JP2002101006A - Receiver and transmitter used for spread spectrum communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To secure proper communicating state by eliminating the occurrence of failures, such as the data transfer failure, drop in throughput, etc., in a communication channel having poor communication quality. SOLUTION: A transmitter (receiver) used for a spread spectrum communication system is provided with a correlation/synchronization discriminating section 14, which discriminates synchronization between received spread-spectrum signals and spread- spectrum codes by computing the correlation between the signals and codes, an RSSI value detecting section 13 which detects the field intensity of the received signals, and a BER measuring section 18 which measures the BER of the received signals. The transmitter (receiver) is also provided with an interface section 11 for a terminal, which discriminates the quality of the currently used communication channel, based on the results obtained by means of the sections 13, 14, and 18. Since the BER is taken into consideration at discriminating of the quality of the communication channel, the presence/absence of disturbing waves and noise which arrive from other channels and can not be discriminated by the conventional synchronization discrimination, and RSSI value detection only can be discriminated. When the quality of the communication channel is poor, the communication quality is secured by moving the communication channel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spread spectrum communication system for performing data communication using a spread spectrum communication system, which can maintain a good communication state in which no communication failure occurs. The present invention relates to a receiving device and a transmitting device used.

[0002]

2. Description of the Related Art In a conventional spread spectrum communication system, signals are transmitted and received, for example, using a terminal device having the configuration shown in FIG. In this terminal device, an antenna 51 is connected to a transmission side circuit 53 via a transmission / reception switch 52.
Alternatively, it is connected to the receiving circuit 54. The transmission side circuit 53 includes a transmission encoding processing unit 55 and a spreading processing unit 5.
6 and a modulator 57.
Is composed of a demodulator 58, a despreading processing unit 59, and a reception encoding processing unit 60. In addition, the terminal device further includes a terminal interface unit 61, an amplifier / detection unit 62, and an RSSI (Received Signal Strength).
th Indicator) detection unit 63 and correlation / synchronization determination unit 64
, An AND circuit 65, and a control unit 66.

The transmission signal is transmitted to a terminal interface unit 6.
1 is input to the transmission encoding processing unit 55 of the transmission-side circuit 53, where various header signals are added to the signal.
Thereafter, the transmission signal is frequency-spread using a spreading code (for example, a PN code) in a spreading processing unit 56, modulated into a high-frequency signal in a modulator 57, and transmitted via an antenna 51.

FIG. 10 shows the configuration of the transmission signal (data). The data includes a header part and a user data part. The MPDU in the user data section is data sent from the terminal interface section 61. Further, the ID code of the terminal device on the transmission side is also added to the user data portion.
On the other hand, the header part includes SYNC, SFD, and SIGN
It consists of AL, SERVICE, LENGTH, and CRC.

[0005] SYNC is a synchronous field pattern, which is an IEEE (Institute of Electrical and Electron).
ics Engineers) compatible data or "10" repetition pattern (both 128 bits). SFD is
This is a frame synchronization signal, and is SFD16 (16 bits) or SFD31 (31 bits). SIGN
AL is data that specifies the modulation scheme of the MPDU.
SERVICE is option data for which no particular use is specified. LENGTH indicates the bit length of the data used for the header part. CRC (Cyclic Redun
dancy Check) is a CRC-FCS (FrameCheck Sequence) added for checking data in the header part.
e) Parity.

Next, a case where a high-frequency signal transmitted from a transmitting-side terminal device is received by the terminal device of FIG. 9 will be described with reference to a flowchart of FIG.

First, the high-frequency signal is input to a demodulator 58 of a receiving circuit 54 via an antenna 51 and a transmission / reception switch 52. The demodulator 58 demodulates the input high-frequency signal into a baseband signal. After that, the baseband signal is despread by a despreading processing unit 59, and then as an original data sequence.
Is input to

On the other hand, an amplifier / detector 62 amplifies and detects a signal received via the antenna 51 and the transmission / reception switch 52. Then, the RSSI detecting section 63 detects an RSSI value indicating the strength of the received signal (SSI).
101). Here, from the RSSI detection unit 63, when the detected RSSI value is larger than a predetermined threshold, A
While “1” is output to the ND circuit 65, the detected R
When the SSI value is equal to or smaller than the threshold, “0” is output to the AND circuit 65.

Next, the correlation / synchronization determination section 64 determines the synchronization of the correlation between the received spread spectrum signal and the spread code (S102). From the correlation / synchronization determination unit 64,
When the two are synchronized, "1" is output to the AND circuit 65. When the two are not synchronized, A is output.
“0” is output to the ND circuit 65.

In the AND circuit 65, the RSSI detector 63
Is ANDed with the output from the correlation / synchronization determination unit 64 (S103), and the result is input to the control unit 66. Only when the output from the AND circuit 65 is "1", the control unit 66 generates a flag indicating that reception is possible (S104). Terminal interface 61
Determines whether the received signal is a valid signal based on the flag generated by the control unit 66. If the received signal is a valid signal, the following processing is further performed.

[0011] The reception encoding processing section 60 checks the ID code of the received signal and checks the CRC-FCS parity (S105). At this time, CRC-FCS
If there is no error in the parity, the reception encoding processing unit 60
Outputs “0” to the terminal interface unit 61. In this case, the terminal interface unit 61 determines that a correct signal has been received, and ends a series of processing (S
106, S107). On the other hand, when there is an error in the CRC-FCS parity, “1” is output from the reception encoding processing unit 60 to the terminal interface unit 61. In this case, the terminal interface unit 61 determines that the received data is invalid, and requests the transmitting terminal device corresponding to the ID code to retransmit the data (S106, S108).

As described above, in the conventional spread spectrum wireless communication system, if the RSSI value indicating the receivable radio field strength is larger than the predetermined threshold value on the receiving side and the correlation of the correlation can be established by the despreading operation, It determines that communication is possible on the currently used channel, and executes data transmission.
Then, on the receiving side, after checking the CRC-FCS parity check of the header part and the ID code of the user data part, it judges whether the data is correct or not, and when the data is not correct, requests retransmission of the data. ARQ (auto
matic repeat request) is adopted as a communication system.

[0013]

By the way, in the above-mentioned spread spectrum communication system, even when the S / N ratio of the communication channel is deteriorated or the jamming radio wave exists in a nearby channel, the RSSI value is good. In addition to showing the same value as in the normal reception state, the synchronization of the correlation is established without any problem. For this reason, even in such an environment, the correctness / incorrectness of the received data is determined as usual.

However, in the above environment, the bit error rate (the ratio of the number of erroneous data to the total number of data transmitted: hereinafter, referred to as BER) increases, so that the validity / absence judgment is invalid. The number of received data to be judged increases, and data retransmission requests frequently occur. As a result, the number of cases in which data transmission fails is increased, and the time required for data transmission is extremely increased, resulting in a significant decrease in throughput.

In the future, when spread spectrum communication systems become widespread and a plurality of networks are used in close proximity, or when the number of Bluetooth devices using the same frequency band as the spread spectrum communication system increases, spread spectrum communication will increase. Since it is easily considered that the quality of the frequency band usable in the system is deteriorated, improvement of the throughput is urgently required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to improve a data transfer failure and a problem of a decrease in throughput, and to provide a spectrum capable of always performing good data communication. An object of the present invention is to provide a receiving device and a transmitting device used in a spread communication system.

[0017]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problem, a receiving apparatus used in a spread spectrum communication system according to the present invention is a synchronous apparatus which determines synchronization by performing a correlation operation between a received spread signal and a spread code. Determining means, intensity detecting means for detecting the radio field intensity (hereinafter, referred to as RSSI value) of the received signal, bit error rate measuring means for measuring the bit error rate (hereinafter, referred to as BER) of the received signal, Control means for determining the quality of a communication channel currently used as a communication channel based on the results obtained by the synchronization determination means, the intensity detection means and the bit error rate measurement means. Features.

According to the above arrangement, the synchronization determination result by the synchronization determination means and the R detected by the intensity detection means are determined.
Based on not only the SSI value but also the BER measured by the bit error rate measuring means, the quality of the channel currently communicating is determined by the control means. In determining the quality of such a communication channel, the above configuration considers the BER, so that the presence / absence of interfering waves and noise from other channels cannot be determined only by the conventional synchronization determination and RSSI value detection. Can be determined. If there is the above interfering wave, etc.,
This is because the ER becomes worse.

Therefore, the control means can accurately judge the quality of the channel on which communication is currently being performed. If the quality of the communication channel is poor, for example, the communication channel is moved to another channel. By doing so, it is possible to take measures to ensure better communication quality. As a result, it is possible to suppress the occurrence of a communication error and a decrease in throughput in a channel with poor communication quality, and maintain a communication state with good communication quality.

In order to solve the above problems, the receiving apparatus used in the spread spectrum communication system according to the present invention is arranged so that the control means has a bit error rate of a received signal in a current communication channel larger than a threshold value, and When the radio wave intensity of the received signal in the adjacent channel is higher than the radio wave intensity of the received signal in the communication channel, control is performed such that communication is performed on a channel other than the adjacent channel.

The BER in the current communication channel is larger than the threshold value, and the R in the adjacent channel is
When the SSI value is larger than the RSSI value in the communication channel, it can be said that the influence of the interference wave from the adjacent channel is strong. In such a case, the control means controls communication to be performed on a channel other than the adjacent channel, so that good communication can be performed on a channel in which a communication failure does not occur.

The receiving apparatus used in the spread spectrum communication system according to the present invention further comprises storage means for storing the radio wave intensity and the bit error rate of the received signal in all communication channels in order to solve the above problems. The control means performs control for selecting a communication channel based on the contents stored in the storage means.

According to the above configuration, if the RSSI value and BER in all communication channels are measured and the results are stored in the storage means, the control means can read the communication status in all communication channels from the storage contents of the storage means. Can be grasped immediately. Therefore, for example, at the time of the next communication, the control means can store the RSSI value stored in the storage means and B
A channel suitable for communication can be selected in a short time based on the ER, and good communication can be performed on the selected communication channel.

[0024] The receiving apparatus used in the spread spectrum communication system according to the present invention further comprises display means for displaying the radio wave intensity and the bit error rate of the received signal in all communication channels in order to solve the above problems. It is characterized by having.

According to the above configuration, the RSSI value and the BER in all communication channels are displayed on the display means.
It is possible to visually notify the user of the communication state in each communication channel, and it is possible to make the spread spectrum communication system easier to use.

A transmitting apparatus used in a spread spectrum communication system according to the present invention is a transmitting apparatus used in a spread spectrum communication system for performing spread spectrum processing on communication data and transmitting the processed data to a receiving apparatus in order to solve the above problems. And a bit error rate measuring signal generating means for generating a bit error rate measuring signal used for measuring the bit error rate of the received signal in the receiving apparatus.

According to the above configuration, if the bit error rate measuring signal generated by the bit error rate measuring signal generating means is added to the transmission signal and transmitted to the receiving device, the receiving device can receive the bit error rate signal. The bit error rate (BER) can be measured using the error rate measurement signal. This allows the receiving apparatus to determine the synchronization between the spread signal and the spread code and to determine the radio field strength (R
It is possible to determine the presence or absence of an interfering wave or noise from another communication channel, which could not be determined only by the SSI value). If there is the above interfering wave, etc., BE
This is because R deteriorates.

Therefore, it is possible for the receiving apparatus to accurately judge the quality of the currently communicating channel. If the quality of the communication channel is poor,
For example, it is possible to take measures to ensure better communication quality by moving a communication channel to another channel. As a result, it is possible to suppress the occurrence of a communication error and a decrease in throughput in a channel with poor communication quality, and maintain a communication state with good communication quality.

In order to solve the above-mentioned problems, the transmitting apparatus used in the spread spectrum communication system according to the present invention is arranged such that the bit error rate measuring signal is a specific pattern or a pseudo pattern in which data is arranged with a periodicity. It is characterized by being a random signal.

According to the above configuration, since the bit error rate measurement signal is constituted by a specific pattern or a pseudo random signal, the BER measurement can be performed without using any special device or means for BER measurement on the receiving device side. Measurement can be performed easily.

In order to solve the above-mentioned problems, a transmitting apparatus used in a spread spectrum communication system according to the present invention has a receiving apparatus in which a bit error rate of a received signal in a communication channel is larger than a threshold value, and An error correction code adding means for adding an error correction code to the transmission signal when the radio wave intensity of the reception signal in the adjacent channel is lower than the radio wave intensity of the reception signal in the communication channel.

In the receiving device, the RSSI value of the adjacent channel adjacent to the communication channel is set to the R value of the communication channel.
If the SSI value is less than or equal to the SSI value, it can be said that the communication channel is less likely to be disturbed by an adjacent channel. However, since the BER of the communication channel is larger than the threshold,
A decrease in throughput occurs on the receiving device side.

Therefore, if the receiving apparatus is provided with a means capable of performing error correction, the error correcting code adding means of the transmitting apparatus adds an error correction code to the transmission signal, thereby enabling the receiving apparatus to perform error correction. Thus, a decrease in throughput can be minimized.

In order to solve the above-mentioned problems, the transmitting apparatus used in the spread spectrum communication system according to the present invention is arranged such that the error correction code adding means uses a receiving apparatus to perform the bit error rate of the received signal in all communication channels. Is larger than the threshold, an error correction code is added to the transmission signal.

In the receiving device, the BER of all communication channels
Is larger than the threshold value, it can be considered that the influence of noise or an interference wave is received on all the channels. Therefore, in such a case, if the error correction code adding means of the transmission device adds error correction code to the transmission signal, and the reception device has a unit capable of performing error correction, the reception device side By performing the error correction described above, communication on a predetermined channel can be performed while minimizing a decrease in throughput.

[0036]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described.
The following is a description based on the drawings.

FIG. 1 shows a schematic configuration of a receiving apparatus and a transmitting apparatus of the present invention (both are hereinafter referred to as terminal apparatuses) used in a spread spectrum communication system. In a spread spectrum communication system, a half-duplex communication system in which data transmission and reception are alternately switched to perform communication is adopted.

In this terminal device, the antenna 1 is connected to the transmission circuit 3 or the reception circuit 4 via the transmission / reception switch 2. The transmission side circuit 3 includes a transmission encoding processing unit 5 (error correction code adding unit), a spreading processing unit 6, and a modulator 7. The reception side circuit 4 includes a demodulator 8 , A despreading processing unit 9 and a receiving encoding processing unit 10. In addition, the terminal device further includes a terminal interface unit 11 (control means), an amplifier / detection unit 12, an RSSI detection unit 13
(Intensity detection means), correlation / synchronization determination section 14 (synchronization determination means), AND circuit 15, control section 16, BER measurement signal generation section 17 (bit error rate measurement signal generation means), BER And a measuring unit 18 (bit error rate measuring means). That is, the terminal device of the present invention is different from the conventional terminal device in that the BER measurement signal generation unit 17
And a BER measurement unit 18 are newly added.

The BER measurement signal generator 17 generates a signal for measuring the BER (bit error rate) in the BER measuring unit 18 of the terminal device on the receiving side.
The BER measurement signal is composed of, for example, a PN signal which is a specific pattern in which data is arranged with a periodicity or a pseudo random signal.

As the specific pattern, for example, 1
There is a repeating pattern of increment data from 0000 to FFFF expressed in hexadecimal. Since the increment data is about 64K bits of data, by repeating this, for example, 1M bits of data can be obtained.

Whether the BER measurement signal generated by the BER measurement signal generation unit 17 is added to the transmission signal depends on whether
It is determined based on the content of a header signal described later generated by the transmission encoding processing unit 5.

When receiving the signal, BER measuring section 18 uses the BER measuring signal included in the received signal to perform BE
Measure R. Specifically, when a specific pattern is inserted into the received signal, the BER measuring unit 18 compares the specific pattern of the received signal with a specific pattern stored in advance in a memory (not shown), and Count the number. On the other hand, when the BER measurement is performed using the PN signal, the transmitting side resets the PN signal generating section of the spreading processing section 6 at the beginning of the user data section of the header signal to be described later, and the receiving side similarly transmits the user data. At the beginning of the section, the PN signal generation section of the despreading processing section 9 is reset, and the BER measurement section 18 on the receiving side compares the received data with the data of the PN signal generation section of the despreading processing section 9 and finds that there is no match. Count the number.

Although the former method is very simple and convenient,
In the case of the specific pattern, the appearance probabilities of the data bits “0” and “1” are uniform, and have different properties from the data that is actually used for data communication.
The reliability of ER is low.

On the other hand, in the case of the PN signal, the appearance probabilities of the data bits “0” and “1” have randomness, and are closer to the characteristics of the actual communication data. More accurate BER measurement can be performed.

In the above configuration, the transmission signal is input from the terminal interface section 11 to the transmission encoding processing section 5 of the transmission side circuit 3, where various header signals are added to the signal. After that, the transmission signal is frequency-spread using a spreading code (for example, a PN code) in a spreading processing unit 6, modulated into a high-frequency signal in a modulator 7, and transmitted via the antenna 1.

FIG. 2 shows the transmission signal (data).
Is shown. The data includes a header part and a user data part. The MPDU of the user data section is usually stored in the terminal interface section 11.
The data sent from the
At the time of R measurement, the BER measurement signal generated by the BER measurement signal generation unit 17 is inserted into a specific position or the entire area of the user data part. Further, the ID code of the transmitting terminal device is also added to the user data portion.

On the other hand, the header part is composed of SYNC and SFD.
, SIGNAL, SERVICE, BER, L
It is composed of ENGTH and CRC. In the following, the BER of the header part is described as a BER header,
It will be distinguished from BER indicating the bit error rate itself.

SYNC is a synchronous field pattern, which is IEEE-compatible data or a "10" repeating pattern (both 128 bits). SFD is a frame synchronization signal, and is SFD16 (16 bits) or SFD31 (31 bits). SIGNAL
Is data that specifies the modulation scheme of the MPDU. SE
RVICE is optional data for which use is not specified. LENGTH indicates the bit length of the data used for the header part. CRC is CRC-FCS parity added for checking data in the header part.

The BER header controls the type of data to be inserted into the user data section, and is used as a header for controlling BER measurement. The BER header is composed of, for example, 8 bits, and each bit is BER1, BER2,.
FIG. 3 shows a configuration example of the BER header when the BER is associated with BER8.

BER1 indicates whether or not to insert a BER measurement signal into the user data section. When BER1 = 1, the transmission encoding processing unit 5 adds the BE to the user data part.
While inserting the R measurement signal, when BER1 = 0,
Insert normal data into the user data section. Therefore, when BER1 = 0, the BER in the receiving terminal device
No measurement is made.

BER2 indicates the type of the BER measurement signal when the BER measurement signal is inserted. When BER2 = 1, the transmission encoding processing unit 5 inserts the above-described specific pattern into the user data part as the BER measurement signal, and when BER2 = 0, the PN signal as the BER measurement signal Is inserted into the user data section.

BER3 indicates whether or not an FEC (error correction code) described later is added to the user data portion.
When BER3 = 1, the transmission encoding processing unit 5 adds FEC to the user data unit, but does not add FEC to the user data unit when BER3 = 0.

A channel for communication is designated by 5 bits of BER4 to BER8. Note that initially, a default channel is specified.

Next, a case will be described in which a high-frequency signal transmitted from a terminal device on the transmitting side is received by the terminal device having the configuration shown in FIG.

First, the high-frequency signal is transmitted to the demodulator 8 of the receiving circuit 4 via the antenna 1 and the transmission / reception switch 2.
Is input to The demodulator 8 demodulates the input high-frequency signal into a baseband signal. Thereafter, the baseband signal is despread by the despreading processing unit 9 and then input to the reception encoding processing unit 10 as an original data string.

On the other hand, amplification / detection of a signal received via the antenna 1 and the transmission / reception switch 2 is performed by the amplifier / detection unit 12. Then, in the RSSI detection unit 13,
An RSSI value indicating the radio wave intensity of the received signal is detected. Here, if the detected RSSI value is larger than a predetermined DC level threshold, the RSSI detection unit 13
"1" is output to the ND circuit 15. On the other hand, the detected R
When the SSI value is equal to or smaller than the threshold, the RSSI detector 13 outputs “0” to the AND circuit 15.

In order to utilize the RSSI value as an analog value, the RSSI detection unit 13 inputs the RSSI value to the terminal interface unit 11 via the control unit 16 while maintaining the DC level, and also transmits the RSSI display driver 19 to the RSSI display driver 19.
I value is input at DC level. The RSSI display driver 19 converts the input RSSI value into data for display on the display 20.

Next, the correlation / synchronization determination section 14 determines synchronization by calculating the correlation between the received spread spectrum signal and the spread code. The correlation / synchronization determination unit 14 outputs “1” to the AND circuit 15 when the two are synchronized, and when the two are not synchronized,
“0” is output to the AND circuit 15.

In the AND circuit 15, the RSSI detector 13
Is ANDed with the output from the correlation / synchronization determination unit 14, and the result is input to the control unit 16. The control unit 16 generates a flag indicating that reception is possible only when the output from the AND circuit 15 is “1”. The terminal interface unit 11 determines whether the received signal is a valid signal based on the flag generated by the control unit 16.

If the received signal is a valid signal, the BER measuring unit 18 measures the BER of the received signal, and the terminal interface unit 11 determines the quality of the communication channel as a communication channel based on the BER measurement result. Move the communication channel as needed. The movement of the communication channel will be described later. Then, the reception encoding processing unit 10 checks the ID code of the received signal and the CRC-FCS parity. If there is no error in the CRC-FCS parity, “0” is output from the reception encoding processing unit 10 to the terminal interface unit 11. In this case, the terminal interface unit 11 determines that a correct signal has been received, and ends a series of processing. On the other hand, CRC-FC
If there is an error in the S parity, “1” is output from the reception encoding processing unit 10 to the terminal interface unit 11. In this case, the terminal interface unit 11 determines that the received data is invalid, and requests the transmitting terminal device corresponding to the ID code to retransmit the data.

Next, the above-mentioned movement of the communication channel will be described with reference to FIGS.

It is assumed that the communication channel is set to channel 5 (hereinafter, the channel is described as Ch) by default. When starting communication for the first time, it is important to determine a default channel and to determine a protocol for confirming a channel to be moved based on the default channel.

Here, the BER required in the spread spectrum communication system is about 1 × 10 ⁻⁵ , and it is considered that there is no significant decrease in throughput if the BER is smaller than this. Therefore, it is appropriate to use this value as a reference as the BER threshold. In this case, when 1 Mbit data is transmitted as BER measurement data in the user data section, it can be said that there is no significant decrease in throughput if there are 10 errors. This is because 10 (the number of error bits) / 10 ⁶ (bit data) = 1 × 10 ⁻⁵ . Therefore, in terms of the number of error bits, the threshold value is 10 for 1 Mbit data.

First, after receiving data at Ch5 (S
1), the BER measuring unit 18 measures the BER of the received data (S2). And the terminal interface unit 11
Indicates whether the measured BER is less than 1 × 10 ^-5
That is, it is determined whether the number of error data is less than 10 for 1 Mbit data (S3).

If the measured BER is smaller than 1 × 10 ^-5 in S3, data transmission / reception is started at the current Ch5 (S4). On the other hand, if the measured BER is 1 × 10 ⁻⁵ or more in S3, the data is received by the adjacent Ch4 having a lower frequency than Ch5 (S5). Then, R
The SSI detecting unit 13 performs RSS of the signal received at Ch4.
The I value is measured (S6). The measured RSSI value is RS
The data is input from the SI detection unit 13 to the terminal interface unit 11 via the control unit 16.

In the example of FIG. 5, the number of error bits of Ch5 is 15, which is larger than the threshold value 10, and BER> 1 × 10 ^-5 for 1 Mbit data, so that S5 and S6 are sequentially performed. Transition.

Next, the terminal interface unit 11
It is determined whether the RSSI value of Ch4 is greater than the RSSI value of Ch5 (S7). In S7, RSS of Ch4
When the I value is larger than the RSSI value of Ch5, the terminal interface unit 11 determines that the current Ch5 cannot be secured with sufficient communication quality due to interference from the neighboring Ch4, and is not affected by the neighboring Ch4. The communication channel is moved to Ch9 (S8).

On the other hand, in step S7, the RSSI value of Ch4 becomes C
If the value is equal to or less than the RSSI value of h5, next, data is received by the adjacent Ch6 having a higher frequency than Ch5 (S9). Thereafter, the RSSI detection unit 13 determines the RSSI of the received signal.
The value is measured (S10). Then, the terminal interface unit 11 sets the RSSI value of Ch6 to C
It is determined whether the value is greater than the RSSI value of h5 (S1).
1).

In S11, the RSSI value of Ch6 is Ch5
Is larger than the RSSI value, the terminal interface unit 11 determines that the current Ch5 is not able to secure sufficient communication quality due to interference from the neighboring Ch6,
The communication channel is moved to Ch9 which is not affected by h6 (S12).

In the example of FIG. 5, the RSSI value of Ch4 is 30.
And larger than the RSSI value 15 of Ch5,
The communication channel is moved from h5 to Ch9. In addition,
Since the RSSI value of Ch6 is 40, which is larger than the RSSI value 15 of Ch5, if the RSSI value of Ch4 is C
Even if it is smaller than the RSSI value of h5, the communication channel is moved from Ch5 to Ch9.

Thereafter, the BER measuring unit 18 determines the C
The BER of the signal received at h9 is measured, and if it is confirmed that the BER on this channel is sufficiently small, communication is performed on this channel.

The BER of Ch9 is large (for example, 1
× 10 ^-5 or more), Ch away from Ch5 and its adjacent channels Ch4 and Ch6,
It is sufficient to move to a channel other than 9 and perform communication again.

On the other hand, if the RSSI value of Ch6 is equal to or less than the RSSI value of Ch5 in S11, the transmission coding processing section 5 of the terminal device on the transmitting side adds the FEC code to the communication data and performs Start transmission / reception of data (S1
3). Further, when the communication channel is moved, even if the BER is deteriorated (BER is larger than the threshold value) in all the communication channels of the moving destination, the transmission encoding processing unit 5 stores the FEC in the communication data. Add sign and C
At h5, data transmission / reception is started. It is assumed that the terminal device on the receiving side includes a circuit capable of executing error correction.

Here, as the above-mentioned FEC code, for example, BCH (Bose-Chaudhuri-H
ocqenghem) code or Reed-Solomon code which is a byte error code can be used. These are the same as those used for the audio data of the BS broadcast.

In any of the above error codes,
A code having a large error correction capability requires a large amount of hardware (computation amount), and even if the same code is used, the correction capability is greatly changed by changing the redundancy. Therefore, which FEC code is optimal depending on the throughput required by the system. It is difficult to judge. However, it is generally said that any of the above error codes can improve the BER by at least about 10 ⁴ to 10 ⁶ after correction.

In this embodiment, as shown in FIG. 6, transmission data is divided into 56-bit data in frame units, and a 7-bit error correction code is added to this data. Thereby, one bit error can be corrected among 56 bits,
A two-bit error can be detected. Also, if the data is transmitted in the order indicated by the arrow in the figure, that is, in the order in which the data is arranged, continuous errors are dispersed when rearranged on the receiving side. Error correction is facilitated.

When adding FEC, BER is 1 ×
10^-FourThat is, an error occurs for 1 Mbit data.
The threshold value is 100 bits, and the error bit is this threshold value.
Is added, the FEC is added. This is a correction
1 × 10 for later BER ^-FiveCan be much smaller than
However, in the example of FIG. 6, 7 bits are used for 56 bits of data.
, The redundancy is 11% ((7
/ (56 + 7)) × 100), resulting in low throughput
In addition, the amount of hardware for error correction also increases.
In the case of
It is necessary to lower it.

In the processing described above, since the data relating to the communication channel such as the ID of the terminal device on the transmitting side, the measurement date, the BER and the RSSI value is very effective, these data are shown in FIG. By storing the data in the storage unit 21 (storage means), and the terminal interface unit 11 reading out these data from the storage unit 21 next time and performing control to select an appropriate communication channel, a communication error or the like can be prevented. The decrease in throughput is reduced. Each of the above data is stored in the storage unit 21 in a format as shown in FIG. 7, for example.

The RS measured on each communication channel
The SI value and the BER value are input to the display 20, and the display 20 can simultaneously confirm these values on one screen. FIG. 8 shows a display screen of the display device 20. On this display screen, the upper side of each channel is RS
The SI value is shown, and the lower side shows the BER measurement value (or error count value). The smaller the BER measurement,
As a matter of course, a good communication state is indicated, so that a channel whose lower bar graph is closer to 0 has a better communication state. Thus, the RSSI value and BER in each communication channel are
By displaying the measured values in a bar graph on the display 20, the user can visually recognize the quality of the communication state in each communication channel.

The display device 20 may be built in the terminal device itself or an external device (for example, a monitor when a PC (Personal Computer) is connected to the terminal device). Is also good.

As described above, according to the present invention, the quality determination of the communication channel is performed based on not only the correlation / synchronization determination result and the RSSI value but also the BER obtained by the BER measurement. By considering the BER in this way, it is determined whether the S / N ratio is deteriorated in the communication channel or the influence of the interference wave from the nearby channel is present, which cannot be determined only by the conventional synchronization determination and RSSI value detection. be able to. When the quality of the communication channel is poor, a better communication quality can be ensured by moving the communication channel to another channel.
As a result, occurrence of a communication error (data transfer failure) and a decrease in throughput in a channel with poor communication quality can be surely suppressed, and a good communication quality with a small number of retransmission requests can be maintained. .

Further, according to the present invention, when the S / N ratio of the communication channel used is good, there is no interference from adjacent channels, and when the BER is sufficiently low, CRC-FCS parity is added to the user data part. Only while making the data area available to the user larger for communication,
When R is bad but BER can be improved by error correction on the receiving side, an FEC code is added to user data on the transmitting side, and error correction is performed on the receiving side. In this case, although the amount of data that can be transmitted and received at one time decreases, the number of retransmissions can be reduced, so that a decrease in throughput can be minimized. Also, FEC
With the addition of the code, data transmission / reception can be performed even when the BER in the communication channel deteriorates.

The terminal device on the receiving side described in the present embodiment can also be expressed as follows.

The terminal device on the receiving side has a configuration in which a bit error rate measuring unit is provided in addition to a receiving electric field strength judging unit and a synchronization judging unit judging synchronization based on a correlation between a spread signal and a spreading code.

Further, the terminal device on the receiving side measures the RSSI value of the channel adjacent to the channel to be communicated, further measures the BER of the used channel, and if the BER is lower than the criterion value (threshold), the RSSI value The configuration is such that control means is provided for selecting a channel having the smallest value and moving the communication channel to the selected channel. According to this configuration, it is possible to understand the cause of the communication error and the decrease in the throughput, so that it is possible to smoothly move to a communication channel having a better communication state.

Further, the terminal device on the receiving side scans all channels and transmits and receives the RSSI value and the BER between the devices.
Is provided with a memory for storing the values when the measurement is performed, and when communication is performed next, control for selecting the best communication channel based on the data in the memory and performing communication is performed. This is a configuration including control means. With this configuration, the communication state of all communication channels can be easily grasped, so that a communication channel with the best communication state can be secured in a short time.

Further, the terminal device on the receiving side is provided with a display for displaying the measured BER value in addition to the display of the RSSI value of the channel used. The display shows the RS of all channels in addition to the channel in use.
It has a display function to check the SI value and BER measurement value at a time. With this configuration, the user can be visually notified of the communication state, and the spread spectrum communication system can be more easily used.

The transmitting terminal device described in the present embodiment can also be expressed as follows.

The terminal device on the transmitting side is provided with a BER measurement signal generator for selecting and inserting a specific pattern or a pseudo random signal (PN code) for BER measurement in the user data area of the transmission signal. is there.

Further, the terminal device on the transmitting side is configured to include an FEC adding section for adding an FEC to the user data section when the measured value of the BER is lower than the determination reference value. With this configuration, communication can be performed with a minimum decrease in throughput even when all channels are affected by noise or interference.

For example, Japanese Unexamined Patent Publication No. Hei 6-204985 discloses a configuration for estimating a BER. However, the present invention differs from the above publication in that the BER is actually measured by the BER measuring unit 18. I have.

[0092]

As described above, the receiving apparatus used in the spread spectrum communication system according to the present invention comprises: a synchronization judging means for judging synchronization by a correlation operation between a received spread signal and a spread code; Strength (hereinafter referred to as RSSI
Value), a bit error rate measuring means for measuring a bit error rate (hereinafter referred to as BER) of a received signal, the synchronization determining means, the intensity detecting means, and the bit error. Control means for determining the quality of the communication channel currently used as a communication channel based on the result obtained by the rate measuring means.

Therefore, in determining the quality of a communication channel, the BER is taken into consideration, and the presence / absence of an interfering wave or noise from another channel, which cannot be determined only by the conventional synchronization determination and detection of the RSSI value, is determined. You can judge.

Therefore, the control means can accurately judge the quality of the channel on which communication is currently being performed. If the quality of the communication channel is poor, for example, the communication channel is moved to another channel. By doing so, it is possible to take measures to ensure better communication quality. As a result, it is possible to suppress the occurrence of a communication error and a decrease in throughput in a channel with poor communication quality, and to maintain a communication state with good communication quality.

As described above, in the receiving apparatus used in the spread spectrum communication system according to the present invention, the control means determines that the bit error rate of the received signal in the current communication channel is larger than the threshold value and the adjacent channel When the radio wave intensity of the received signal in the communication channel is higher than the radio wave intensity of the received signal in the communication channel, control is performed so that communication is performed on a channel other than the adjacent channel.

Therefore, when the influence of an interfering wave from an adjacent channel is considered, the communication channel is moved by the control means, so that good communication can be performed on a channel in which no communication failure occurs. It works.

The receiving apparatus used in the spread spectrum communication system according to the present invention further comprises storage means for storing the radio field intensity and the bit error rate of the received signal in all communication channels, as described above. Is a configuration for performing control for selecting a communication channel based on the contents stored in the storage means.

Therefore, the control means can immediately grasp the communication state in all communication channels from the contents stored in the storage means. Therefore, the control means, for example, at the time of the next communication, the RSSI value stored in the storage means and the BER
Thus, it is possible to select a channel suitable for communication in a short time based on the above, and it is possible to perform good communication on the selected communication channel.

As described above, the receiving apparatus used in the spread spectrum communication system according to the present invention is configured to further include the display means for displaying the radio field intensity and the bit error rate of the received signal in all communication channels. is there.

Therefore, it is possible to visually notify the user of the communication state in each communication channel, and it is possible to make the spread spectrum communication system easier to use.

As described above, the transmitting apparatus used in the spread spectrum communication system according to the present invention includes a bit generating a bit error rate measuring signal used for measuring a bit error rate of a received signal in the receiving apparatus. This is a configuration including an error rate measurement signal generation unit.

Therefore, if the bit error rate measuring signal generated by the bit error rate measuring signal generating means is added to the transmission signal and transmitted to the receiving device, the receiving device side can generate the bit error rate measuring signal. The bit error rate (BER) can be measured using the signal. This allows the receiving apparatus to determine the presence or absence of an interfering wave or noise from another communication channel, which could not be determined based on the synchronization between the spread signal and the spread code or the radio wave intensity (RSSI value) of the received signal alone. It becomes possible.

Therefore, it is possible for the receiving apparatus to accurately judge the quality of the currently communicating channel. If the quality of the communication channel is poor,
For example, it is possible to take measures to ensure better communication quality by moving a communication channel to another channel. As a result, it is possible to suppress the occurrence of a communication error and a decrease in throughput in a channel with poor communication quality, and to maintain a communication state with good communication quality.

In the transmitting apparatus used in the spread spectrum communication system according to the present invention, as described above, the bit error rate measuring signal is a specific pattern or a pseudo random signal in which data is arranged with a periodicity. Configuration.

Therefore, there is an effect that BER measurement can be easily performed without using a special device or means for BER measurement on the receiving device side.

As described above, in the transmitting apparatus used in the spread spectrum communication system according to the present invention, the bit error rate of the received signal in the communication channel is larger than the threshold value in the receiving apparatus. An error correction code adding means for adding an error correction code to a transmission signal when the radio wave intensity of the signal is equal to or lower than the radio wave intensity of the received signal in the communication channel.

Therefore, assuming that the receiving apparatus has a means capable of performing error correction, the error correcting code adding means of the transmitting apparatus adds an error correcting code to the transmission signal, so that an error on the receiving apparatus side can be obtained. The correction has an effect that a decrease in throughput can be minimized.

As described above, in the transmitting apparatus used in the spread spectrum communication system according to the present invention, the error correction code adding means is arranged so that the receiving apparatus sets the bit error rate of the received signal in all communication channels lower than the threshold value. When the size is large, an error correction code is added to the transmission signal.

Therefore, if the receiving apparatus is provided with a means capable of performing error correction, even if the receiving apparatus is affected by noise and interference waves on all channels by error correction, a predetermined channel can be used. This makes it possible to carry out this communication while minimizing a decrease in throughput.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a schematic configuration of a receiving device and a transmitting device used in a spread spectrum communication system according to the present invention.

FIG. 2 is an explanatory diagram showing a configuration of a signal transmitted from the transmission device.

FIG. 3 is an explanatory diagram showing a configuration of a BER header of a header section included in the transmission signal.

FIG. 4 is a flowchart showing a flow of operation when a final communication channel is determined.

FIG. 5 is an explanatory diagram for explaining movement of a communication channel performed based on an RSSI value and a BER.

FIG. 6 is an explanatory diagram showing a state in which an error correction code is added to a transmission signal.

FIG. 7 is an explanatory diagram for describing contents stored in a storage unit.

FIG. 8 is an explanatory diagram illustrating an example of a display screen of a display device.

FIG. 9 is a block diagram showing a schematic configuration of a receiving device and a transmitting device used in a conventional spread spectrum communication system.

FIG. 10 is an explanatory diagram showing a configuration of a signal transmitted from the transmission device.

FIG. 11 is a flowchart showing a flow of an operation in the case where communication is performed by the ARQ scheme in the receiving apparatus.

[Explanation of symbols]

5 Encoding unit for transmission (error correction code adding unit) 11 Interface unit for terminal (control unit) 13 RSSI detection unit (strength detection unit) 14 Correlation / synchronization determination unit (synchronization determination unit) 17 BER measurement signal generation unit (Bit error rate measurement signal generation means) 18 BER measurement section (Bit error rate measurement means) 20 Display (Display means) 21 Storage section (Storage means)

Claims (8)

[Claims] 1. A synchronization determining means for determining synchronization by calculating a correlation between a received spread signal and a spread code; an intensity detecting means for detecting radio wave intensity of a received signal; and a bit error for measuring a bit error rate of the received signal. Rate measuring means, and control means for determining the quality of a communication channel currently used as a communication channel based on the results obtained by the synchronization determining means, the intensity detecting means, and the bit error rate measuring means. A receiving device for use in a spread spectrum communication system, comprising: 2. The control means according to claim 1, wherein the bit error rate of the received signal in the current communication channel is higher than a threshold value, and the radio wave intensity of the received signal in the adjacent channel is higher than the radio wave intensity of the received signal in the communication channel. 2. The receiving apparatus used in a spread spectrum communication system according to claim 1, wherein when it is large, control is performed such that communication is performed on a channel other than the adjacent channel. 3. A storage unit for storing the radio field intensity and the bit error rate of a received signal in all communication channels, wherein the control unit performs control for selecting a communication channel based on the storage contents of the storage unit. The receiving apparatus used in the spread spectrum communication system according to claim 1 or 2. 4. The spread spectrum communication system according to claim 1, further comprising display means for displaying a radio field intensity and a bit error rate of a received signal in all communication channels. The receiving device used. 5. A transmitting apparatus used in a spread spectrum communication system for transmitting spread spectrum data to a receiving apparatus after performing spread spectrum processing on the communication data, wherein a bit error used for measuring a bit error rate of a received signal in the receiving apparatus. A transmitting apparatus used in a spread spectrum communication system, comprising: a bit error rate measuring signal generating means for generating a rate measuring signal. 6. The spread spectrum communication system according to claim 5, wherein the bit error rate measuring signal is a specific pattern or a pseudo random signal in which data is arranged with a periodicity. Transmission device. 7. A receiving apparatus, wherein a bit error rate of a received signal in a communication channel is larger than a threshold value, and a radio wave intensity of a received signal in an adjacent channel is lower than a radio wave intensity of a received signal in the communication channel. 7. The transmission apparatus used in a spread spectrum communication system according to claim 5, further comprising an error correction code adding means for adding an error correction code to the transmission signal in such a case. 8. The error correction code adding means adds an error correction code to a transmission signal when a bit error rate of a reception signal in all communication channels is greater than a threshold value in the receiving device. A transmission device used in the spread spectrum communication system according to claim 7.