JP2653421B2 - Orthogonal spread spectrum communication system, code division multiple access system and code division multiple access cellular system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an orthogonal spread spectrum communication system and a code division multiple access to which the orthogonal spread spectrum system is applied to reduce mutual interference between spread spectrum signals in a spread spectrum communication system and improve transmission characteristics. About the method.

[0002]

2. Description of the Related Art In a code division multiple access (CDMA) system using a spread spectrum (SS) communication system, transmission characteristics deteriorate due to mutual interference between spread spectrum (SS) signals and channel capacity is limited. As one of the countermeasures, the orthogonal SS communication system is used. In the conventional orthogonal SS communication system, a method using an orthogonal code composed of a Walsh function as a spread spectrum code is generally used.
(Sumiyoshi, Tanimoto, Komai: "Theoretical Study of Synchronous Spread Spectrum Multiplexing", IEICE Technical Report, CS81-11, April 1981). In addition, a method using Manchester coded orthogonal sequences (Habuchi, Hasegawa, Hakura, Haneishi: “Code division multiplexing method using Manchester coded orthogonal sequences”, IEICE Transactions, B-II, J74-B-II, No. 5, May 1991). However, a method using an orthogonal code composed of a Walsh function and a Manchester-coded orthogonal sequence generally becomes orthogonal only in a specific synchronization state.

An outline of an orthogonal SS communication system using a modified M-sequence will be described. The autocorrelation function Q (τ) of the M-sequence having the code length N is as shown in FIG. 1, and the size of the side lobe is -1 / N. However, if an appropriate DC component α is added to the transmitted and received M-sequence, the side lobe of the autocorrelation function R (τ) can be made completely zero as shown in FIG. Here, α is a document (Sumiyoshi, Tanimoto, Komai: "Theoretical study of synchronous spread spectrum multiplexing communication", IEICE Technical Report,
CS81-11, April 1981) as a function of the code length N. FIG. 2 shows an example of a modified M-sequence when N = 15 and α = 0.2. In the figure, an example of the modified M-sequence is shown by a numerical sequence and its time waveform, and is shown in a simplified manner by delimiting a temporal minimum constituent unit (chip) of the sequence.

In such a method of assigning a phase-shifted version of the modified M-sequence as a spread code of each SS signal, no mutual interference occurs between the SS signals (the spread spectrum codes are orthogonal), so that the SS signals are not synchronized. It is expected that the signals will be mutually orthogonal. However, considering the modulation by the information bits, the SS signals are orthogonal to each other only in the synchronous state.

[0005]

However, the conventional orthogonal SS communication system has a problem in that when the synchronization is easily established, the form of use is limited because the characteristics deteriorate significantly due to the loss of orthogonality in an asynchronous state. Therefore, it is an object to realize an SS communication scheme that is orthogonal even in an asynchronous state, and to remove restrictions on a usage form. Another object is to realize an orthogonal code division multiple access system by using an orthogonal SS communication system.

[0006] In order to achieve the above goal, the cause of the loss of orthogonality in an asynchronous state in an SS communication system using a modified M-sequence will first be clarified. FIG. 3 shows the state of the correlation output with respect to the timing of the spread demodulation code when the SS signal is synchronous (spread code and information bits are synchronous) and asynchronous. On the left side of the figure, the timing relationship between the information bits of the desired SS signal S (t) and the undesired SS signal U (t) and the spreading code is shown. In the figure, each signal is not indicated by its waveform, but is indicated by a bit and a chip for simplicity, and the spreading codes C _D (t) and C _U (t) of the desired SS signal and the undesired SS signal are shown. One cycle is separated by a solid line.
Here, as described above, each spread code is obtained by relatively shifting the phase of the modified M-sequence code. Incidentally, one period and the bit interval of the spreading code is coincident, the spreading code length T _C and the bit interval T _B is equal. Further, the chips as a phase reference deformable M sequence shown in black represent the phase difference (time difference) in T _P. On the right side of the figure, the correlation output between each SS signal and the spreading demodulation code C _D (t) is shown with respect to the relative timing to the spreading code. It should be noted that the correlation value other than the point where the autocorrelation peak value and the correlation value are 0 in the figure is conceptual and is not always accurate. Further, the hatching of the correlation output conceptually indicates that the correlation value differs depending on the preceding and succeeding bits (bit polarity) and the like (there is a range of values).

In FIG. 3, desired SS and spreading code C _D (t)
Takes a peak value at the synchronization timing (t _S = 0) of the spreading code. In addition, interference S in the case of bit synchronization
The correlation between S and C _D (t) is zero at t _S = 0. On the other hand, the correlation in the case of bit asynchronous (synchronous timing error t _D ) does not become 0 at t _S = 0. However, when there is no modulation by information (inversion of the polarity of the spreading code), even if a timing error occurs, the correlation becomes 0 at t _s = 0. Therefore, the loss of orthogonality in the direct spreading SS system due to the modified M sequence is due to the partial correlation between the preceding and succeeding bits and the spreading code, and can be interpreted as a kind of intersymbol interference. The loss of orthogonality due to such causes
This is a problem of the SS communication system using the modified M sequence.

The present invention devises a method of selecting a spread spectrum code and a technique of despreading a spectrum to remove such a cause of loss of orthogonality, thereby enabling an SS communication system using a modified M sequence to be asynchronously performed. The purpose is to make it orthogonal. It is another object of the present invention to orthogonalize the code division multiple access system in a quasi-synchronous state.

[0009]

In order to achieve the above object, in the orthogonal spread spectrum communication system of the present invention, (a) the spread code length is not set equal to the bit interval, but the bit interval is set to the spread code length. And (b) extending the information signal and extending the spreading code by periodic repetition of the spreading code instead of making the guard interval a non-signal interval. (C) third means for selecting and allocating a spread code group having a larger phase shift amount than the synchronization timing error of the spread spectrum signal from the modified M sequence, and (d) receiving in the spread demodulation. After establishing synchronization between the signal and the spread demodulation code, the spread demodulation code and fourth means for performing correlation processing (correlation processing with a gate) in the spread code length section can be used in an asynchronous state. It was also realized orthogonalized in.

Further, in the code division multiple access system of the present invention, (a) the maximum value of the round-trip propagation time between the base station and the mobile station is set as the synchronization timing error, the guard interval is set accordingly, and the spreading code is set. First means for selecting a group and setting the range of the correlation processing with a gate; and (b) S of mobile station transmission
Second means for making the spread code timing of the S signal dependent on the spread code timing of the code division multiplexed signal received by the mobile station in base station transmission, and (c) establishing synchronization for spread demodulation in base station reception. Utilizing the fact that the timing of the code division multiple access signal is in a quasi-synchronous relationship with the timing of the base station transmission, and using a third means realized by fine adjustment of the timing based on the transmission timing. ,
Orthogonalization is realized in quasi-synchronous state.

[0011]

When the setting of the guard section and the correlation processing with the gate are introduced, the state of the cross-correlation with the spread code when the SS signal is synchronous and asynchronous is as shown in FIG. The notation in the figure is almost the same as that in FIG.
The timing relationship of the S signal is shown. On the left side of the figure, one cycle of the spreading code is shown by a thick solid line, and bit sections are shown by a thin solid line. Where the bit interval T
_B is set to be longer than the spreading code length T _C , and the difference is the guard interval (time T _G ). The guard section is not a non-signal section but a section where the information code and the spreading code are extended. In addition, it is assumed that the spread code is subjected to periodic repetition. On the other hand, the right side of the figure shows the state of the correlation output with the spread demodulation code in the spread demodulation. In this spread demodulation, a spread demodulation code and a correlation process (gated correlation process) are performed in the _TC section. Note that a similar technique is to introduce a guard interval (B.Floch, R.Lassallele) for delay countermeasures in an orthogonal multicarrier system (OFDM) that performs demodulation by Fourier transform (FFT).
and D.Castelain, "Digital sound broadcasting to mob
ile receivers, "IEEE Trans. Consum. Electro., Vol.
35, No. 3, Aug. 1989.), but there is no example used for spread demodulation of spread spectrum signals.

Desired SS and spreading code shown on the right side of FIG.
The correlation with C _D (t) is based on the synchronization timing of the spreading code (t _S =
The peak value is taken at 0). Further, the correlation between the interference SS and C _D (t) in the case of bit synchronization is 0 at t _S = 0 and its surroundings (± _TG section). On the other hand, the correlation when the synchronization timing error t _D at bit asynchronous guard time T _G smaller becomes 0 at t _S = 0. Although the orthogonalization is possible in most cases by the above means, the phase difference between the spreading codes of the undesired SS signal and the desired SS signal is canceled by the synchronization timing error, and when the spreading codes of both are synchronized, The correlation becomes very large. This phenomenon can be avoided by selecting a spread code group from the modified M sequence such that the mutual phase shift amount is equal to or greater than the synchronization error.

Another problem is that, although orthogonalization is possible, a large correlation output with an unsynchronized undesired SS signal appears. Therefore, if the number of multiplexed SS signals increases, it becomes difficult to synchronize with the desired signal. The problem of becoming (Sumiyoshi, Tanimoto, Komai:
`` Theoretical study of synchronous spread spectrum multiplexing communication '',
IEICE Technical Report, CS81-11, April 1981
Mon) is pointed out. However, this problem is not purely a problem of synchronization of spreading codes, but a problem of channel identification or radio station identification that is regarded as being integrated with synchronization in a normal SS system. Therefore, it is possible to deal with the problem of channel identification.

Further, when the synchronization timing error is large, it is necessary to set a large guard time, and there is a problem that the number of usable orthogonal spreading codes decreases. For this reason,
From a practical point of view, the range in which the proposed method is effective is that it is used in a bit quasi-synchronous state (a state where the synchronization error is sufficiently smaller than the bit interval) and is applied to a system in which the bit quasi-synchronous state can be easily realized. Limited. However, in a satellite communication system and a mobile communication system, such a problem can be solved by a method of performing SS transmission in a mobile station in synchronization with a base station transmission SS signal.

[0015]

FIG. 5 is a block diagram showing an embodiment of an orthogonal spread spectrum communication system according to claims 1 and 2 of the present invention. The figure shows
1 shows a configuration on the transmission side (method of generating a spread spectrum signal) and a configuration on the reception side (method of demodulating a spread spectrum signal).

On the transmitting side, a code timing generator 6 generates a spread code timing signal 11 from a data clock 5 and a spread code clock generator 7.
Generates a clock signal 12 for the spreading code. Using the timing signal 11 and the clock signal 12 as time references, the spread code phase setting unit 8 sets the amount of phase shift of the spread code, and the modified M sequence generation unit 9 generates a modified M sequence. Next, the guard section code adding section 10 generates a spread spectrum code in which a guard time section code is added to the modified M sequence. On the other hand, the input information bit 1 is information-modulated by the information modulator 2, and then spectrum-spread by the spread code by the spread-spectrum modulator 3 to become a spread spectrum signal 4. Although the configuration on the transmitting side shows generation of a desired SS signal, non-desired SS signals generated by the same configuration are combined to become a reception signal.

On the other hand, on the receiving side, the desired SS
A timing synchronized with the spread code of the signal is detected, and the timing is adjusted by a timing control unit based on the detected timing.
Generates a clock signal. Next, a spread spectrum signal for spread demodulation is generated by a spread spectrum code generation section 17, and the spread demodulation section 15 performs a gated correlation process between the spread spectrum signal and the received spread spectrum signal 14 so that no mutual interference occurs. Performs spread demodulation. Here, a complex correlation is taken as the correlation, and processing for removing the influence of the carrier phase is performed. The non-desired SS signal maintains orthogonality regardless of the carrier phase difference from the desired SS signal. afterwards,
The information demodulation unit 16 demodulates information and outputs the output bit information 22
Is output.

In the method shown in FIG. 5, when establishing synchronization with the desired SS signal, there is a possibility that, in some cases, erroneous synchronization with a non-desired SS signal having a spreading code with a small mutual phase difference other than the desired SS signal may occur. Therefore, the channel identification unit 21 performs channel identification based on the output bit information, specifically, detects false synchronization, and based on the result, the timing control unit 19 adjusts the timing of the spread demodulation code until the synchronization becomes normal. The synchronization with the desired SS signal is established.

Next, an embodiment of the orthogonal spectrum communication system according to claim 3 of the present invention, in which the spread spectrum communication system is applied as a measure against multipath delay distortion, will be described. Originally, the direct spread SS method is excellent in multi-wave resistance and capable of path diversity, but has a problem of low spectrum utilization efficiency. A spreading code is selected in consideration of a delay time difference in multiplex wave propagation, and code division multiplexing is performed. As a result, the orthogonality of the code division multiplexed spread spectrum signal can be maintained in a multipath propagation environment, and the spectrum utilization efficiency can be improved.

Next, an embodiment of a code division multiple access system according to claim 4 of the present invention in which the orthogonal spectrum communication system is applied to a mobile communication system will be described.

First, FIG. 6 shows an overall configuration of a system assumed when the code division multiple access system is applied to mobile communication. The assumed system is composed of a base station and a number of mobile stations. The downlink (base station to mobile station) is code division multiplexed (CDM) in a synchronized state, and the uplink (mobile station to base station) is in a semi-synchronized state. Operates in code division multiple access (CDMA). As a CDMA spreading code, a spreading code group created by phase shift of a modified M sequence is used. In another cell, a spreading code group created from another modified M sequence is used. On the other hand, the transmission timing of the spreading code of the mobile station is synchronized with the CDM reception signal timing.
The timing error between CDMA signal of the base station reception becomes less than or equal to the maximum value T _MAX of the propagation time of the round trip between the base station and the mobile station. Bit semi-synchronous, i.e., sufficiently large shall hold than the propagation time T _MAX is the bit interval T _B of the reciprocating. Hereinafter, the configuration of the transmission / reception system for the uplink operated in quasi-synchronization will be described.

FIG. 7 shows a configuration diagram of a transmission system of a mobile station for CDMA that becomes orthogonal in quasi-synchronous manner. In the transmission system, information modulation is performed from the input information bit 1 by the information modulator 2, a spread code is generated by the spread spectrum code generator 17, and a spread spectrum signal is generated by the spread spectrum modulator 3. The timing of the spread code generated by the code clock generator 18 is controlled by the reception code clock timing 25. The generated SS signal is optionally combined with the SS signal generated by another system of spread spectrum signal generation unit and the multiplexing unit 24.
Multiplexed and transmitted.

In the spread modulation shown in FIG. 7, a guard section is set and a spread code group is selected so that orthogonality can be maintained with respect to a timing error at the time of reception at the base station. Timing error between CDMA signals received by the base station is 2
FIG. 8 shows the setting of the guard section and the selection of the spreading code group in the case of within the chip. In the figure, the modified M sequence length is 3
It is set to 1. The spreading code group is selected from M sequences having a mutual phase shift of 3 chips or more, and the number of codes is 10. The setting of the timing error within two chips is sufficiently realistic. For example, in the case of using a direct spreading SS system with a chip speed of 1 M chip / s in a micro cell having a cell radius of 300 m (maximum propagation delay of 1 μs), the timing error is within 2 chips.

FIG. 9 shows a configuration diagram of a receiving system of a base station for CDMA which is asynchronous and orthogonal. In the base station, the received spread spectrum signal is distributed by the signal distribution unit 26 and supplied from each mobile station to the spread spectrum reception unit 27 prepared for each of the multiple access SS signals. Synchronization in spread demodulation utilizes the fact that the timing of each received signal is quasi-synchronous with the transmission clock timing 28 of base station transmission.
This is realized by fine adjustment of the timing by the timing control unit 19. In some cases, a method may be considered in which the synchronization of the spreading code is separately detected by the synchronization timing detection unit 20.

The received SS signal is subjected to a gated correlation process with a spread demodulation code by a spread demodulation unit 15 and spread demodulation is performed without mutual interference. Then, the information demodulation unit 1
In step 6, information demodulation is performed, and output bit information 22 is output.
As a countermeasure against erroneous synchronization with the undesired SS signal, the channel identification unit performs channel identification based on the output bit information, and based on the result, adjusts the timing of the spread demodulation code by the timing control unit 19 to synchronize with the desired SS signal. .

The above-described embodiment of the quasi-synchronous and orthogonal code division multiple access system has been applied to a cellular system which is orthogonal in the same cell. Next, an embodiment of the code division multiple access system according to claim 4 of the present invention in which orthogonality between adjacent cells is maintained will be described. By establishing synchronization between SS communication signals transmitted from adjacent base stations, a quasi-synchronous state can be realized in the downlink, that is, in the mobile station reception. Also in the uplink, a quasi-synchronous state can be realized by making the spread code timing of the SS signal transmitted by the mobile station dependent on the spread code timing of the mobile station reception by the base station transmission. Therefore, the synchronization timing error is set to be larger than the maximum value of the round-trip propagation time difference between the base station and the mobile station, and accordingly, the setting of the guard section, the selection of the spreading code group, and the setting of the range of the gated correlation processing are performed. By doing so, orthogonalization can be realized even between adjacent cells.

Next, another embodiment of the code division multiple access system according to claim 4 of the present invention in which orthogonality between adjacent cells is maintained. When orthogonality is maintained between adjacent cells, the same desired SS signal is transmitted from the adjacent cells, and each signal is independently demodulated and diversity-combined, so that path diversity or site diversity can be reduced by mutual interference. It can be realized without getting up.

[0028]

According to the orthogonal spread spectrum communication system of the present invention, it is possible to reduce mutual interference between spread spectrum signals without assuming synchronization of the mutual signals. Improvement is possible. In addition, a countermeasure against a multipath delay distortion by the spread spectrum communication method can be realized without significantly impairing the spectrum use efficiency.

On the other hand, the code division multiple access system of the present invention can be expected to increase the channel capacity of a CDMA cellular system in the mobile communication field. Further, unlike the non-orthogonal conventional method, the "far problem" is negligible, so that the burden of transmission power control can be greatly reduced. Furthermore, it is easy to realize a quasi-synchronous and orthogonal system. In addition, it is possible to realize an orthogonal system between adjacent cells, and it is also possible to effectively realize site diversity.

[Brief description of the drawings]

FIG. 1 is a diagram of an autocorrelation function of an M-sequence code and a modified M-sequence code related to the description of the related art.

FIG. 2 is a diagram showing an example of a modified M-sequence relating to the description of the prior art.

FIG. 3 is a diagram illustrating a state of loss of orthogonality due to bit asynchronism in a modified M-sequence relating to a problem of the related art.

FIG. 4 is a diagram showing a countermeasure against loss of orthogonality in bit asynchronous operation according to the means for solving the problem of the present invention.

FIG. 5 is a configuration diagram of a transmitting side and a receiving side according to the first and second embodiments of the present invention.

FIG. 6 is a diagram of a microcell CDMA cellular system assumed to be applied in an embodiment of claim 3 of the present invention.

FIG. 7 is a configuration diagram of a CDMA transmission system of a mobile station according to an embodiment of the present invention.

FIG. 8 is a diagram showing an example of setting of a guard section and selection of a spreading code according to the third embodiment of the present invention.

FIG. 9 is a configuration diagram of a CDMA receiving system of a base station according to an embodiment of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 input bit information 2 information modulator 3 spread spectrum modulator 4 spread spectrum signal 5 clock signal 6 code timing generator 7 spread code clock generator 8 spread code phase setting unit 9 modified M sequence generator 10 guard time section code adder Reference Signs List 11 timing signal 12 clock signal 13 spread spectrum code generator 14 received spread spectrum signal 15 spread demodulator 16 information demodulator 17 spread spectrum code generator 18 code clock generator 19 timing controller 20 synchronization timing detector 21 channel identifier 22 Output bit information 23 Spread spectrum signal generator 24 Multiplexer 25 Received code clock timing 26 Signal distributor 27 Spread spectrum receiver 28 Transmitted code clock timing

Claims (5)

(57) [Claims] 1. Modified M-sequence, that is, a sequence in which a side lobe of an autocorrelation function is completely zeroed by adding a DC bias to the M-sequence in order to reduce mutual interference between spread spectrum signals. In the orthogonal spread spectrum communication system using as a spreading code, (a) a first method of introducing a guard interval by lengthening a bit interval with respect to a spreading code length instead of setting a spreading code length and a bit interval to be equal.
Means, (b) rather than to the guard interval no signal section, and a second means for extending the spreading code by a periodic repetition of the spread code, mutual from the synchronization timing error (c) spread spectrum signals Third means for selecting and allocating a spreading code group having a large phase shift amount from the modified M sequence,
(D) In spread demodulation, a received signal and a spread code length section
And fourth means for performing Dege over preparative with correlation processing, by using the orthogonal spread spectrum communication system, characterized in that orthogonality is maintained even in an asynchronous state. 2. The orthogonal spread spectrum communication system according to claim 1, wherein: (a) first means for identifying a channel from a demodulated information signal to detect erroneous synchronization; and (b) spreading in the case of erroneous synchronization. second means for fine adjustment of the timing of the demodulation codes, by using the synchronization correctly Cartesian spread spectrum communication you and establishes the desired spread spectrum signal and the spread demodulation codes in spread demodulation method. 3. The orthogonal spread spectrum communication system according to claim 1 , wherein (a) first means for selecting a spread code group in consideration of a delay time difference due to multiplex wave propagation, and (b) 2) a second means for performing spread spectrum modulation on an information signal sequence with each spread code of the selected spread code group and multiplexing the generated orthogonal spread spectrum signal , thereby improving resistance to multiplex delay distortion. Naga
Et al., Cartesian spread spectrum communication system you characterized in that to improve the information transmission rate per band used. 4. The orthogonal spread spectrum communication method according to claim 1 or 2 is applied to a mobile communication system including a base station and a plurality of mobile stations, and a downlink from the base station to the mobile station is synchronized. Thus, the uplink from the mobile station to the base station is in a semi-synchronous state , that is, although the bit is not in the synchronous state ,
Timing error from initial timing compared to bit interval
In a code division multiple access system operated in a sufficiently small state , (a) the upper limit of the synchronization timing error defined by the maximum value of the round-trip propagation time between the base station and the mobile station
Means for setting a guard section, selecting a spread code group, and setting a range of the correlation processing with a gate, and (b) setting the spread code timing of the SS signal transmitted by the mobile station to the mobile station by base station transmission. Second means for synchronizing the spread code timing of the received code division multiplexed signal, and (c) code division multiplexing
The timing of the connection signal and the timing of the base station transmission are
Specified by the maximum round-trip propagation time between the base station and mobile station
By utilizing that the timing error range that is, the synchronization establishing for the spread demodulation at the base station receiver, using a third means for realizing the fine adjustment of the timing on the basis of the transmit timing, the A code division multiple access system characterized by maintaining orthogonality in a quasi-synchronous state. 5. The code division multiple access system according to claim 4.
Is a cellular system that uses the same frequency in adjacent cells
In the code division multiple access cellular system applied to
(A) first means for mutually synchronizing spread spectrum signals transmitted from adjacent base stations in adjacent cells ; (b)
Upper limit of the synchronization timing error defined by the maximum value of the round trip propagation time difference between the base station or adjacent base station in the cell and the mobile station
A second means for setting a guard section, selecting a spreading code group, and setting a range of the correlation processing with a gate,
Third means for performing the assignment of spreading codes, including neighboring cell from the spread code group of the (c) selecting, that orthogonality including neighboring cell in a quasi-synchronization state has to be maintained with the Characteristic code division multiple access cellular system .