JP2002026873A - Direct spreading complement sequence repetitive modulation type comb-teeth spectral communication system employing self-complementary sequence - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a direct spreading complement sequence repetitive modulation type comb-teeth spectral communication system employing a self- complementary sequence that can prevent appearance of a side lobe in an autocorrelation characteristic, makes a correlation value in the autocorrelation characteristic zero, limit a band of a transmission signal, and minimize deterioration in the SNR due to a noise intruded in a transmission channel. SOLUTION: A transmitter 4 is provided with two multipliers 21, 22 that multiply different spread codes with transmission data to generate a comb-teeth spread spectral signal, two route Nyquist filters 14, 24 that respectively limit a frequency band of the comb-teeth spread spectrum signal generated by the multipliers 12, 22, two multipliers 18, 28 that multiply carriers having different frequencies with output signals from the two route Nyquist filters 14, 24 and an adder 30 that sums output signals from the multipliers 18, 28 to generate a transmission signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a direct spread type complementary sequence repetitive modulation type comb comb tooth spectrum communication system.

[0002]

2. Description of the Related Art In recent years, mobile phones and PHS (Personal Han
2. Description of the Related Art In mobile communication systems such as dyphone systems, code division multiple access (CDMA) is known.
iple Access) system is being used. In this CDMA system, since the same frequency band can be used by a plurality of users, time division multiple access (TDMA:
There is an advantage that the number of users per bandwidth can be increased as compared with the Time Division Multiple Access method.

However, in the CDMA system, a receiver receives a signal addressed to another station as well as a signal addressed to its own station.
Depending on the positional relationship of the user, the signal level addressed to the own station (autocorrelation characteristic) may be lower than the signal level addressed to another station (cross-correlation characteristic), and it may be difficult to detect the signal addressed to the own station. This is known as a perspective problem in the CDMA system.
There is a direct spread complementary sequence repetition modulation type comb-toothed spectrum communication system disclosed in Japanese Patent Application Laid-Open No. 1-261448.

In this communication system, when the frequency and phase of the carrier of the signal received by the receiver and the frequency of the local oscillation signal of the receiver completely match, excellent auto-correlation characteristics and cross-correlation characteristics are obtained. Thus, the above-mentioned perspective problem can be solved.

[0005] In the above-mentioned tangent spread complementary sequence repetitive modulation type comb-toothed spectrum communication system, the frequency band of signals transmitted and received is not limited. However, from the viewpoint of effective use of the frequency band, it is preferable to limit the frequency band of the signal.

When the transmitter limits the frequency band of a transmission signal, as shown in FIG.
16), the information data d output from the transmission data generator 102 and the spreading code [A0A0A0A0] ([A1A1A) output from the spreading code generator 104 (114).
1A1]), the band is limited using a low-pass filter (LPF) 108 (118) on the baseband spread signal obtained by multiplying the baseband spread signal, or the RF output from the adder 224 as shown in FIG. There is a method of limiting the band of a signal using a band-pass filter (BPF) 226.

When the frequency band of a received signal is limited in a receiver, as shown in FIG.
4 (314), the received signal and the local oscillator signal generator 302
The baseband signal obtained by multiplying the local oscillation signal f0 (f1) output from (312) is
There is a method of limiting the band using (316) or a method of limiting the band of the received RF signal using the BPF 400 as shown in FIG.

[0008]

However, FIGS.
As shown in FIG. 5, when a filter that passes only the main lobe of the frequency spectrum of the transmission signal or the reception signal is used, interference occurs between chip points, side lobes appear in the autocorrelation characteristics, and mutual lobes appear. The correlation characteristic has a problem that the correlation value does not become zero. Further, as shown in FIG. 5, when the band of the received RF signal is limited by using the BPF, the bandwidth of the BPF needs to be wider than twice the chip rate by the frequency of the carrier. If this condition is not satisfied, there is a problem that the signal-to-noise ratio (SNR) deteriorates due to noise mixed in the transmission path. For this reason, while maintaining the correlation characteristics of the direct spread complementary sequence repetitive modulation comb in the toothed spectrum communication system disclosed in JP-A-11-261448, the transmission signal is band-limited and mixed in the transmission path. SN due to noise
It is required to minimize R deterioration.

An object of the present invention is to solve the above-mentioned conventional problems, and an object of the present invention is to prevent the appearance of side lobes in the autocorrelation characteristic and to reduce the correlation value in the cross-correlation characteristic to zero while transmitting the transmission signal. Of the present invention is to provide a direct spread complementary sequence repetitive modulation comb comb tooth spectrum communication system using a self-complementary sequence capable of minimizing the SNR degradation due to noise mixed in the transmission path by limiting the bandwidth of the comb. .

[0010]

In order to achieve the above object, the present invention provides a transmitter for a direct spread complementary sequence repetitive modulation comb-type toothed spectrum communication system using N self-complementary sequences. Multiply the data by different spreading codes,
N first multipliers for generating a comb-tooth spread spectrum signal, and N first to limit the frequency band of the comb-tooth spread signal generated by each of the first multipliers. A root Nyquist filter, N second multipliers for multiplying each of the output signals of the first root Nyquist filters by carriers having different frequencies, and an output signal of each of the second multipliers. A first adder that adds the signals to generate a transmission signal.

[0011] The present invention also provides a receiver for a direct spread complementary sequence repetitive modulation comb-toothed spectrum communication system using N self-complementary sequences for receiving a signal from the transmitter. N multiplied by different local oscillation signals to generate baseband signals, and N third multipliers that limit each of the frequency bands of the baseband signals generated by the third multipliers A second root Nyquist filter; N samplers for sampling the output signals of the second root Nyquist filters at known symbol timings; and different inverse signals for the output signals of the samplers. The apparatus includes N matched filters for correlating with a spreading code, and a second adder for adding output signals of the matched filters to derive a correlation signal.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on one embodiment shown in the drawings. FIG. 1 shows an example of the configuration of a communication system to which a direct spread complementary sequence repetition modulation comb-like toothed spectrum communication system according to the present invention is applied. The communication system 2 of the present embodiment transmits an information signal from the transmitter 4 to the receiver 6 by using a direct spread complementary sequence repetitive modulation comb-like toothed spectrum communication system using a self-complementary sequence. . Note that the number of self-complementary sequences is N (N
Can be assigned as a power of 2). In the present embodiment, a case where N = 2, that is, a case where two self-complementary sequences A0 and A1 are assigned will be described. For example, the self-complementary sequence A0 is {+1, +1, +1, -1,
+1, +1, -1, + 1}, and the self-complementary sequence A1 is {+1, -1, +1, +1, +
This is a sequence having a code length of 8 consisting of 1, -1, -1, -1.

The transmitter 4 in the communication system 2 includes a transmission data generator 8, a spreading code generator 10, a multiplier 12, a band limiting filter (root Nyquist filter) 14, a carrier generator 16, a multiplier 18, and a spreading code generator. 20, multiplier 22, band limiting filter (root Nyquist filter) 24, carrier generator 26, multiplier 28, adder 3
0, and an antenna 32.

The transmission data generator 8 outputs transmission data d (d
= ± 1) is output. The spreading code generator 10 outputs a spreading code [A0A0A0A0] obtained by repeating A0, which is one of the two self-complementary sequences, four times at a predetermined generation cycle (chip cycle) Tc. The multiplier 12 multiplies the transmission data d output from the transmission data generator 8 by the spread code [A0A0A0A0] output from the spread code generator 10 to generate a comb-tooth spread spectrum signal.

The root Nyquist filter 14 limits the band of the output signal of the multiplier 12. Frequency characteristic (transfer function) H of root Nyquist filter 14
(F) shows the root Nyquist characteristic,

(Equation 1) Becomes However, 0 <α ≦ 1.

The carrier generator 16 outputs a carrier signal f0 (frequency f0). The multiplier 18 converts the frequency of the output signal of the root Nyquist filter 14, and multiplies the output signal of the root Nyquist filter 14 by the carrier signal f0 from the carrier generator 16.

Similarly, the spreading code generator 20 converts a spreading code [A1A1A1A1] obtained by repeating A1 which is one of the two self-complementary sequences four times, into a spreading code [A0A0A].
0A0] in the same chip cycle Tc. Multiplier 2
2 is the transmission data d output from the transmission data generator 8
And the spreading code [A1 output from the spreading code generator 20.
A1A1A1] to generate a comb-tooth spread spectrum signal. The root Nyquist filter 24 limits the band of the output signal of the multiplier 22. Frequency characteristic (transfer function) H of root Nyquist filter 24
(F) shows the same root Nyquist characteristic as in the above-described equation (1). The carrier generator 26 outputs a carrier signal f1 (frequency f1). The multiplier 28 converts the frequency of the output signal of the root Nyquist filter 24,
The output signal of the root Nyquist filter 24 is multiplied by the carrier signal f1 from the carrier generator 26.

Here, focusing on the frequency spectrum of the output signal of the root Nyquist filter 14 and the frequency spectrum of the output signal of the root Nyquist filter 24,
These are comb-like spectra in which predetermined frequency components are missing. At the time of transmission, it is necessary that the frequency spectrum of the output signal of the root Nyquist filter 14 and the frequency spectrum of the output signal of the root Nyquist filter 24 do not overlap. In other words, the frequency spectrum of the output signal of the root Nyquist filter 24 needs to appear at a position where the frequency spectrum of the output signal of the root Nyquist filter 14 is missing.
Root Nyquist filter 1 is provided by multipliers 18 and 28.
It is for this reason that the frequencies of the output signals of 4, 24 are converted. Further, the carrier generators 16, 2
In 6, the frequencies of the carrier signals f0 and f1 are determined so that the frequency spectrum of the output signal of the root Nyquist filter 24 appears at a position where the frequency spectrum of the output signal of the root Nyquist filter 14 is missing.

The adder 30 adds the output signal of the multiplier 18 and the output signal of the multiplier 28. The output signal of the adder 30 is transmitted from the antenna 32 to the receiver 6.

On the other hand, the receiver 6 in the communication system 2
Is an antenna 42, a local oscillator 44, a multiplier 46,
Band limiting filter (root Nyquist filter) 48,
Sampler 50, matched filter 52, local signal generator 5
4, a multiplier 56, a band limiting filter (root Nyquist filter) 58, a sampler 60, a matched filter 62, and an adder 64.

The antenna 42 receives the signal transmitted by the transmitter 4. The local oscillator signal generator 44 outputs a local oscillator signal f0 having the same frequency (frequency f0) as the carrier signal f0 output from the carrier generator 16 of the transmitter 4. Multiplier 46
Separates one baseband signal from the received signal by multiplying the signal received by the antenna 42 by the local signal f0 from the local signal generator 44.

The root Nyquist filter 48 has the frequency characteristic H (f) shown in the above equation 1, and limits the band of the baseband signal from the multiplier 46. The sampler 50 samples the output signal of the root Nyquist filter 48 at a symbol point using the known symbol timing Ts. The matched filter 52 correlates the output signal of the sampler 50 with a despreading code [A0A0] obtained by repeating A0, which is one of the two self-complementary sequences, twice.

Similarly, the local signal generator 54 is connected to the transmitter 4
And outputs a local oscillation signal f1 having the same frequency (frequency f1) as the carrier signal f1 output from the carrier generator 26. The multiplier 56 separates one baseband signal from the received signal by multiplying the signal received by the antenna 42 by the local signal f1 from the local signal generator 54.

The root Nyquist filter 58 has the frequency characteristic H (f) shown in the above equation 1, and limits the band of the baseband signal from the multiplier 56. The sampler 60 samples the output signal of the root Nyquist filter 58 at a symbol point using the known symbol timing Ts. Matching filter 62 correlates the output signal of sampler 60 with a despreading code [A1A1] obtained by repeating A1 which is one of the two self-complementary sequences twice.

The adder 62 adds the correlation output of the matched filter 52 and the correlation output of the matched filter 62. As a result of this addition, the cross-correlation characteristic becomes zero level, indicating only the auto-correlation characteristic. Further, no side lobe appears due to the autocorrelation characteristic. Therefore, it is necessary to prevent the appearance of side lobes in the autocorrelation characteristic, limit the transmission signal band while reducing the correlation value in the cross correlation characteristic to zero, and minimize the SNR degradation due to noise mixed in the transmission path. it can.

The embodiment of the present invention has been described with reference to the drawings. However, it is apparent that the present invention is not limited to the matters described in the above embodiments, and that changes, improvements, and the like can be made based on the description in the claims.

[0027]

As described above, according to the present invention, the appearance of side lobes in the auto-correlation characteristic is prevented, the transmission signal is band-limited while the correlation value in the cross-correlation characteristic is reduced to zero, and mixed in the transmission path. SNR degradation due to noise can be minimized.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of a configuration of a communication system to which a direct spread complementary sequence repetitive modulation comb comb tooth spectrum communication system using a self-complementary sequence according to the present invention is applied.

FIG. 2 is a diagram illustrating an example of a LP on a transmitting side for a baseband spread signal.
FIG. 3 is a diagram illustrating an example of a configuration of a communication system to which a direct-spread complementary sequence repetitive modulation repetitive modulation comb-toothed spectrum communication system using a self-complementary sequence, which limits a band using F, is applied.

FIG. 3 shows a configuration of a communication system to which a direct-spread complementary-sequence repetition modulation type comb-toothed spectrum communication method using a self-complementary sequence is applied to a RF signal on a transmitting side, in which a band is limited using a BPF. It is a figure showing an example of.

FIG. 4 is a diagram illustrating a communication system in which a band is limited to a baseband signal using an LPF on a receiving side, and a direct spread complementary sequence repetitive modulation comb-like toothed spectrum communication system using a self-complementary sequence is applied. It is a figure showing an example of composition.

FIG. 5 is a communication system to which a direct-spread complementary sequence repetitive modulation comb-toothed spectrum communication system using a self-complementary sequence, in which a band is limited using a BPF for a received RF signal on a receiving side, is applied. FIG. 3 is a diagram showing an example of the configuration of FIG.

[Explanation of symbols]

 2 Communication System 4 Transmitter 6 Receiver 8 Transmission Data Generator 10 Spreading Code Generator 12 Multiplier 14 Root Nyquist Filter 16 Carrier Generator 18 Multiplier 20 Spreading Code Generator 22 Multiplier 24 Root Nyquist Filter 26 Carrier Wave Generator 28 Multiplier 30 Adder 32 Antenna 42 Antenna 44 Local signal generator 46 Multiplier 48 Root Nyquist filter 50 Sampler 52 Matching filter 54 Local signal generator 56 Multiplier 58 Root Nyquist filter 60 Sampler 62 Adder 62 Matched filter 64 adder

Claims (2)

[Claims] 1. A direct spread complementary sequence repetitive modulation comb-toothed spectrum transmitter using N self-complementary sequences, the transmission data being multiplied by different spreading codes to obtain a comb-tooth spread spectrum. N first multipliers for generating signals; N first root Nyquist filters for respectively limiting the frequency band of the comb-teeth spread spectrum signal generated by each of the first multipliers; Each of the output signals of the first root Nyquist filters is multiplied by N second multipliers for multiplying a carrier having a different frequency, and the output signals of the second multipliers are added. And a first adder for generating a comb. 2. A receiver according to claim 1, which receives a signal from the transmitter according to claim 1, which is a direct spread complementary sequence repetitive modulation comb-type tooth comb spectrum communication system using N self-complementary sequences. N third multipliers for generating a baseband signal by multiplying the received signal by different local oscillation signals, and N for limiting each frequency band of the baseband signal generated by each of the third multipliers N second root Nyquist filters, and N which samples output signals of each of the second root Nyquist filters at a known symbol timing.
Samplers, N matched filters that take correlations with different despreading codes for each of the output signals of the samplers, and the output signals of the matched filters are added to generate a correlation signal. And a second adder for deriving a comb.