JPH0865264A - Method and equipment for communication for cdma system using spread spectrum modulation - Google Patents

Abstract

PURPOSE: To extract a data signal from a desired transmitting station out of received signals by changing the chip rate of a second spread code signal into the same rate as the chip rate of the first spread code signal of the desired transmitting station at a receiving station. CONSTITUTION: The reception system of the CDMA type communication system uses BPSK(binary phase shift keying) as a spread modulation stem. Spread demodulation is performed by multiplying the spread code signal generated by a spread code selection generator 25 to the received signal of which the frequency is converted by a frequency converter 22. Further, a clock selection generator 28 of a means for generating a clock signal is constituted. Then, even when the chip rate of the first spread code signal on the side of the transmitting station is different, at the receiving station, the chip rate of the second spread code signal is changed into the same rate as the chip rate of the first spread code signal of the desired transmitting station so that the data signal from the desired transmitting station can be extracted out of the received signals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a CDMA (Code Division Multiple Access) type communication method and a communication apparatus using spread spectrum modulation.

[0002]

2. Description of the Related Art With the increase in the number of wireless communication stations, a spread spectrum modulation system, which is resistant to noise and interference, is drawing attention. The spread spectrum modulation method is a method in which a signal subjected to normal data modulation such as PSK or QAM is further modulated by a high-speed code string called a spread code to intentionally widen the spectrum band. Diffusion (DS: Direct s
sequence and frequency hopping (FH: Frequency H)
opping) method. Here, the transmission system and the reception system in the DS communication system are shown in FIGS.
Will be described with reference to.

In the transmission system, as shown in FIG. 1, an input data signal such as a digital voice signal is subjected to data modulation by a data modulator 1 and then supplied to a spread modulator 2, where it is already allocated by the system. Spread-modulation is performed by the spread-code signal P1 indicating a spread-code string consisting of a plurality of bits. The spread code signal P1 is generated from the spread code generator 3, and the clock signal that determines the bitwise generation timing of the spread code signal P1 is generated in the clock generator 4. The generation rate of the spread code signal P1, that is, the timing of the clock signal is much faster than the data rate, so that the band of the signal modulated is widened. The generation rate of the spread code signal is called the chip rate,
Twice that is the spreading band. The spreading band is usually selected to be about 10 to 100 times the data band.
The spread signal is frequency-converted by the frequency converter 6 by the carrier signal from the local oscillator 5 to become a radio frequency transmission signal, which is transmitted from the antenna 7.

2 and 3 show the waveforms and spectra of the signals of the various parts of the above transmission system. In FIG.
(A) is an input data signal waveform after data modulation,
(B) is a spread code signal waveform emitted from the spread code generator 3, (c) is a signal after spread modulation, and (d)
Is the carrier signal waveform. In addition, in FIG.
(A) is the spectrum of the input data signal, (b) is the spectrum of the spread code signal, (c) is the spectrum of the signal after spread modulation, (d) is the spectrum of the carrier signal, e) is the spectrum of the transmitted signal.

The ratio of the data band to the spread band, that is, the ratio of the data rate to the chip rate is called a processing gain. As shown in the spectrum of FIG. 4A, the reception signal received in the reception system includes the transmission signal A from the transmission station to be received and the transmission signal B from another station.
It is assumed that C, the wideband interference signal D, and the narrowband interference signal E are included. The received signal is received from the antenna 10 as shown in FIG. 5, and then the carrier signal from the local oscillator 12 is put together by the frequency converter 11 to be frequency-converted to the base band. The frequency-converted received signal (FIG. 4B) is subjected to demodulation processing of the spread modulation signal in the spreading demodulator 15 at the next stage. This demodulation process is called despreading. In the receiving system, a spread code selection generator 13 is provided internally in the memory 13a as data of spread codes of all partner stations with which communication is possible. In the spreading code selection generator 13, the same spreading code as that of the transmitting station to be received from the plurality of spreading codes stored in the memory 13a, for example, the spreading code shown in FIG. 2 (d) and FIG. 3 (d). The same P1 is selected and output as a spread code signal in synchronization with the clock signal. The clock signal is generated by the clock generator 14 and its frequency is
The frequency of the clock signal of 4 is the same. The selected and output spread code signal is supplied to the spread demodulator 15 to despread the frequency-converted received signal.

As shown in FIG. 4 (c), the signal A is restored to the original narrow band signal by despreading, but the wide band signals B and C from other stations are spread again with spreading code signals different from those at the time of spread modulation. Since it has been modulated, it remains almost broadband. The wideband interference signal D has been spread-modulated and remains in the wideband. The narrow band interference signal E is newly spread-modulated and spreads to the band of the spread code. Thus, only the signal spread by the same code signal as the spread code signal used for despreading can be returned to the narrow band signal.
By supplying the signals output from these spread demodulators 15 to the filter 16 that passes only the data band, it is possible to take out the desired signal that has returned to the narrow band signal as shown in FIG. 4D. If this is demodulated by the data demodulator 17, the original data signal is obtained. The transmission signal from another station and the reception signal of the interference signal are reduced by the ratio to the spread band because the spectrum outside the pass band of the filter 16 is lost. Therefore, the S / N is improved by the processing gain.

Binary phase shift keying (BPSK) is often used as the spread modulation method. Further, when BPSK is used as the data modulation method, "0" in the data signal and the spread code signal is converted into "-1". In data modulation, there is no processing other than this conversion. The spread modulator 2 includes a multiplier that multiplies a spread code signal and a data signal,
The spread demodulator 15 is composed of a multiplier that multiplies the spread code signal and the received signal. When the spread modulation is BPSK, spread demodulation is performed by the receiving station again performing spread modulation using the same spreading code signal as that of the transmitting station. This is because performing BPSK twice using the same spread code signal is the same as doing nothing, so BPSK modulation is also BPSK demodulation at the same time.

The spread code signal is required to have random characteristics that the peak of the autocorrelation function is sharp and the cross-correlation coefficient is small. An ideal code signal having this property is a noise code signal having an infinite length, but from a practical point of view, a pseudo noise (PN) code represented by an M-sequence, a Gold code, etc., which is a finite repetition. The signal is used. 6 and 7
Shows examples of the autocorrelation function and cross-correlation function of these code signals. A limited number of code signals having a fixed length have such a property, and such spread code signals are assigned to each user (each station) as shown in FIG. In FIG. 8, fc is the center frequency of the carrier signal, P
1, P2, ..., Pn are spread code signals different from each other, and R is its chip rate.

The above is the flow of signals from the viewpoint of frequency, but the despreading and the subsequent filter processing are actually multiplication and integration (or addition) processing, and from the viewpoint of time, the spread code signal. It means that the correlation coefficient is calculated in the cycle. These are collectively called a matched filter, and there are various ways to realize it, such as numerical calculation using an analog method using a convolver or a digital method. Among the received signals, the signal spread-modulated by the same code signal as the spreading code signal of the receiving station has a large output because the peak of the autocorrelation function is large, and the cross-correlation coefficient of the signals spread-modulated by different codes is large. Its output is small because it is small. That is, the correlation characteristic of the spread code signal provides the ability to distinguish between the desired signal and the unwanted signal. Conversely, the ability to discriminate between the desired signal and the unnecessary signal depends on the correlation characteristic of the spread code signal. As described above, the spread code signal also serves as a user ID.

As can be seen from the above description of the operation, the spread spectrum modulation method has the following advantages. (1) By using different spreading code signals, a plurality of transmitting stations can use the same frequency band at the same time. (2) Strong resistance to interference (interference, multipath fading, intentional interference, etc.).

(3) Since the spectral density is small, the degree of interference with existing narrow band communication is small. (4) Communication is possible even in a situation where the spectral density is smaller than noise, and communication is confidential. (5) There is confidentiality when the spread code signal used at the transmitting station is unknown.

In a communication system, the multiple access method using the advantage (1) is a code division multiple access (CDM).
It is called the A) system and is the third multiplexing system after the frequency division multiple access (FDMA) system and the time division multiple access (TDMA) system. As shown in FIG. 9, the FDMA system divides a predetermined frequency band into a number and divides a plurality of users into different frequency axes so that they coexist. T
In the DMA method, as shown in FIG. 10, the time to be used for each user is divided within the same frequency band, and a plurality of users are dispersed on the time axis to coexist. CDMA
In the system, a code axis is provided as a third axis as shown in FIG. 11, and a plurality of users can communicate with each other in the same predetermined frequency band even at the same time.

FIG. 12 shows an arrangement in a plurality of cells adjacent to each other when the FDMA method is applied to a cellular telephone system as a communication system, and FIG. 12 shows an arrangement in a plurality of cells adjacent to each other when the CDMA method is applied. Thirteen
Shown in In the FDMA system, is allocated a different frequency such as to avoid interference between adjacent cells requires at least seven frequency bands (center frequency f ₁ ~f _7). This is further divided into channels CH1, CH2, ... And assigned to users. Since it is not necessary to divide by frequency in the CDMA system, the same frequency band (center frequency f) can be used in all cells.
Different PN codes P1, P2, ..., P23 are assigned to the users so that they do not interfere with each other. CDM
In the A-system cellular telephone system, the frequency utilization efficiency is improved as compared with the conventional FDMA-based or TDMA-based cellular telephone system.

[0014]

By the way, the conventional CD
In the receiving station of the MA communication system, the transmission signals of the stations other than the communication partner station and the reception signals of the interference signals remain as wideband signals even after despreading, so that unnecessary signals outside the pass band are filtered by the filter. Although the narrow band desired signal is taken out by removing the spectrum, the spectrum of the unnecessary signal is actually included in the pass band, which causes the deterioration of the S / N. As the number of users increases, the S / N deterioration increases, and the minimum allowable value of this S / N limits the number of users. In order to effectively use the frequency, it is necessary to take as many users as possible within the unit band. In order to increase the allowable number of users, it is conceivable to further expand the spreading band (further increase the chip rate) in the conventional CDMA system and reduce the spectral density of the transmission signal of the station other than the communication partner station. Since a wider band is required, there is a drawback that the frequency cannot be effectively used even if the number of users increases. It is also conceivable to use a modulation system with a small required S / N that occurs in data modulation and demodulation, but a modulation system with a small required S / N generally has a low data transmission rate, so that even if the number of users increases. There is a drawback that the amount of data transmission is reduced.

Therefore, an object of the present invention is to provide a CDMA communication method using spread spectrum modulation capable of increasing the number of users in a unit band without further expanding the spread band or lowering the data transmission rate. It is to provide a communication device.

[0016]

According to the communication method of the present invention, a plurality of transmitting stations generate a first spread code signal composed of a code string of a plurality of bits, and a data signal to be transmitted according to the first spread code signal. A spread signal is generated by performing spread spectrum modulation on the received signal, a second spread code signal having the same code sequence as the first spread code signal is generated at the receiving station, and the received signal is obtained by receiving the transmit signal. A CDMA communication method using spread spectrum modulation for performing spread spectrum demodulation according to a second spread code signal to restore a data signal of a desired transmitting station among a plurality of transmitting stations. The chip rate of the first spread code signal is different from each other, and the chip rate of the second spread code signal is different from that of the desired station.
It is characterized in that it is made equal to the chip rate of the spread code signal.

The communication apparatus of the present invention includes a first spreading code generating means for generating a first spreading code signal composed of a code string of a plurality of bits at the time of transmission, and a data signal to be transmitted according to the first spreading code signal. Means for performing spread spectrum modulation to generate a transmission signal, second spreading code generation means for generating a second spreading code signal having the same code sequence as the first spreading code signal, and receiving the transmission signal at the time of reception A CDMA communication apparatus using spread spectrum modulation, which comprises means for performing spread spectrum demodulation on the obtained received signal in accordance with a second spread code signal to restore a data signal, wherein a second spread code generation The means makes the chip rate of the second spread code signal variable.

[0018]

According to the present invention, even if the first spread code signal of the same code sequence is generated in each of the plurality of transmitting stations and the transmission signal is generated by subjecting the data signal to spread spectrum modulation, Since the chip rates of the one spread code signal are different from each other, the receiving station changes the chip rate of the second spread code signal to the same rate as the chip rate of the first spread code signal of the desired transmitting station. It is possible to extract the data signal from the desired transmitting station.

[0019]

Embodiments of the present invention will now be described in detail with reference to the drawings. The receiving system of the CDMA communication system according to the present invention shown in FIG.
I am using SK. In this receiving system, the antenna 2
The received signal received at 1 is supplied to the frequency converter 22. The frequency converter 22 frequency-converts the received signal into a base band by the carrier signal emitted from the local oscillator 23. The output signal of the frequency converter 22 is supplied to the spread demodulator 24 composed of a multiplier. The spread demodulator 24 is provided with a spread code selection generator 25 having the same configuration as the spread code selection generator 13 described above. Spreading demodulation is performed by multiplying the received signal whose frequency has been converted in the frequency converter 22 by the spreading code signal generated from the spreading code selection generator 25. The signal that is spread and demodulated by the spread demodulator 24 becomes a narrow band signal of only the data band by the filter 26, and the narrow band signal is data demodulated by the data demodulator 27 to become the original data signal. The spread demodulator 24 and the filter 26 form a matched filter.

The above configuration is simply the BP of the configuration shown in FIG.
Only the configuration using SK is used. According to the present invention,
Further, the means for generating the clock signal comprises a clock selection generator 28. The clock selection generator 28 has a memory 28a in which a plurality (m) of different chip rates R1 to Rm are stored as data. In the clock selection generator 28, the chip rates R1 ...
The chip rate of 1 is selectively read out of Rm,
A clock signal having the one chip rate is generated for the spread code selection generator 25. Spreading code selection generator 25
In this case, one spreading code is selectively read out as a spreading code signal in synchronization with the clock signal from the plurality (n pieces) of spreading codes P1 to Pn stored in the memory 25a, and the spreading code signal is It is output to the spread demodulator 24.
The spread code selection generator 25 and the clock selection generator 28 are determined according to a selection command from a control circuit (not shown).
A spreading code of 1 and a chip rate of 1.

Further, even when the spread code signal indicating the same spread code is generated, one of the chip rates R1 to Rm is selected.
The cycle of the spread code signal differs depending on the clock signal generated by selecting one chip rate. Therefore, the length of the spread code signal used for the correlation calculation in the filter 26 is the chip rates R1 to Rm as shown in FIG.
According to the above, it is determined in the cycle unit of the extension code signal.

In such a configuration, the spread code and chip rate used for spread modulation of the transmission system are predetermined for each station. That is, in the transmission system shown in FIG. 1, the frequency of the spread code string indicated by the spread code signal output from the spread code generator 3 and the frequency of the clock signal generated from the clock generator 4 are predetermined for each station. . If the same spreading code and chip rate as the transmitting station to be received are selected in the receiving station, a signal including the narrow band signal transmitted by the transmitting station can be obtained from the signal demodulated in the spreading demodulator 24. become. The filter 26 outputs the narrowband signal as it is because the peak of the autocorrelation function is generated for the narrowband signal by the calculation of the correlation.

However, when the spreading code is different between the receiving station and the transmitting station, the demodulation output signal of the spreading demodulator 24 of the receiving station which receives the transmission signal from the transmitting station becomes a wide band signal. The filter 26 does not output the wideband signal as it is because the cross-correlation coefficient is small for the wideband signal according to the calculation of the correlation. Also, even if the spreading code is the same between the receiving station and the transmitting station, if the chip rates are different, the demodulation timing will not match in the spreading demodulator 24 of the receiving station that received the transmission signal from that transmitting station, so the demodulation output signal It becomes a wideband signal inside. The filter 26 does not output the wideband signal as it is because the peak of the autocorrelation function does not occur due to the correlation calculation and the crosscorrelation coefficient is small for the wideband signal.

Further, when the spreading code and the chip rate are different between the receiving station and the transmitting station, a wide band signal is obtained in the output signal of the spreading demodulator 24 of the receiving station which received the transmitting signal from the transmitting station. Therefore, the wideband signal is removed by the filter 26 and is not output as it is. As described above, according to the present invention, the receiving station can separate and extract the transmission signal from the station to be received from the received signal not only by the type of spreading code but also by the chip rate. Even if the codes are the same, it is possible for users having the same chip rate to communicate within the same frequency band. Therefore, as shown in FIG.
N of different predetermined bit lengths for performing spread modulation
A spreading code signal indicating one spreading code of the spreading codes of a type is generated, and the transmission rate of the spreading code signal is determined by one chip rate of m chip rates R1, R2, ..., Rm. In the communication system, n × m users can be used at the same time, and the conventional system can use only n users at the same time in the same frequency band. Be improved. For example, in a communication system using 10 kinds of spreading codes, the number of users who can use the same frequency band at the same time is expanded from 10 to 30 by allowing 3 kinds of chip rates.

A user assigned a chip rate smaller than the maximum chip rate allowed from the frequency band condition does not use all the predetermined band, and thus the processing gain is inferior to that of the user having the maximum chip rate. Degradation can be minimized by selecting the required chip rate from the values as close as possible to the maximum value. If the maximum chip rate is 1 (Mbps), 0.
You can select it as 9, 0.8, ... (Mbps).

The present invention can be applied to a mobile communication system using a cell structure such as a cellular telephone system. The structure between the cells is shown in FIG. Here, different spreading codes P1 to P7 are used for the seven hexagonal cells.
Are allocated one by one, and different chip rates R1, R2, ... Are allocated to the users in the cell. Since the spreading codes are different between adjacent cells, no interference will occur. In this case, different spreading codes are required for a plurality of cells surrounding one cell, and the chip rate is required for the number of users in the cell.

On the other hand, the allocation of the spread code and the chip rate in FIG. 17 is reversed, and as shown in FIG. 18, different chip rates R1 to R7 are allocated to the cells, respectively, and the users in the cell are mutually allocated. Different spreading codes P1, P
It is also possible to assign 2, ... Since adjacent chips have different chip rates, no interference occurs.
In this case, among a plurality of cells surrounding one cell, different chip rates are required for the number of cells, and spreading codes are required for the number of users in the cell.

19 and 20 show another embodiment of the present invention. FIG. 19 shows the configuration of the receiving system.
The same parts as those in the embodiment shown in FIG.
The clock selection generator 30 is different from the clock selection generator 28 of the receiving system in FIG. 14 and has a memory 30a in which two mutually different chip rates R1 and R2 are stored as data. In the clock selection generator 30, a chip rate R is generated according to a selection command from a control circuit (not shown).
A chip rate of 1 is selectively read out of 1 and R2, but different chip rates are read out during communication in the upward direction and during communication in the downward direction. That is, in the communication between the base station and the mobile station in the cell, the transmission from the mobile station to the base station is the upstream communication, and the transmission from the base station to the mobile station is the upstream communication. Therefore, the chip rate R
If 1 is used for upstream communication and the chip rate R2 is used for downstream communication, in the clock selection generator 30 of the receiving system of the base station, the chip rate R1 is the memory 3
0a, a clock signal according to the chip rate R2 is generated, and the clock selection generator 30 in the reception system of the mobile station reads the chip rate R1 from the memory 30a and generates a clock signal according to the chip rate R1. appear.

FIG. 20 shows a configuration of a transmission system corresponding to the reception system of FIG. 19. In this transmission system, an input data signal is data-modulated by a data modulator 31,
It is supplied to the spread modulator 32 composed of a multiplier. The spread code signal is supplied from the spread code selection generator 33 to the spread modulator 32, and spread modulation is performed by multiplying the spread data signal by the data modulated data signal. The spread-modulated signal is frequency-converted by the frequency converter 35 by the carrier signal from the local oscillator 34 to become a radio frequency transmission signal, which is transmitted from the antenna 36.

The spreading code selection generator 33 has the same configuration as the spreading code selection generator 25, and the spreading code selection generator 33
A clock selection generator 37 is connected to. The clock selection generator 37, like the clock selection generator 30,
It has a memory 37a in which two different chip rates R1 and R2 are stored as data. In the clock selection generator 37, different chip rates are read during communication in the upward direction and during communication in the downward direction according to a selection command from a control circuit (not shown). As described above, if the chip rate R1 is used for upstream communication and the chip rate R2 is used for downstream communication, the clock selection generator 37 of the transmission system of the base station reads the chip rate R1 from the memory 37a. Issued and chip rate R1
A clock signal according to
In 3, the spread code signal indicating the spread code designated by the selection command from the control circuit is output to the spread modulator 32 in synchronization with the clock signal of the chip rate R1. On the other hand, in the clock selection generator 30 of the receiving system of the mobile station, the chip rate R2 is read from the memory 37a and a clock signal according to the chip rate R2 is generated, and the spread code selection generator 33 outputs the specified spread code. The spread code signal shown is output to the spread modulator 32 in synchronization with the clock signal of the chip rate R2.

Note that the chip rate may not be selectable in each communication device of the mobile station and the base station as in the above embodiment, but may be fixed in advance to different values in the up and down directions. Further, in each of the above-mentioned embodiments,
Although the direct spread (DS) method using BPSK has been described, the scope of application of the present invention is not limited to this, and QP
The present invention can be applied not only to the DS method using other modulation methods such as SK but also to the frequency hopping (FH) method.

If the control circuit obtains the data of the partner station by mutually notifying which spread code and chip rate each station has by using the common spread code and chip rate on the control channel. In the subsequent communication channel, it is possible to receive by using the spread code and the chip rate of the communication partner station.

[0033]

As described above, according to the present invention, the first spread code signal of the same code string is generated in each of the plurality of transmitting stations, and the spread signal is applied to the data signal according to the first spread code signal to generate the transmit signal. Even if generated, since the chip rates of the first spreading code signals are different from each other, the receiving station should change the chip rate of the second spreading code signal to the same rate as the chip rate of the first spreading code signal of the desired transmitting station. Due to
A data signal from a desired transmitting station can be extracted from the received signal. Therefore, it is possible to increase the number of users in a unit band such as a cell without further expanding the spread band or lowering the data transmission rate.

[Brief description of drawings]

FIG. 1 is a block diagram showing a transmission system of a conventional CDMA communication apparatus.

FIG. 2 is a diagram showing signal waveforms of respective parts of the transmission system of FIG.

FIG. 3 is a diagram showing a spectrum of each part of the transmission system of FIG.

FIG. 4 is a diagram showing a spectrum of each part of the reception system of FIG.

FIG. 5 is a block diagram showing a receiving system of a conventional CDMA communication apparatus.

FIG. 6 is a diagram showing an autocorrelation function of a spread code signal.

FIG. 7 is a diagram showing a cross-correlation function of a spread code signal.

FIG. 8 is a diagram showing allocation of spreading codes for each user.

FIG. 9 is a diagram showing a multiplexing structure of an FDMA system.

FIG. 10 is a diagram showing a TDMA-based multiplexing structure.

FIG. 11 is a diagram showing a multiplexing structure of a CDMA system.

FIG. 12 is a diagram showing frequency allocation in each cell when the FDMA method is applied to the cellular telephone system.

FIG. 13 is a diagram showing frequency allocation in each cell when the CDMA system is applied to the cellular telephone system.

FIG. 14 is a block diagram showing a configuration of a receiving system of the communication device according to the present invention.

FIG. 15 is a diagram showing the length of a spread code signal used for correlation calculation for each chip rate.

FIG. 16 is a diagram showing allocation of spreading codes and chip rates for each user.

FIG. 17 is a diagram showing allocation of spreading codes and chip rates in each cell when the present invention is applied to a cellular telephone system.

FIG. 18 is a diagram showing allocation of spreading codes and chip rates in each cell when the present invention is applied to a cellular telephone system.

FIG. 19 is a block diagram showing a configuration of a receiving system as another embodiment of the present invention.

FIG. 20 is a block diagram showing a configuration of a transmission system as another embodiment of the present invention.

[Explanation of symbols for main parts]

 1,31 Data modulator 2,32 Spreading modulator 13,25,33 Spreading code selection generator 15,24 Spreading demodulator 17,27 Data demodulator 28,30,37 Clock selection generator

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Claims (8)

[Claims] 1. A plurality of transmitting stations generate a first spread code signal composed of a code string of a plurality of bits, perform spread spectrum modulation on a data signal to be transmitted according to the first spread code signal, and transmit the signal. And the receiving station generates a second spreading code signal composed of the same code sequence as the first spreading code signal, and responds to the second spreading code signal with respect to the received signal obtained by receiving the transmission signal. Is a CDMA (code division multiple access) communication method using spread spectrum modulation for performing spread spectrum demodulation to restore a data signal of a desired one of the plurality of transmission stations. The generation rate of the first spreading code signal is different for each station, and the generation rate of the second spreading code signal is equal to the generation rate of the first spreading code signal of the desired station. Communication method to be. 2. The receiving station prestores a plurality of mutually different generation rates of the second spread code signal as data, selectively reads out one generation rate data from the stored data, and reads the data. 2. The communication method according to claim 1, wherein the second spread code signal is generated according to the one generation rate data. 3. The communication method according to claim 1, wherein the generation rate of the first spread code signal is fixed to a rate determined by each of the plurality of transmitting stations. 4. In a communication system using cells, transmitting stations between adjacent cells generate the first spreading code signals of different code strings, and the transmitting stations in the same cell are the same. 2. The communication method according to claim 1, wherein the first spread code signals of the code sequence of are generated at different generation rates. 5. In a communication system using cells, the plurality of transmitting stations between cells adjacent to each other generate the first spreading code signals at different generation rates, and the transmitting stations in the same cell mutually 2. The communication method according to claim 1, wherein the first spread code signals of different code strings are generated at the same generation rate. 6. The communication method according to claim 1, wherein in the communication system using cells, the generation rates of the first spread code signals are set to different rates for the base station and the mobile station. 7. A first spreading code generating means for generating a first spreading code signal composed of a code string of a plurality of bits at the time of transmission, and spread spectrum modulation for a data signal to be transmitted according to the first spreading code signal. Means for generating a transmission signal, and a second code consisting of the same code sequence as the first spread code signal
Second spreading code generating means for generating a spreading code signal, and means for restoring a data signal by performing spread spectrum demodulation on the received signal obtained by receiving the transmission signal at the time of reception according to the second spreading code signal. A communication device of a CDMA system using spread spectrum modulation, comprising: the second spread code generating means varying a generation rate of the second spread code signal. 8. The second spreading code generating means selectively selects from a first memory in which a plurality of different generation rates of the second spreading code signal are stored in advance as data, and data stored in the first memory. And a clock generating means for generating a clock signal according to the read first generation speed data and a plurality of different code strings of the second spread code signal are previously stored as data. A second memory and the second code corresponding to the read first code string data selectively from the data stored in the second memory.
8. The communication device according to claim 7, further comprising a signal generating unit that generates a spread code signal in synchronization with the clock signal.