmitted is detected, the soft decision value is changed to a value that does not affect the likelihood, and the effect of the interference wave pulse on the error correction decoding is suppressed. Thus, it is another object of the present invention to provide an error correction receiving circuit in a wireless communication system that solves the problem that it is difficult to reduce errors even if an error correction code is used when an interference wave is added. Thus, in the presence of an interference wave of high transmission power, the effect of increasing bit errors due to the interference wave is mitigated, and the effect of interference from the interference wave that is difficult to mitigate even with the use of error correction codes is suppressed. Another object of the present invention is to provide an error correction transmitting circuit and a receiving circuit in a wireless communication system, which realizes a high quality wireless communication system capable of suppressing the influence of interference on the interfering station side.

[0017]

In order to solve the above-mentioned problems, an error correction transmitting circuit in a wireless communication system according to claim 1 is an error correction device for error-correcting coding transmission data and outputting a coded data signal. A coding circuit, a modulation circuit that modulates the output of the error correction coding circuit, an interference wave detection circuit that receives an interference wave signal and detects a transmission period during which the interference wave signal is transmitted, and the error correction A control signal is provided between the coding circuit and the modulation circuit, which generates a control signal for stopping the transmission of the error correction coding circuit output for a certain period over the period indicated by the output of the interference wave detection circuit, and performs the modulation. And a transmission control circuit for supplying the circuit. With the above configuration, a period in which the reception sensitivity of an interference wave periodically transmitted with a large transmission power is high is detected, and during that period, the error correction coded signal is controlled so as not to be transmitted. It is possible to avoid the influence of errors that could not be reduced even by using the correction code. Also, by controlling the transmission to be stopped during the period when the reception sensitivity of the interference wave is high, it is possible to reduce the error from the interfering station and suppress the interference to the interfering station. The high quality wireless communication used can be realized.

An error correction transmission circuit in a radio communication system according to claim 2, wherein an interference wave signal is input, an interference wave signal level detection circuit for detecting a reception signal level of the interference wave signal, and the interference wave signal. A multi-stage threshold circuit that outputs each of the threshold information signals when the output of the level detection circuit is obtained as an input signal and the preset input signals sequentially exceed a plurality of preset thresholds over time, and the multi-stage threshold circuit. Output as an input, an interference wave transmission period detection circuit for detecting the transmission period for each received signal level of the interference wave according to the threshold information signal, in addition to the transmission data,
Obtaining the output signal of the multi-stage threshold circuit and the interference wave transmission period detection circuit as an input, according to the output signal of the multi-stage threshold circuit, error correction coding is performed on the transmission data at each coding rate, A coding rate variable error correction coding circuit that generates and outputs an error correction coding signal over each period according to an output signal of the interference wave transmission period detection circuit, the coding rate error correction coding circuit, and the plurality of coding rate error correction coding circuits. Each output signal of the stage threshold circuit and the interference wave transmission period detection circuit is obtained as an input, and when the threshold information signal of a specific threshold value or more is input, transmission data of the transmission data is output according to the output signal of the interference wave transmission period detection circuit A transmission control circuit for generating a control signal for stopping the output for a certain period is provided. With the above configuration, it is possible to detect the reception sensitivity of the interference wave periodically transmitted with the high transmission power in stages, and adaptively change the coding rate when performing error correction coding according to each stage to reduce the coding rate. Error correction coding is performed at the coding rate. Specifically, by performing an operation in which the coding rate decreases as the influence of the interference wave increases, the error correction capability of the signal expected to increase the influence of the interference wave and increase the error will be improved. This makes it possible to reduce the errors increased by the interference wave. In addition, by performing control to stop transmission in the period when the reception sensitivity of the interference wave is high, errors from the interference wave are reduced,
In addition, it reduces interference with interfering stations. From the above operation, it is possible to realize high quality wireless communication using the improvement effect of the error correction code. By performing such an operation, it is possible to realize high quality wireless communication using the improvement effect of the error correction code.

The error correction transmission circuit in the radio communication system according to claim 3 receives an interference wave signal as an input,
The interference wave detection circuit for detecting the transmission period during which the interference wave signal is transmitted, and the output of the interference wave detection circuit is obtained as an input, over the period indicated by the output signal of the interference wave detection circuit, in the transmission data. On the other hand, with the above-described configuration including a variable coding rate error correction coding circuit that performs error correction coding at a low coding rate, the reception sensitivity of an interference wave periodically transmitted at high transmission power is high. It is possible to detect the following period and adaptively change the coding rate in the case of performing the error correction coding during that period to perform the error correction coding at a low coding rate. Therefore, the error correction capability of a signal that is expected to increase in error due to the addition of the interference wave is improved, and the error increased by the interference wave can be reduced. By performing such an operation, it is possible to realize high-quality wireless communication utilizing the improvement effect of the error correction code.

The error correction transmission circuit in the radio communication system according to claim 4 is any one of claims 1 to 3.
In the same circuit as described in the paragraph, an interference wave that estimates a repetition cycle or a transmission period for an interference wave that is repeated at a constant cycle and outputs a transmission period signal that indicates the transmission period based on this estimated value. It was decided to provide a detection circuit.
Also with the above configuration, it is possible to detect or estimate the period during which the reception sensitivity of the interference wave periodically transmitted with the high transmission power is high, and adaptively change the coding rate during error correction coding during that period. Error correction coding can be performed at a low coding rate. Therefore, the error correction capability of a signal that is expected to increase in error due to the addition of the interference wave is improved, and the error increased by the interference wave can be reduced.

An error correction receiving circuit in a radio communication system according to claim 5 performs a soft decision by obtaining a detection circuit for detecting a received signal and an output signal of the detection circuit as inputs, and the soft decision value. A soft-decision circuit that outputs, and an output signal of the soft-decision circuit as an input, an error correction decoding circuit that performs error correction decoding, and an interference wave pulse signal as an input, and the interference wave pulse signal is transmitted. Between the interference wave pulse position detection circuit for detecting a period during which the soft decision value is output and the soft decision value output from the interference wave signal position detection circuit is supplied between the soft decision circuit and the error correction decoding circuit. In the period in which the output of the interference wave signal position detection circuit is input, a soft decision value null signal insertion circuit that rewrites the soft decision value to a value indicating zero likelihood is provided. Further, the error correction receiving circuit in the wireless communication system according to claim 6 is the same circuit according to claim 5, wherein the interference wave pulse repeated at a constant cycle has a repetition cycle or a transmission period. And then
An interference wave pulse position detection circuit that outputs a transmission period signal indicating the transmission period based on this estimated value is provided. With the above configuration, the operation of detecting or estimating the interference wave pulse period that is periodically transmitted with high transmission power and replacing the soft decision value of the demodulated signal received during that period with 0 is performed. When the interference wave pulse is added to the received signal, the soft decision value is greatly affected, and it is considered that the soft decision value is largely incorrect from the correct likelihood. Therefore, when performing maximum likelihood estimation, the soft decision value at the time of receiving the interference wave pulse does not affect the preceding and subsequent bits so that the wrong soft decision value does not affect the estimation values of other bits. Maximum likelihood estimation is performed by substituting the likelihood value. By performing the above operation, it is possible to improve the error correction capability of a signal in which an interference wave is added and an error is expected to increase, and it is possible to reduce the error increased by the interference wave. Therefore, it is possible to realize high-quality wireless overreliance using the effect of improving the error correction code.

According to the present invention, with the above-described configurations, in the presence of an interference wave of high transmission power, the influence of an increase in bit errors due to the interference wave is mitigated, and even if an error correction code is used, it is difficult to reduce the interference. Suppress the effects of interference from waves, or
It is possible to provide a transmitting / receiving circuit that realizes a high-quality wireless communication system capable of suppressing the influence of interference on the interfering station side.

[0023]

1 is a block diagram showing an embodiment of a transmission circuit in a wireless communication system of the present invention. The transmission circuit in the wireless communication system of the present invention includes an error correction coding circuit 11, an interleave circuit 12,
It is composed of a modulation circuit 13, an interference wave detection circuit 14, and a transmission control circuit 15.

In the embodiment shown in FIG. 1, the transmission data (a) is input to the error correction coding circuit 11, is subjected to error correction coding, and outputs a coded data signal (b). The interleave circuit 12 receives the encoded data signal (b) and outputs the interleave signal (c) by performing interleaving. On the other hand, the interference signal (e) is input to the interference signal detection circuit 4,
Here, the transmission period of the interference signal is detected, and the control signal (f) indicating the transmission period of the interference signal is output. In the embodiment of the present invention shown here, the case where the transmission period of the interference signal is detected has been described, but for interference that is repeated at a constant period, the repetition period and the transmission period are estimated, and this estimation is performed. Transmission period signal (f) indicating the transmission period based on the value
It is naturally possible to output.

The interleave signal (c) and the transmission period signal (f) are input to the transmission control circuit 15, and during the period in which the interference signal indicated by the control signal is being transmitted, the transmission control interleave signal ( Do not output g). This is a feature of the embodiment of the present invention, and is realized by the interference signal detection circuit 14 and the transmission control circuit 15. The modulation circuit 13 performs modulation using the transmission control interleave signal (g) and outputs the transmission signal (d).

FIG. 2 is a block diagram showing another embodiment of the transmission circuit in the wireless communication system of the present invention. The transmission circuit in the wireless communication system of the present invention includes an interleave circuit 22, a modulation circuit 23, and a transmission control circuit 25.
A variable coding rate error correction coding circuit 26, an interference wave signal level detection circuit 27, and an interference signal multi-stage threshold circuit 28.
And an interference wave transmission period detection circuit 29.

In the embodiment shown in FIG. 2, the interference signal (e) is input to the interference wave signal level detection circuit 27,
Here, the reception sensitivity of the interference wave signal is measured, and the reception sensitivity signal (h) is output. In the interference signal multi-stage threshold circuit 28,
A plurality of thresholds are set, and when the thresholds are exceeded, the level signal (i) corresponding to the reception sensitivity signal is output. The interference wave transmission period detection circuit 29 detects the transmission period of each interference wave signal according to the output signal of each level, and outputs the transmission period signal (j). In the embodiment shown here, the case of detecting each transmission period of each level of the interference signal has been shown, but for interference such as being repeated at a constant period, each repetition period or transmission period is estimated, It is naturally conceivable to output the transmission period signal (j) indicating the transmission period based on this estimated value.

The transmission data (k) is the level signal (i),
It is input to the coding rate variable error correction coding circuit (f) together with the transmission period signal (j), the coding rate is determined according to the level signal (i), and the coding is performed over the transmission period indicated by the transmission period signal (j). Error correction coding is performed with the changed coding rate. Specifically, a method of reducing the coding rate as the reception sensitivity of the interference wave increases can be considered. The encoded data signal (l) is input to the interleave circuit 22 and, as a result, the interleave signal (c) is output. In the transmission control circuit 25, when an interference wave signal power equal to or higher than a preset threshold value indicated by the level signal (i) with respect to the interleave signal (c) is input,
The transmission is stopped for the time indicated by the transmission period signal (j) corresponding to the level. Specifically, when the transmission period signal (j) indicating the period in which the interference wave is received most strongly is input, the transmission stop control is performed and the transmission is stopped.

The above description is a characteristic part of the embodiment of the present invention shown in FIG.
7, an interference signal multi-stage threshold circuit 28, an interference wave transmission period detection circuit 29, a variable coding rate error correction coding circuit 26, and a transmission control circuit 25. The modulation circuit 23 performs modulation using the transmission control interleave signal (g),
The transmission signal (d) is output.

FIG. 3 is a block diagram showing still another embodiment of the transmission circuit in the wireless communication system of the present invention. The transmission circuit in the wireless communication system of the present invention includes an interleave circuit 32, a modulation circuit 33, an interference wave detection circuit 34, and a variable coding rate error correction coding circuit 36.

In the embodiment shown in FIG. 3, the interference wave signal (e) is input to the interference wave detection circuit 34, where the transmission period of the interference wave signal is detected and the transmission period indicating the transmission period of the interference wave signal. The signal (f) is output. Here, the case where the transmission period of the interference wave signal is detected has been described. However, similar to the embodiments shown in FIGS. 1 and 2, for an interference wave that is repeated at a constant cycle, the cycle of spelling and transmission are repeated. It is naturally conceivable to estimate the period of and output the transmission period signal (f) indicating the transmission period based on this estimated value.

The transmission data (a) is the transmission period signal (f).
It is input to the variable coding rate error correction coding circuit 36 together with it, and during the period indicated by the transmission period signal (f), error correction coding with a lower coding rate is performed, and the output of the coded data (b) is output. Done. This is the feature of the embodiment of the present invention shown in FIG. 3, which is realized by the interference wave detection circuit 34 and the variable coding rate error correction coding circuit 36. The encoded data signal (b) is input to the interleave circuit 32, where interleaving is performed and the interleave signal (c) is output. The modulation circuit 33 performs modulation using the interleaved signal (c) and outputs a transmission signal (d).

FIG. 4 is a block diagram showing an embodiment of a receiving circuit in the wireless communication system of the present invention. The reception circuit in the wireless communication system of the present invention includes an interference signal pulse position detection circuit 44, a detection circuit 51, a soft decision circuit 52, a soft decision value null signal insertion circuit 53, a deinterleave circuit 54, and an error correction decoding. It is composed of a circuit 55.

In the embodiment shown in FIG. 4, the received signal (m) is input to the detection circuit 51, where the detection is performed and the demodulated signal (n) is output. In the soft decision circuit 52, the demodulated signal (n) is input, the soft decision is performed here, and the soft decision value (o) is output. On the other hand, the interference pulse signal (e) is input to the interference signal pulse position detection circuit 44, where the pulse position period is detected and the transmission period signal (f) is output. In the embodiment shown here, similar to the embodiments shown in FIGS. 1 to 3, the case where the interference pulse signal period is detected has been described. However, in the case of interference that is repeated at a constant cycle, a repetition cycle or a transmission cycle It is naturally conceivable to estimate the period and output the transmission period signal (f) indicating the transmission period based on this estimated value.

Soft decision value signal (o) and transmission period signal (f)
Is input to the soft decision value null signal insertion circuit 53, and the soft decision value of the signal received in the period indicated by the transmission period signal is set to NULL.
Corrected soft decision value signal (p)
Is output. This portion is a feature of the embodiment shown in FIG. 4, and the interference signal pulse position detection circuit 4
4. It is realized by the soft decision value null signal insertion circuit 53.
The corrected soft decision value (p) is input to the deinterleave circuit 54, deinterleaved here, and the deinterleaved corrected soft decision value signal (q) is output. The deinterleaved soft decision value signal (q) is input to the error correction decoding circuit 55, where error correction decoding is performed and output data (r) is obtained.

As described above, the present invention is based on the CSMA / C
The transmission power difference between the transmitting station used in the access method such as A or the communication method that continuously transmits and the interfering station represented by the weather radar is large, and the interference wave is transmitted from the rotating antenna. To detect the transmission period of the interfering liquid (1) by utilizing the fact that the interference wave is transmitted as a pulse signal.
When the interference wave arrives at the communication station as a group of pulse signals, the transmission period is the passing period of the group), (2) when the interference wave is determined to be transmitted, the transmission is stopped, (3) If it is determined that the interference wave is transmitted, reduce the coding rate of the error correction code, and (4) measure the reception sensitivity of the interference wave and encode the error correction code as the reception sensitivity increases. By reducing the rate and stopping the transmission during the period when the reception sensitivity of the interference wave becomes the highest or higher than the set value, even if the error correction code is used when the interference wave is added, the bit error generated on the wireless transmission line It solves the problem of difficulty in mitigation, and also solves the problem of interference given to the interfering station side by stopping transmission when it is determined that an interference wave is being transmitted.

When the period in which the interference wave pulse is transmitted is detected, the soft decision value is changed to a value that does not affect the likelihood, and the effect of the interference wave pulse on the error correction decoding is suppressed. Thus, even if an error correction code is used when an interference wave is added, it is possible to solve the problem that it is difficult to reduce the error. In this way, even if there is an interference wave of high transmission power, the effect of increasing bit errors due to the interference wave is mitigated, and the effect of interference from the interference wave, which is difficult to mitigate even with error correction codes, is suppressed. Alternatively, a high-quality wireless communication system capable of suppressing the influence of interference on the interfering station side is realized. In the embodiment of the present invention, the transmission circuit and the reception circuit are described as being independent, but they may be integrated and realized. Further, although it is general to detect the transmission period of the interference wave and the interference pulse period described above, -for interference that is repeated at a fixed period, estimate the repetition period and the transmission period. It is naturally conceivable to use the estimated signal of the transmission period or the interference wave pulse period based on this estimated value. In this case, the same effect can be obtained.

[0038]

As described above, according to the present invention, even if there is an interference wave of high transmission power, the effect of increase in bit errors due to the interference wave is mitigated, and mitigation is difficult even if an error correction code is used. It is possible to suppress the influence of interference from various interference waves or the influence of interference on the interfering station side as much as possible. This makes it possible to provide an error correction transmitting / receiving circuit that realizes a high-quality wireless communication system. Further, in the receiving circuit of the present invention, when the period during which the interference wave pulse is transmitted is detected or estimated, the soft decision value is changed to a value that does not affect the likelihood, and the interference wave that affects error correction decoding is changed. By suppressing the influence of the pulse, it is possible to solve the problem that it is difficult to reduce even if an error correction code is used when an interference wave is added.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an error correction transmission circuit in a wireless communication system of the present invention.

FIG. 2 is a block diagram showing another embodiment of an error correction transmission circuit in the wireless communication system of the present invention.

FIG. 3 is a block diagram showing still another embodiment of the error correction transmission circuit in the wireless communication system of the present invention.

FIG. 4 is a block diagram showing an embodiment of an error correction receiving circuit in the wireless communication system of the present invention.

FIG. 5 is a block diagram showing a configuration example of an error correction transmission circuit in a conventional wireless communication system.

FIG. 6 is a block diagram showing a configuration example of an error correction receiving circuit in a conventional wireless communication system.

[Explanation of symbols]

11 ... Error correction coding circuit, 12 (22, 32) ... Interleave circuit, 13 (23, 33) ... Modulation circuit, 14
(34) ... Interference wave detection circuit, 15 (25) ... Transmission control circuit, 26 ... Coding rate variable error correction coding circuit, 27 ... Interference wave signal level detection circuit, 28 ... Interference signal multi-stage threshold circuit, 29 ... Interference wave transmission period detection circuit, 36 ... Variable coding rate error correction coding circuit, 44 ... Interference signal pulse position detection circuit, 51 ... Detection circuit, 52 ... Soft decision circuit, 53 ... Soft decision value null signal insertion circuit, 54 … Deinterleave circuit,
55 ... Error correction decoding circuit

Front page continuation (72) Inventor Tetsuya Shiramizu 2-3-1, Otemachi, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Inventor Mitsuhiro Baba 2-3-1, Otemachi, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation Telephone Corporation (72) Inventor Noriyuki Nagamatsu 2-3-1, Otemachi, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation (56) Reference JP-A-6-37762 (JP, A) JP-A-7- 222245 (JP, A) JP-A-11-150530 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04B 1/04 G06F 11/10 330 H03M 13/23 H04L 1/00

Claims (6)

(57) [Claims] 1. An error correction coding circuit for error correction coding transmission data and outputting a coded data signal, a modulation circuit for modulating the output of the error correction coding circuit, and an interference wave signal for receiving the interference signal. An interference wave detection circuit that detects a transmission period in which a wave signal is transmitted, and is provided between the error correction coding circuit and the modulation circuit, and is provided over the period indicated by the output of the interference wave detection circuit. An error correction transmission circuit in a wireless communication system, comprising: a transmission control circuit that generates a control signal for stopping transmission of an error correction coding circuit output for a certain period and supplies the control signal to the modulation circuit. 2. An interference wave signal is input, an interference wave signal level detection circuit for detecting a reception signal level of the interference wave signal, and an output of the interference wave signal level detection circuit is obtained as an input signal, and the input signal is When a plurality of preset thresholds are sequentially exceeded over time, a multi-stage threshold circuit that outputs each threshold information signal and an output of the multi-stage threshold circuit are obtained as inputs, and in accordance with each of the threshold information signals. An interference wave transmission period detection circuit for detecting a transmission period for each reception signal level of the interference wave, and in addition to the transmission data, the output signal of the multi-stage threshold circuit and the interference wave transmission period detection circuit is obtained as an input, According to the output signal of the multi-stage threshold circuit, error correction coding is performed on the transmission data at each coding rate, and the error correction coding is performed for each period according to the output signal of the interference wave transmission period detection circuit. A variable coding rate error correction coding circuit for generating and outputting an error correction coded signal, and the output signals of the coding rate error correction coding circuit, the plurality of threshold circuits, and the interference wave transmission period detection circuit. And a transmission control circuit that generates a control signal that stops the output of transmission data for a certain period according to the output signal of the interference wave transmission period detection circuit when a threshold information signal that is obtained as an input and is equal to or greater than a specific threshold value is input. An error correction transmission circuit in a wireless communication system, comprising: 3. An interference wave detection circuit that receives an interference wave signal as an input and detects a transmission period during which the interference wave signal is transmitted, and an output of the interference wave detection circuit as an input, and the interference wave detection circuit Error correction coding circuit for performing error correction coding on transmission data at a low coding rate over a period indicated by the output signal of Transmitter circuit. 4. An interference wave detection circuit for estimating a repetition cycle or a transmission period for an interference wave repeated at a constant cycle and outputting a transmission period signal indicating the transmission period based on the estimated value. The error correction transmission circuit in the wireless communication system according to claim 1, further comprising: 5. A detection circuit that detects a received signal, a soft decision circuit that performs a soft decision by obtaining an output signal of the detection circuit as an input, and outputs the soft decision value, and an output signal of the soft decision circuit. , An error correction decoding circuit for performing error correction decoding, and an interference wave pulse position detection circuit for receiving the interference wave pulse signal as an input and detecting a period during which the interference wave pulse signal is transmitted, A period during which the interference wave signal position detection circuit output and the soft decision value which is the soft decision circuit output are supplied between the soft decision circuit and the error correction decoding circuit, and the interference wave signal position detection circuit output is input. Then, a soft decision value null signal insertion circuit for rewriting the soft decision value to a value indicating that the likelihood is zero, the error correction receiving circuit in a wireless communication system. 6. An interference wave pulse position for estimating a repetition cycle or a transmission period for an interference wave pulse repeated at a constant cycle and outputting a transmission period signal indicating the transmission period based on the estimated value. The error correction receiving circuit in a wireless communication system according to claim 5, further comprising a detection circuit.