JPH08288927A - Spread spectrum communication system and spread spectrum communication equipment - Google Patents

Abstract

PURPOSE: To increase the number of permitted speeches by reducing it that plural transmission data from the same transmitter are interfered with each other at correlation detection by a receiver. CONSTITUTION: A 0-th element signal, a 1st element signal and a 2nd element signal from a Walsh function 0-th generator 105, a Walsh function 1st generator 106, and a Walsh function 2nd generator 107 are multiplexed by a spread code from a spread code generator 101 by multipliers 108, 110, 112 and the products are used for spread codes of a synchronizing signal, speech data and a call control signal respectively. Then the synchronizing signal, the speech data and the call control signal sent from a synchronizing signal generator 102, a speech data source 103, and a call control signal processing unit 104, respectively are subject to spread operation by multipliers 109, 110, 111, the results are added by an adder 114 to generate base band data, and a carrier frequency modulator 115 modulates the generated data into data for a radio frequency band. A receiver conducts the operation symmetrical to above.

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 and a spread spectrum communication device, and more particularly to a communication system (for example, a personal communication system (PCS)) that employs a code division multiple access (CDMA) communication system. It is suitable for application to mobile communication systems such as digital cellular.

[0002]

2. Description of the Related Art A CDMA communication system is being used in various mobile communication systems with a large number of mobile stations (users) because of its high frequency effective utilization, and research and development are being actively conducted. The CDMA communication system employs a spread spectrum communication method, and spreads transmission data with a spreading code peculiar to each user and transmits the spread data.

In mobile communication, fading of a propagation path has become a problem, and initial synchronization is established on the receiving device side, and propagation path characteristics are estimated to eliminate the effects of fading and the like. Is performed. It is possible to establish initial synchronization and estimate propagation path characteristics from the signal transmitted by spreading the transmission data with the spreading code peculiar to each user, but the configuration becomes complicated and it takes a long time to establish the initial synchronization. May occur or the estimation accuracy of the propagation path characteristics may not be sufficient.

Therefore, there has already been proposed a spread spectrum communication system which also communicates a synchronization signal used for establishing initial synchronization and estimating channel characteristics (Reference 1: US Pat. No. 52).
28056).

In this patented technology, a signal obtained by spreading transmission data with a spreading code and a synchronization signal separate from the spreading code are simultaneously transmitted. This sync signal is
Spreading code to spread the transmission data is a sequence or phase different spreading code for synchronization multiplied by a constant gain (only spreading code is applied as a code sequence,
Therefore, it means that the transmitting side is always transmitting the synchronization data of the constant phase and the constant amplitude. Therefore, on the receiving side, from the value obtained by demodulating the synchronization signal for each propagation path, it is possible to estimate the change in amplitude due to fading of the propagation path, the rotation of the phase (propagation path characteristic), and to determine the synchronization phase. it can.

That is, it is possible to detect the phase rotation in the multipath propagation path by this spreading code for synchronization and perform coherent correlation detection.

[0007]

By the way, in the CDMA communication system, all or many mobile stations use the same frequency at the same time. Therefore, the signals of other users who are talking at the same time become interference waves. Basic CDMA
In the communication system, each user transmits one spread signal (a signal obtained by spreading the transmission data), but in the above system that simultaneously transmits the synchronization signal (spread code for synchronization),
Due to the transmission of the synchronization signal, the number of simultaneous callers apparently increases (doubles), and the signal-to-noise ratio (S / N ratio) of the demodulated baseband signal does not communicate the synchronization signal. Further, it is deteriorated by 3 [dB], and the probability of error during data demodulation increases. It should be noted that when the synchronization signal is used for estimating the propagation path characteristic, the probability of erroneous occurrence is alleviated to some extent.

In order to improve the S / N ratio of the demodulated baseband signal, it is conceivable to reduce the number of users accommodated in the communication system accompanied by the transmission of the synchronization signal as compared with the basic communication system. In order to compensate the above-mentioned deterioration of 3 [dB], it is necessary to reduce the number of simultaneous callers to half. Therefore, for a mobile communication system that is required to accommodate a large number of users, it is necessary to transmit a synchronization signal. It is difficult to apply the accompanying communication system.

Even when the synchronization signal is not transmitted, when the transmission data of a plurality of channels is communicated, similarly,
There is a problem of limiting the number of simultaneous calls due to the deterioration of the S / N ratio.

Therefore, the S / N of the demodulated baseband signal is
There is a demand for a spread spectrum communication system and a spread spectrum communication device capable of communicating transmission data of a plurality of channels without deteriorating the ratio.

[0011]

In order to solve the above problems, according to the first aspect of the present invention, baseband data obtained by spreading transmission data of a plurality of channels by different spreading codes respectively and then adding the baseband data is transmitted and received. In a spread spectrum communication method that is transmitted and received between devices, a characteristic is that each spreading code is obtained by multiplying an orthogonal code determined by mutually orthogonal channels by the same original spreading code.

The spread spectrum communication apparatus on the transmitting side according to the second aspect of the present invention transmits the transmission data of the corresponding channel to different orthogonal codes determined by the channels which are orthogonal to each other and the same original code unique to the apparatus. Baseband data is formed by adding the spread spectrum means for each channel that performs spectrum spreading with a product of the spread code as a spread code, and a plurality of data subjected to spread processing from the spread spectrum means for each channel. And an adding means for performing the addition.

Further, the spread spectrum communication apparatus on the receiving side according to the third aspect of the present invention is different depending on the branching means for branching the baseband data converted from the received signal into the number of channels and the channels orthogonal to each other. As a despreading code, a product of an orthogonal code and the same original spreading code unique to the transmission side spread spectrum communication device is used as a despreading code, and the spectrum of each channel is despread by multiplying the baseband data from the branching means. And a despreading means.

In the first to third aspects of the present invention, it is preferable to use, as each orthogonal code, one of the codes of the Walsh function system of period 4 which has orthogonality even with different phase shifts.

[0015]

In the first to third aspects of the present invention, the baseband data obtained by spreading the transmission data of a plurality of channels by respective different spreading codes and then adding the baseband data is transmitted and received between the transmitting device and the receiving device. As the spreading code or despreading code of the transmission data, the same spreading code or despreading code is used in the receiving device in which communication is established by using a product obtained by multiplying the same original spreading code by the orthogonal code determined by the mutually orthogonal channels. Of the S / N after despreading by reducing interference between transmission data of a plurality of channels from the transmitter of
It improves the ratio.

Here, if each of the orthogonal codes is one of the codes of the Walsh function system having the period 4 and having a different phase shift, the orthogonality is also reduced, the interference between the different channels of the different transmitters is reduced. S / after despreading
The N ratio can be further improved.

[0017]

【Example】

(A-1) First Embodiment of Spread Spectrum Transmitting Device Hereinafter, a first embodiment of a spread spectrum communication device on the transmitting side (hereinafter referred to as a spread spectrum transmitting device) according to a spread spectrum communication system according to the present invention will be described with reference to the drawings. I will explain it in detail. Here, FIG. 1 is a block diagram showing the configuration of the spread spectrum transmitter of this embodiment.

In FIG. 1, the spread spectrum transmitter of the first embodiment is a spread code generator 101, a synchronization signal generator 102, a call data source 103, a call control signal processor 104, and a Walsh function No. 0 generator. (Walsh
No. 0) 105, Walsh function first generator (W
alsh No. 1) 106, a Walsh function second generator (Walsh No. 2) 107, multipliers (exclusive OR circuits) 108 to 113, an adder 114, and a carrier frequency modulator 115.

Here, the sync signal generator 102, the call data source 103 and the call control signal processor 104 are respectively for generating a sync signal, call data and a call control signal to be used for transmission. Signals, call data, and call control signals correspond to the corresponding multipliers 109, 111,
Given to 113.

The synchronization signal is for generating a spreading code in synchronization with the demodulated baseband data on the receiving device side (sometimes used for estimating propagation path characteristics), and is serial digital data. As the synchronizing signal, it is assumed that pattern data of a predetermined cycle is repeated, but all "0" or all "1" may be used. The call data is obtained by converting a voice signal from the user into serial digital data. The call control signal is a signal for executing a call control sequence,
It is serial digital data. The 1-bit periods of the synchronization signal, the call data, and the call control signal are selected to be the same. Hereinafter, the call data and the call control signal are collectively referred to as communication data.

The spreading code generator 101 is an original spreader (unique in the sense that it includes a difference in phase offset) which is serial digital data for spreading a synchronization signal, call data and a call control signal and is unique to the transmitter. A code is generated and given to the multipliers 108, 110 and 112. For example, a PN (pseudo noise) code can be applied as the original spreading code. As is well known, the 1-bit period of the original spreading code (hereinafter referred to as 1-chip period) is selected to be significantly shorter than the 1-bit period of the synchronization signal, the call data and the call control signal.

The Walsh function No. 0 generator 105, the Walsh function No. 1 generator 106, and the Walsh function No. 2 generator 107 of this embodiment are each the 0th of the Walsh function system of the period 4 which is an orthogonal code system. No. element w0 = (0
000), the 1st element w1 = (0101), and the 2nd element w2 = (0011) are repeated serial digital data (hereinafter, respectively, the 0th element signal, the 1st element signal,
(Hereinafter referred to as the second element signal) and the corresponding multiplier 10
8, 110, 112. The bit cycle of the repetitive serial digital data of the 0th element w0, the 1st element w1 and the 2nd element w2 is selected in one chip period like the original spread code from the spread code generator 101. .

Reference 2 discloses the structure of the Walsh function system and the numbering of functions.

Reference 2: “Mobile Station-Base Station
Compatibility Standard for Dual-Mode Wideband Spre
ad Spectrum Cellular System ", IS-95 In addition, the spreading code from the spreading code generator 101 and the Walsh function No. 0 generator 105, the Walsh function No. 1 generator 106, and the Walsh function No. 2 generator 107 are used. It is naturally preferable to output the 0th element signal, the 1st element signal, and the 2nd element signal in synchronism with each other from a predetermined start phase in consideration of synchronization in the receiving device.

The multipliers 108, 110 and 112 generate the spreading code from the spreading code generating circuit 101 and the corresponding Walsh function number 0 generator 105, Walsh function number 1 generator 106 and Walsh function number 2 respectively. Bowl 10
The multipliers 109, 111 and 11 corresponding to the 0th element signal, the 1st element signal and the 2nd element signal from
3 is given. Therefore, these multipliers 108,
The spread codes from 110 and 112 are orthogonalized to each other.

Since the Walsh function No. 0 element w0 is (0000), the Walsh function No. 0 generator 105 and the multiplier 108 are replaced with an inverting circuit for inverting the spread code from the spread code generator 101. be able to. FIG. 1 shows a principle configuration example in which the features of this embodiment are easier to understand.

The multipliers 109, 111 and 113 respectively correspond to the synchronization signal generator 102 and the call data source 1 respectively.
03, synchronization signal, call data, call control signal from the call control signal processing device 104, and the corresponding multipliers 108, 11
The orthogonal signals from 0 and 112 are multiplied, and the synchronization signal, the call data, and the call control signal are spread spectrum-processed and given to the adder 114.

The adder 114 adds the output spread signals from the multipliers 109, 111 and 113 to create baseband data.

The carrier frequency modulator 115 carries out carrier modulation of this baseband data into a radio frequency band.

Therefore, in the spread spectrum transmitter constructed by each of the above parts, the spread code generator 1
For the original spreading code unique to the transmitter in the sense of including the difference in the phase offset from 01, the Walsh function No. 0 generator 105 and the Walsh function No. 1 generator 10
6. The multiplier 1 uses the 0th element signal, the 1st element signal, and the 2nd element signal from the Walsh function second generator 107.
08, 110, 112 multiplied by the synchronization signal,
As the spreading code of each of the call data and the call control signal, the sync signal, the call data, and the call control signal output from each of the sync signal generator 102, the call data source 103, and the call control signal processor 104 are used. , Multiplier 1
After being spread by 09, 110, and 111, the adder 114 adds them together to create baseband data, and the carrier frequency modulator 115 performs carrier modulation on the radio frequency band and transmits.

Next, the meaning of orthogonalizing the original spreading code using the elements of the Walsh function system as the spreading code for the transmission data (synchronization signal, call data and call control signal) of each channel Will be explained.

In the case of this embodiment, as an example of an orthogonal code system, a Walsh function system of period 4 W = {w0, w1, w2
, W3} is applied. Against natural number n, the Walsh function system is constituted by the 2 ⁿ elements having periods 2 ^n, Walsh function system W cycle 4 has a four element as described above, each element w0 , W1, w2,
w3 is represented as follows. Note that one period is indicated by ().

W0 = (0000) w1 = (0101) w2 = (0011) w3 = (0110) (1) When the inner product operation is represented by, at any two different elements w i and w j of the Walsh function system W, The inner product wi ・ w
Since j represents the total sum of the number of coincidences and non-coincidences at the same position in the cycle, it is 0 and orthogonal, and is an orthogonal code. In other words, any 2-orthogonal code (functional element)
Has a value (inner product) of 0 obtained by performing the correlation calculation for the period peculiar to the code system.

The Walsh function system element having such a property is multiplied by the original spreading code unique to the transmitter,
If the spreading code for the transmission data of each channel,
The spread signals of the transmission data of each channel are orthogonal. Therefore, when performing correlation detection using spread codes that have undergone orthogonalization processing in the receiving device, the transmission data of each channel from the same transmitting device do not become interference components with each other. In other words, the original spread code is orthogonalized using the elements of the Walsh function system (orthogonal code), and is used as the spread code for the transmission data (synchronization signal, call data, and call control signal) of each channel, so that It is possible to reduce interference at the time of correlation detection between channels from the transmitter.

Next, the significance of applying a short-period orthogonal code, which is an element (Walsh function) of the Walsh function system of period 4 (4 chip periods), will be described.

When a plurality of mobile stations equipped with the spectrum transmitter of the embodiment communicate with the same base station,
Even if each mobile station maintains synchronism, it can be regarded as a state in which transmission is performed asynchronously due to a propagation delay wave or the like. In such an asynchronous transmission state, generally, the spread signal of the synchronization signal of a certain station becomes an interference component for the spread signal of the communication data of another station. This is because the code of the synchronization signal of a certain station and the code of the spread signal of the communication data of another station are out of phase with each other, so that orthogonality is not guaranteed. In other words, two long-period orthogonal codes naturally maintain orthogonality with respect to the same amount of phase shift, but when the amount of phase shift is different, orthogonality is not guaranteed, and the station If they are different, the amount of phase shift through the propagation path is different, so that the orthogonality between the code of the synchronization signal of a certain station and the code of the spread signal of the communication data of another station is not guaranteed.

It is inevitable that synchronization signals related to the same orthogonal code and communication data become interference components due to simultaneous transmission of a plurality of stations.

In order to overcome such inconvenience, in this first embodiment, a short period orthogonal code, that is,
The elements of the Walsh function system of period 4 are applied. This is because the orthogonality code can be observed even when the phases are deviated by using the short-period orthogonal code.

Walsh function No. 0 element w0, Walsh function No. 1 element w1 and Walsh function No. 2 element w
2 are orthogonal to each other at any phase shift. This will be briefly described below. Since orthogonality is assumed based on the chip period, the phase shift is assumed to occur on a chip-by-chip basis. Further, in the following description, the inversion operation is indicated by /.

The Walsh function 0th element w0 is
As is clear from the equation (1), the odd and even chip shifts are w0. The Walsh function first element w1 is
As is clear from the above equation (1), the odd chip shift is w1 /, and the even chip shift is w1. The second element of the Walsh function w2 has an odd chip shift of w3 or w3 / and an even chip shift of w2 or w2 / as is apparent from the above equation (1). The inversion operation does not change the orthogonality. Therefore, the function set W '= {w0, w1, w2} used in this embodiment maintains the orthogonality regardless of any chip shift. The function set W '= {w0, w1 used in this embodiment
, W2}, the Walsh function No. 2 element w2 and the Walsh function No. 3 element w3 are not used as elements at the same time, because if the phase shift amounts of the two stations are different, they may be indistinguishable and may become interference components. Is.

The short-cycle Walsh function code generators 105 to 107 have an advantage that they can be easily formed into a circuit.

As described above, when the Walsh function system of period 4 which is a short period orthogonal code system is applied, the number of codes in the code system is 4, and the orthogonality at the time of phase shift can be obtained. Considering this, the number of usable codes is three, but as shown in FIG. 1, the number of channels transmitted by one transmitting station (transmitting device) is practically 3 at most, which is sufficient. The same can be said when the orthogonal code of another orthogonal code system is applied.

Therefore, according to the spread spectrum transmitting apparatus of the first embodiment, it is possible to easily establish the code synchronization in the receiving apparatus, and to follow up even if the phase of the propagation path changes due to fading after setting the communication path. You can Also,
It is possible to reduce interference by making the signal obtained by spreading the synchronization signal and the spread signal of the communication data orthogonal to each other. Interference between channels of different communication data can also be reduced. Regarding the interference with the signals from other transmitters which are not synchronized, the period of the orthogonal code system to be used is set to be short, so that it is possible to reduce the interference according to the synchronized state. .

As a result, the number of simultaneous calls of a station equipped with the spread spectrum transmitter of this embodiment can be increased to nearly double that in the conventional case.

(A-2) Second of spread spectrum transmitter
Second Embodiment FIG. 2 shows a second embodiment of the spread spectrum transmission apparatus to which the spread spectrum communication system of the present invention is applied.

The difference from the spread spectrum transmission apparatus of the first embodiment is that, with respect to the original spread code from the spread code generation apparatus 101 specific to the transmission apparatus, the synchronization signal generation apparatus 102,
A synchronization signal, call data, which is an output from each of the call data source 103 and the call control signal processing device 104, and
After multiplying the call control signal by the multipliers 108, 110, 112, the 0th element signal from the Walsh function No. 0 generator 105, Walsh function No. 1 generator 106, Walsh function No. 2 generator 107, This is the point that the first element signal and the second element signal are multiplied by the multipliers 109, 111, and 113 and given to the adder 114.

That is, only the multiplication order of the three signals to be multiplied is different, and the essential points are the same as in the first embodiment. Therefore, the same effect as that of the spread spectrum transmitter of the first embodiment can be obtained.

(A-3) Third of spread spectrum transmitter
Third Embodiment FIG. 3 shows a third embodiment of the spread spectrum transmission apparatus to which the spread spectrum communication system of the present invention is applied.

The difference from the spread spectrum transmitter of the first embodiment is that the synchronizing signal generator 102 and the multiplier 109 are omitted and the signal from the multiplier 108 is directly applied to the adder 114. The spread spectrum transmitter according to the third embodiment is equivalent to the spread spectrum transmitter according to the first embodiment to which a sync signal generator 102 that outputs all "1" sync signals is applied.

That is, the essential points of the third embodiment are similar to those of the first embodiment. Therefore, the same effect as that of the spread spectrum transmitter of the first embodiment can be obtained.

(A-4) Fourth of spread spectrum transmitter
Fourth Embodiment FIG. 4 shows a fourth embodiment of the spread spectrum transmission apparatus to which the spread spectrum communication system of the present invention is applied.

The spread spectrum transmitter of the first embodiment is
The call data and the call control signal are transmitted on different channels, but in the spread spectrum transmitter of the fourth embodiment, the call data and the call control signal are transmitted on the same communication data channel. That is, the communication data source 103A multiplexes the call data and the call control signal by time division and includes them in the same channel, and gives the communication data to the multiplier 111.

That is, the essential points of the fourth embodiment are similar to those of the first embodiment. Therefore, the same effect as that of the spread spectrum transmitter of the first embodiment can be obtained.

(B-1) First of spread spectrum receiver
First Embodiment A first embodiment of a spread spectrum communication apparatus on the receiving side (hereinafter referred to as a spread spectrum receiving apparatus) according to a spread spectrum communication system according to the present invention will be described in detail below with reference to the drawings. Here, FIG. 5 is a block diagram showing the configuration of the spread spectrum receiving apparatus of the first embodiment.

Here, the spread spectrum receiving apparatus of the first embodiment is for receiving the signal transmitted by the spread spectrum transmitting apparatus of the above-mentioned first, second or third embodiment. For the example spread spectrum transmitter,
It has a symmetrical configuration.

In FIG. 5, the spread spectrum receiver of this embodiment is a spread code generator 201, a synchronization signal processor 202, a call data processor 203, a call control signal processor 204, and a Walsh function No. 0 generator 205. , Walsh function first generator 206, Walsh function second
Number generator 207, multipliers 208 to 213, branch node 2
14 and a demodulator 215.

The demodulator 215 demodulates the received signal, which is carrier-modulated in the radio frequency band, into baseband data (more accurately, converts it into a signal in the baseband band) and demodulates it. The baseband data obtained by
9, 211, 213.

Spreading code generator 201, Walsh function No. 0 generator 205, Walsh function No. 1 generator 20
6 and the Walsh function second generator 207 are respectively
Corresponding component 101 in the spread spectrum transmitter,
It has the same code generating function as 105, 106 and 107.

Output from the spread code generator 201,
The original spread code unique to the intended spread spectrum transmitter is adapted to be provided to the multipliers 208, 210 and 212. Further, the 0th element signal, the 1st element signal and the 2nd element signal from the Walsh function number 0 generator 205, the Walsh function number 1 generator 206 and the Walsh function number 2 generator 207 are respectively It is adapted to be provided to the corresponding multipliers 208, 210 and 212.

The multipliers 208, 210 and 212 respectively have the original spreading code from the spreading code generator 201 and the corresponding Walsh function number 0 generator 205, Walsh function number 1 generator 206 and Walsh function number 2 respectively. Generator 2
No. 0 element signal from No. 07, No. 1 element signal, No. 2 element signal, and corresponding multipliers 209, 211, 2
13 is given.

The multipliers 209, 211 and 213 are respectively the demodulated baseband data from the demodulator 215 via the branch node 214 and the corresponding multipliers 208 and 21.
0, 212 and the spread code subjected to the orthogonalization processing (correlation detection) to despread the spectrum, and the obtained synchronization signal, call data, and call control signal are applied to the corresponding synchronization signal processing device. 202, a call data processing device 203, and a call control signal processing device 204.

The synchronization signal processing device 202 includes a multiplier 209.
The synchronization of various signals and codes in the receiving apparatus is established based on the synchronization signal from the. Although the signal lines are not shown when synchronization is established, the synchronization signal processing device 202 includes a spreading code generator 201, a Walsh function No. 0 generator 205, a Walsh function No. 1 generator 206, and The Walsh function second generator 207 is supplied with a control signal of the generated phase, and the carrier generator in the demodulator 215 is supplied with the phase control signal.

The call data processing device 203 processes the call data from the corresponding multiplier 211 so that the user can pronounce and output the call data.

The call control signal processing device 204 executes a call control sequence process according to the call control signal from the corresponding multiplier 213.

Therefore, in the spread spectrum receiving apparatus composed of the above respective parts, the spread code generating apparatus 2
For the original spreading code from 01, Walsh function No. 0 generator 205, Walsh function No. 1 generator 206,
The multiplier 20 receives the 0th element signal, the 1st element signal, and the 2nd element signal from the Walsh function second generator 207.
8, 210 and 212 are used as the despreading codes for the synchronization signal, the call data and the call control signal, and the demodulator 215 returns the received signal to the baseband frequency band and the despreading thereof. The codes are multiplied by the multipliers 209, 210 and 211 to perform despreading (correlation detection), and the obtained synchronization signal, call data and call control signal are processed by the corresponding sync signal processing device 202 and call data processing device 203. , To the call control signal processor 204.

The orthogonalization processing of the spreading code using the elements of the Walsh function system is used as the despreading code for the transmission data (synchronization signal, call data and call control signal) of each channel, and the period 4 The meaning of applying a short-period orthogonal code called an element of the Walsh function system (Walsh function) is, of course, exactly the same as that described for the transmission device.

Therefore, according to the spread spectrum receiving apparatus of the first embodiment, it is possible to easily establish the code synchronization and follow the propagation path phase change due to fading after the communication path is set. Further, it is possible to reduce interference by making the signal obtained by spreading the synchronization signal and the spread signal of the communication data orthogonal to each other and making the spread signals of the communication data of different channels orthogonal to each other. Regarding the interference between signals from a plurality of transmitters that are not synchronized, the period of the orthogonal code system used is set to be short, so that it is possible to reduce the interference according to the synchronized state. .

As a result, the number of simultaneous calls in the communication system using the spread spectrum receiver of this embodiment can be almost doubled as compared with the conventional one.

(B-2) Second of spread spectrum receiver
And the third embodiment It goes without saying that the spread spectrum receiver according to the spread spectrum communication system according to the present invention is not limited to that of the first embodiment, and is symmetrical to the spread spectrum transmitters of the above second to fourth embodiments. Such a spread spectrum receiver also constitutes an embodiment of the spread spectrum receiver according to the spread spectrum communication system according to the present invention.

FIG. 6 shows the configuration of the spread spectrum receiver of the second embodiment symmetrical to the spread spectrum transmitter of the second embodiment, and FIG. 7 shows the spread spectrum transmitter of the fourth embodiment. The structure of the symmetrical spread spectrum receiver of 3rd Example is shown. The configuration of the spread spectrum receiver which is symmetrical to the spread spectrum transmitter of the third embodiment is the same as that of the spread spectrum receiver of the first embodiment shown in FIG. 5 described above.

Since the operation of the spread spectrum receivers of the second and third embodiments can be easily understood, the configurations are limited to those shown in FIGS. 6 and 7, respectively, and the description of the configurations and operations will be omitted.

(C) Other Embodiments In the above embodiments, the Walsh function system is shown as the orthogonal code system, but an orthogonal code of another orthogonal code system can be used, and the same effect as the above embodiment can be obtained. Obtainable. Further, even when the Walsh function system is applied, the Walsh function system of period 4 is not limited as long as a plurality of orthogonal codes having orthogonality even with different phase shifts can be selected.

In the above embodiments, the case where the synchronization signal and the communication data are transmitted and received is shown. However, the present invention is applicable to a spread spectrum communication system, a spread spectrum transmitter, and a spread spectrum receiver for transmitting and receiving the transmission data of a plurality of channels. It can be widely applied. For example, a communication signal that does not communicate a synchronization signal but communicates call data and a call control signal on separate channels, or transmission data that is communicated for purposes other than synchronization (for example, estimation of channel characteristics) other than communication data. The present invention can be applied to certain things.

The application of the present invention is not limited to a mobile communication system such as a personal communication system or a digital cellular system, and the propagation path may be a wired system.

When the spread spectrum transmitter according to the present invention is applied to a mobile station of a mobile communication system, the combination of the channel and the orthogonal code may be the same for all mobile stations. Depending on the combination, the combination may be different. In the former case, each mobile station can be easily manufactured.

[0076]

As described above, according to the spread spectrum communication system and the spread spectrum communication apparatus of the present invention, the spread signals of the transmission data of a plurality of channels are made orthogonal to each other by using orthogonal codes, so that interference is prevented. Can be reduced,
The allowable number of simultaneous calls can be increased more than ever before.

Here, when a synchronization signal is included as transmission data of a certain channel, interference is reduced to facilitate establishment of code synchronization, and even if the phase of the propagation path changes due to fading after setting the communication path, Follow-up can be easily performed. Moreover, when the orthogonal code system to be used has a short cycle, it is possible to reduce signal interference from a plurality of transmitters that are not synchronized.

[Brief description of drawings]

FIG. 1 is a block diagram showing a spread spectrum transmitter according to a first embodiment.

FIG. 2 is a block diagram showing a spread spectrum transmitter according to a second embodiment.

FIG. 3 is a block diagram showing a spread spectrum transmitter according to a third embodiment.

FIG. 4 is a block diagram showing a spread spectrum transmitter according to a fourth embodiment.

FIG. 5 is a block diagram showing a spread spectrum receiver according to the first embodiment.

FIG. 6 is a block diagram showing a spread spectrum receiver according to a second embodiment.

FIG. 7 is a block diagram showing a spread spectrum receiver according to a third embodiment.

[Explanation of symbols]

 101, 201 Spread code generator 102 Synchronous signal generator 103 Call data source 103A Communication data source 104, 204 Call control signal processor 105, 205 Walsh function No. 0 generator 106, 206 Walsh function No. 1 generator 107, 207 Walsh function second generator 108 to 113, 208 to 213 Multiplier 114 Adder 115 Carrier frequency modulator 202 Synchronous signal processing device 203 Call data processing device 203A Communication data processing device 214 Branch node 215 Demodulator.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Atsushi Fukasawa 1-7-12 Toranomon, Minato-ku, Tokyo Oki Electric Industry Co., Ltd.

Claims (6)

[Claims] 1. In a spread spectrum communication system in which transmission data of a plurality of channels are spread by different spreading codes and then added, base band data is transmitted and received between a transmission device and a reception device. A spread spectrum communication system characterized by using a product obtained by multiplying different orthogonal codes determined by each channel being used by the same original spread code unique to the transmitting device. 2. The spread spectrum communication system according to claim 1, wherein the transmission data of the plurality of channels is a synchronization signal, call data, and a call control signal. 3. The spread spectrum communication system according to claim 1 or 2, wherein each of the orthogonal codes is a code of a Walsh function system having a period of 4 and has orthogonality even if different phase shifts are used. . 4. Spread spectrum is obtained by multiplying transmission data of a corresponding channel by different orthogonal codes determined by mutually orthogonal channels and the same original spreading code unique to the apparatus, as a spreading code. A spectrum on the transmission side, which has a spread spectrum means for each channel and an addition means for adding a plurality of data subjected to spread processing from the spread spectrum means for each channel to form baseband data. Spreading communication device. 5. A branching unit for branching the baseband data converted from the received signal into the number of channels, different orthogonal codes determined by mutually orthogonal channels, and an original unique to the spread spectrum communication apparatus on the transmitting side. A spread spectrum code on the receiving side, characterized in that it has a spread spectrum spread means for each channel for multiplying the base band data from the branch means to spread spectrum and spread the spectrum as a despread code Communication device. 6. The spread spectrum communication apparatus according to claim 4 or 5, wherein, as each of the orthogonal codes, one of the codes of the Walsh function system of period 4 which has orthogonality even with different phase shift is used. .