JP3243109B2 - Spread spectrum wireless communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spread spectrum radio communication system using a plurality of spread codes.

[0002]

2. Description of the Related Art In wireless communication, there is spread spectrum communication as a communication method excellent in interference resistance, and a method of performing spread spectrum using a plurality of spreading codes as a method of increasing an information transmission speed while keeping a processing gain constant. Was published in
3-283246. FIG. 9 is a diagram for explaining a conventional spread spectrum communication system using a plurality of spread codes. In the figure, 9A is a wireless transmitting station, and 9B is a wireless receiving station. First, the configuration of the radio transmitting station will be described. 9-1 is an information signal to be transmitted, 9-2 is a serial / parallel conversion circuit, 9-3-1 to 9-3-n are spectrum spread circuits, and 9-4. Is a combining circuit, 9-5 is a transmitter, and 9-6 is a transmitting antenna. Next, the configuration of the radio receiving station 9B will be described. 9-7 is a receiving antenna, 9-8 is a receiver, and 9-9-
1-9-9-n are spectrum despreading circuits, 9-10-
1 to 9-10-n are demodulation circuits, 9-11 is a parallel / serial conversion circuit, and 9-12 is a demodulated signal.

Next, the principle of the spectrum radio communication system will be described. In the radio transmitting station 9A, the information signal 9-
1 is inputted to the serial / parallel conversion circuit 9-2, each identical having the amount of information and the n pieces of parallel signals S ₁ to S _n having a transmission speed of 1 / n of the original signal 9-1 Is converted. This direct /
N output signals S ₁ to S _n of the parallel converter 9-2, respectively, are input to the spectrum spreading circuit 9-3-1～9-3-n, each different spreading code is multiplied, spread spectrum It is converted into n signals SS ₁ ~ SS _n which made the the. After n signals SS ₁ ~ SS _n has been made of the spread spectrum is synthesized by the synthesis circuit 9-4 in this manner, it is transmitted via the antenna 9-6 by the transmitter 9-5.

In the radio receiving station 9B, a radio signal is received by a receiver 9-8 via a receiving antenna 9-7, and the received signal is divided into n number of spectrum despread circuits 9-9-1 to 9-9-1.
9-9-n. Then, the spectrum despreading circuits 9-9-1 to 9-9-n form the spread spectrum circuits 9-3-1 to 9-3-n of the radio transmitting station 6A.
Is performed, and the resulting n output signals are demodulated by demodulation circuits 9-10-1 to 9-10-n, respectively. Then, n demodulation circuits 9-10-1 to 9-9
The output signal of -10-n is input to the parallel / serial conversion circuit 9-11.
According to the reverse procedure performed by the parallel conversion circuit 9-2, n parallel signals are combined into a serial signal and output as a demodulated signal 9-12.

FIG. 10 is a diagram showing an example of a spectrum according to the prior art. In the figure, (a) shows the spectrum of the input signals S1 to Sn of the spread spectrum circuits 9-3-1 to 9-3-n, and (b) shows the spread spectrum circuit 9-3-.
The spectrum of the output signals SS1 to SSn of 1 to 9-3-n is shown, and (c) is the spectrum of the output signal of the synthesis circuit 9-4. Here, the n signals subjected to the serial / parallel conversion have the same frequency bandwidth before the spread spectrum and the same frequency bandwidth after the spread spectrum, and therefore gain obtained by performing the spread spectrum, That is, the processing gain is also equal.

[0006]

As described above,
In the conventional spread spectrum wireless communication system, each signal constituting an information signal is transmitted under the same condition regardless of the required quality.

However, the required quality such as a bit error rate, a symbol error rate, and a frame error rate required when transmitting an information signal often differs depending on the type of each signal constituting the information signal to be transmitted. . For this reason, a situation arises in which it becomes difficult to transmit all signals under conditions that satisfy the required quality.

The present invention has been made in view of the circumstances described above, and has as its object to provide a spread spectrum wireless communication system for transmitting a plurality of information signals in a form suitable for each required quality.

[0009]

In order to solve the above-mentioned problems, according to the present invention, a radio transmitting station performs spectrum spreading on a plurality of information signals, and then adjusts power to a required quality. The power-adjusted signals are combined and transmitted.

[0010]

[0011]

That is, in the spread spectrum radio communication system according to the first aspect, the radio transmitting station has a transmission rate of V
_1, V _2, ..., different place is V _n (n is an integer of 2 or more)
For n information signals having required quality , V ₁ · K ₁ = V ₂
· K ₂ = ...... = satisfies V _n · K _n condition: spreading factor K _1,
N spread-spectrum signals by multiplying each of the spreading codes having K ₂ ,..., K _n (） 1).
(SS ₁ ~SS _n) to produce respectively, the power of each of these signals subjected to the spread spectrum (SS ₁ ~SS _n), wherein
A signal with a high required quality has a high transmission power and the required quality
Is adjusted so as to have a low transmission power, and the signals (SA _{1 to} SA _n ) whose powers have been adjusted are combined and transmitted as radio signals in the same frequency band. Then, the radio receiving station performs spectrum despreading on the radio signal received from the radio transmitting station using the plurality of spreading codes.

Further, in the spread spectrum wireless communication system according to claim 2, the radio transmission station, transmission speed information signal to be transmitted is V _1, V _2, ..., different required product is V _n
Is divided into n pieces of information signals (n is an integer of 2 or more) having quality, and each of the divided information signals is composed of n different spreading codes, V ₁ · K ₁ = V ₂・ K ₂ = ……
= Diffusivity satisfying V _n · K _n condition: _{K 1, K 2, ...,} K
_n (≠ 1) is multiplied by each of the spreading codes to obtain n spread-spectrum signals (SS ₁ to SS ₁ ).
SS _n ), and the power of each of the spread-spectrum signals (SS _{1 to} SS _n ) is calculated by the required quality.
A signal having a high transmission quality has a high transmission power and a signal having a low required quality.
The signal is adjusted to have a low transmission power, and the signals (SA _{1 to} SA _n ) whose powers have been adjusted are combined and transmitted as radio signals in the same frequency band. Then, the radio receiving station performs spectrum despreading on the radio signal received from the radio transmitting station using the plurality of spreading codes, and demodulates each signal obtained as a result of these spectrum despreading. The signals obtained by the demodulation are combined according to a procedure reverse to the procedure of dividing the information signal in the radio transmitting station.

[0014]

According to the spread spectrum radio communication system of the present invention, different required qualities supplied to the radio transmitting station are provided.
After the spread spectrum is performed in each information signal spreading factor that is inversely proportional to the speed feed their transfer to, each power, the
A signal with a high required quality has a high transmission power and the required quality
Are adjusted so as to have a low transmission power, and the signals whose powers have been adjusted are combined and transmitted as wireless signals in the same frequency band. According to this spread spectrum wireless system, by changing both the transmission power and the spreading factor, it is possible to perform transmission under conditions suitable for the required quality of each signal.

[0015]

[0016]

According to the spread spectrum radio communication system of the present invention, each information signal supplied to the radio transmitting station has a different required quality having a predetermined transmission speed V _{1 to} V _n.
It is divided into n information signal to be. Then, each of the divided information signals is subjected to spectrum spreading at a spreading rate inversely proportional to the transmission rate of each signal, and then each power is supplied to the required product.
High quality signals have high transmission power and low required quality
The signals are adjusted to have a low transmission power, and the respective signals whose powers have been adjusted are combined and transmitted as radio signals in the same frequency band. According to this spread spectrum wireless system, by changing both the transmission power and the spreading factor, it is possible to perform transmission under conditions suitable for the required quality of each signal.

[0018]

Embodiments of the present invention will be described below with reference to the drawings. A. First Embodiment (1) Configuration of Embodiment FIG. 1 is a block diagram showing a configuration of a first embodiment of the present invention. In the figure, 1A is a wireless transmitting station, and 1B is a wireless receiving station. In the wireless transmitting station 1A, 1-1 is an information signal to be transmitted, 1-2 is a serial / parallel conversion circuit, and 1-3-1 to 1-3-1.
1-3-n is a spread spectrum circuit;
4-n is a transmission power control circuit, 1-5 is a combining circuit, 1-6
Is a transmitter, and 1-7 is a transmitting antenna. In the wireless receiving station 1B, 1-9 is a receiving antenna, 1-10 is a receiver, 1-10-1 to 1-10-n is a spectrum despreading circuit, 1-11-1 to 1-11-n Is a demodulation circuit, 1
-12 is a parallel / serial conversion circuit, and 1-13 is a demodulated signal.

(2) Operation of Embodiment FIG. 2 shows a spectrum of a signal of each section of the radio transmitting station 1A. In FIG. 2, (a) shows a spread spectrum circuit 1-3-1 to 1-3-3. n input signals S _{1 to} S _n
And (b) shows a spread spectrum circuit 1-3.
Spectrum of the output signal SS ₁ ~ SS _n of -1~1-3-n, (c) the transmission power control circuit 1-4-1～1-4-
n, the spectrum of the output signal, and (d) the synthesis circuit 1-5.
Is the spectrum of the output signal of FIG. Hereinafter, the operation of this embodiment will be described with reference to FIG. 2 in addition to FIG.

[0020] Information signals 1-1, depending on the required quality, is divided into a straight / n pieces of information signals S ₁ transmission rate is equal to the parallel converter 1-2 to S _n. These information signals S ₁
ＳS _n have the same frequency bandwidth because their transmission rates are equal. Each information signal S ₁ to S _n are each inputted to a spectrum spreading circuit 1-3-1~1-3-n, a spread spectrum using mutually different spread codes is performed.
Here, since each spreading code has the same spreading factor, each of the spread spectrum circuits 1-3-1 to 1-3-3-n
Thus, signals SS _{1 to} SS _{n that} are spread in the same frequency bandwidth are obtained.

The power of the thus obtained n spread spectrum signals SS _{1 to} SS _n is controlled by transmission power control circuits 1-4-1 to 1-4-4-n. As a result, a signal having a high required quality (eg, signal SS _{1 in} FIG. 2) is converted into a signal having high transmission power (eg, signal S ₁ ).
A ₁ ), and a signal of low required quality (eg, signal SS _{n in} FIG. 2) is output as a signal having low transmission power (eg, signal SA _n ). Then, after the output signals of the transmission power control circuits 1-4-1 to 1-4-4-n are combined by the combining circuit 1-5, the combined signals are supplied to the transmitter 1-6 and transmitted from the transmission antenna 1-7 at the same frequency. It is transmitted as a band radio signal.

In the radio receiving station 1B, the received signal is input to the n despreading circuits 1-10-1 to 1-10-n, and these despreading circuits use the same spreading code as the radio transmitting station 1A. Despreading is performed, and the n output signals obtained as a result are input to demodulation circuits 1-11-1 to 1-11-n, respectively. Each output signal of the demodulation circuits 1-11-1 to 1-11-n is converted into a serial signal by the parallel / serial conversion circuit 1-12 and output as a demodulated signal.

B. Second Embodiment FIG. 3 is a block diagram showing a configuration of a second embodiment of the present invention. In the figure, 3A is a wireless transmitting station, and 3B is a wireless receiving station. In the wireless transmitting station 3A, 3-1 is an information signal to be transmitted, 3-2 is a signal dividing circuit, and 3-3-1 to 3-3-1.
3-n is a spread spectrum circuit, 3-4-1 to 3-4-4-
n is a transmission power control circuit, 3-5 is a combining circuit, 3-6 is a transmitter, and 3-7 is a transmission antenna. In the wireless receiving station 3B, 3-9 is a receiving antenna, 3-10 is a receiver, 3-10-1 to 3-10-n is a spectrum despreading circuit, 3-11-1 to 3-11-n. Is a demodulation circuit, 3-1
2 is a signal synthesis circuit, and 3-13 is a demodulated signal. The configuration of the present embodiment differs from that of the first embodiment in the following points.

A. The point that the serial / parallel conversion circuit 1-2 and the parallel / serial conversion circuit 1-12 in the first embodiment are replaced by a signal division circuit 3-2 and a signal synthesis circuit 3-12. b. A point in which spread codes having different spreading factors are used as needed in the spread spectrum circuits 3-3-1 to 3--3-n.

<Configuration Example of Signal Dividing Circuit> FIG. 4 is a diagram for explaining a signal dividing process performed by the signal dividing circuit 3-2 in the present embodiment. In this signal division processing,
Its time input information signal in (FIG. 4 (a)) is divided into a plurality of information signals D ₁ to D _n (Figure 4 (b)). Then, these information signals D _{1 to} D _n are output within a fixed time irrespective of the respective information amounts (FIG. 4C). Therefore, an information signal having a large amount of information among the divided information signals is output at a high transmission rate, and an information signal having a small amount of information is output at a low transmission rate. That each transmission speed information signal 3-1 by signal dividing circuit 3-2 in this embodiment for performing the aforementioned processing is divided into a plurality of information signals S ₁ to S _n is V ₁ ~V _n It is.

FIG. 5 shows a specific configuration example of a circuit for performing the signal division processing. In the figure, 5-1 is a serial / parallel conversion circuit, and 5-2 is a synthesis circuit. Transmission speed of 3a (bp
The signal represented by s) is converted into a signal of 2a (bps) and a
(Bps). The information signal is input to the serial / parallel conversion circuit 5-1 and converted into three signals whose transmission speeds are represented by a (bps). Two of the three signals are input to the synthesis circuit 5-2. The signal is then combined with a signal whose transmission speed is represented by 2a (bps).

(2) Operation of Embodiment FIG. 6 shows the spectrum of the signal of each part of the radio transmitting station 3A. In FIG. 6, (a) shows the spread spectrum circuits 3-3-1 to 3-3-3. n input signals S _{1 to} S _n
And (b) shows a spread spectrum circuit 3-3.
Spectrum of the output signal SS ₁ ~ SS _n of -1~3-3-n, (c) the transmission power control circuit 3-4-1～3-4-
n is the spectrum of the output signal, and (d) is the synthesis circuit 3-5.
Is the spectrum of the output signal of FIG. The operation of this embodiment will be described below with reference to FIG. 6 in addition to FIG.

The information signal 3-1 has a transmission speed of V ₁ , V ₂ ,..., V according to the required quality by the signal dividing circuit 3-2.
is divided into n information signal S ₁ to S _n, represented by _n. These information signals S ₁ to S _n has a frequency band width corresponding to each transmission speed. In FIG. 6 (a) for example, the information signals S ₁ has been output at a low transmission rate, Accordingly frequency bandwidth becomes narrower. On the other hand, the information signal _Sn is output at a high transmission rate, and therefore has a wide frequency bandwidth.

The information signals S ₁ to S _n with wide and narrow Thus the frequency bandwidth, respectively, spread spectrum circuits 3-3
Input to 1-3-3-n. Then, each of the signals S _{1 to} S _n
In contrast, spread spectrum using different spreading codes is performed. However, for an information signal having a high transmission rate and a wide frequency bandwidth (for example, the signal S _{n in} FIG. 6), a low spreading factor is used. Spread spectrum using codes is performed. On the other hand, an information signal having a low transmission rate and a narrow frequency bandwidth (for example, signal S _{1 in} FIG. 6) is subjected to spectrum spreading using a spreading code having a high spreading factor. More precisely speaking, for each information signal S ₁ to S _n having a transmission rate V ₁ ~V _n, the condition V ₁ × K ₁ = V _{2
× K 2 = ... = V n} × spectrum spread using a spreading code of spreading factor K ₁ ~K _n that satisfies the K _n is made. As a result,
From each of the spread spectrum circuits 3-3-1 to 3--3-n,
Spectrum spread signal SS1～SS _n is obtained in one and the same frequency bandwidth.

Further, paying attention to the transmission speed, the transmission rate of the spread spectrum signal SS ₁ ~ SS _n is applied to each and the transmission speed V ₁ ~V _n of the previous signal S ₁ to S _n to be spread expressed as the product of spreading factor K ₁ ~K _n. Therefore, the transmission rate of the signal SS _i after the spread spectrum is V _i × K _i
Where V ₁ × K ₁ = V ₂ × K ₂ =... = V _n × K _n , so that n spread spectrum circuits 3-3-1 to 3-3 are provided.
Transmission rate of the output signal SS ₁ ~ SS _n of -n are all equal.

[0031] n signals SS ₁ ~ SS _n it has been made of the spread spectrum obtained in this way, similarly to the first embodiment, the transmission power control circuit 3-4-1～3-4-n Each power is controlled. In FIG. 6, the signal S
S ₁ is output as a signal SA ₁ having a high transmission power,
An example in which the signal SS _n is output as a signal SA _n having a low transmission power is illustrated. Then, the output signals of the transmission power control circuits 1-4-1 to 1-4-n are combined with the combining circuit 1-1-1.
5, the signal is supplied to a transmitter 1-6, and transmitted from a transmission antenna 1-7 as a radio signal in the same frequency band.

In the radio receiving station 3B, the received signal is input to the n despreading circuits 3-10-1 to 3-10-n, and these despreading circuits use the same spreading code as the radio transmitting station 3A. Despreading is performed, and the n output signals obtained as a result are input to demodulation circuits 3-11-1 to 3-11-n, respectively. Each output signal of the demodulation circuits 3-11-1 to 3-11-n is input to a signal combining circuit 3-12, where the signal is divided by the signal dividing circuit 3-2. The signals are combined in the reverse procedure and output as a demodulated signal.

As described above, in this embodiment, each signal is transmitted in a form that satisfies each required quality by using both the adjustment of the transmission power and the setting of the spreading factor. C. Third Embodiment (1) Configuration of the Embodiment FIG. 7 is a block diagram showing the configuration of the third embodiment of the present invention. In the figure, 7A is a wireless transmitting station, and 7B is a wireless receiving station. In the wireless transmission station 7A, 7-1-1 to 7-
1-n are information signals to be transmitted, 7-2-1 to 7-2
-N is a direct spreading circuit, 7-3-1 to 7-3-n are transmission power control circuits, 7-4 is a combining circuit, 7-5 is a transmitter, 7-
Reference numeral 6 denotes a transmitting antenna. In the radio receiving station 7B, 7-7 is a receiving antenna, 7-8 is a receiver, and 7-9-
1-7-9-n are despreading circuits, 7-10-1-7-10
-N is a demodulation circuit, and 7-11-1 to 7-11-n are demodulated signals.

(2) Operation of the Embodiment In the second embodiment, one information signal is divided and spread spectrum is performed. However, in this embodiment, the transmission rate of the radio transmitting station 7A is V _{1 to} V _n. A plurality of information signals 7-1
-1 to 7-1-n are received and subjected to spectrum spreading using a spreading code having a spreading factor inversely proportional to each transmission rate, and transmitted. Also, the radio receiving station 7B
The received signal from the wireless transmitting station 7A is subjected to spectrum despreading using the same spreading code as that of the wireless transmitting station, and the demodulated signal 5-
11-1 to 5-11-n are output. That is, only the point that the information signal is not divided on the transmission side and the demodulated signal is not synthesized on the reception side is different from the second embodiment, and the other points are completely the same as the second embodiment. . FIG. 8 shows a spectrum of a signal of each unit of the radio transmitting station 7A. In FIG. 8, (a) shows information signals 7-1-1 to 7-.
1-n spectrum, (b) direct diffusion circuit 7-2-
The spectrum of each output signal SS1 to SSn of _{1 to} 7-2- _n , (c) is a transmission power control circuit 7-3-1 to 7-3-n
(D) is the spectrum of the output signal of the synthesis circuit 7-4.

D. Another Embodiment The embodiment of the present invention has been described above, but the scope of the present invention is not limited to this, and for example, the following modifications are possible.

In the third embodiment, the radio transmitting station 7A transmits a plurality of information signals 7-1-1 to 7-1-1 having transmission speeds V _{1 to} V _n.
7-1-n are received and subjected to spectrum spreading using a spreading code having a spreading factor inversely proportional to each transmission rate, and transmitted. However, a plurality of information signals are received at the same transmission rate, and the same spreading is performed. Spread the spectrum at a rate,
Only the transmission power may be adjusted according to the required quality and transmitted. In each of the above embodiments, the example in which the spread spectrum circuit and the inverse spread spectrum circuit are configured in the baseband band has been described. However, the same effect can be obtained in the circuit in the intermediate frequency band.

[0037]

As described above, according to the present invention,
Since a plurality of signals after spread spectrum are adjusted to transmit power in consideration of their respective required qualities and transmitted, each information signal having a different required quality can be transmitted so as to satisfy each required quality. effective.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a spread spectrum wireless communication system according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a spectrum of a signal of each unit in the embodiment.

FIG. 3 is a block diagram illustrating a spread spectrum wireless communication system according to a second embodiment of the present invention.

FIG. 4 is a diagram illustrating signal division processing performed in the embodiment.

FIG. 5 is a diagram illustrating a configuration example of a signal division circuit in the embodiment.

FIG. 6 is a diagram showing a spectrum of a signal of each unit in the embodiment.

FIG. 7 is a block diagram illustrating a spread spectrum wireless communication system according to a third embodiment of the present invention.

FIG. 8 is a diagram showing a spectrum of a signal of each unit in the embodiment.

FIG. 9 is a diagram illustrating a conventional spread spectrum wireless communication system.

FIG. 10 is a diagram illustrating a spectrum of a signal of each unit in a conventional spread spectrum wireless communication system.

[Description of Signs] 1-1 Information signal 1-2 Serial / parallel conversion circuit 1-3-1 1-3-n Spread spectrum circuit 1-4-1 1-4 -N ... transmission power control circuit, 1-5 ... synthesis circuit, 1-6 ... transmitter, 1-7 ... transmission antenna, 1-8 ... reception antenna, 1-9 ... receiver, 1 -10-1 to 1-10-n: despreading circuit, 1-11-1 to 1-11-n: demodulation circuit, 1-12: parallel / serial conversion circuit, 1-13: demodulated signal .

────────────────────────────────────────────────── ─── Continued on the front page (56) References JP-A-63-283246 (JP, A) JP-A-5-102943 (JP, A) JP-A-5-153086 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H04B 1/69-1/713 H04J 13/00-13/06

Claims (2)

(57) [Claims] 1. A radio transmitting station, for n information signals having different required qualities whose transmission speeds are V ₁ , V ₂ ,..., V _n (n is an integer of 2 or more), V ₁ · K _{1 = V 2 · K 2 =} ...... = V n · K n diffusion rate K ₁ to satisfy the condition _{that, K 2, ..., K n} (≠ 1)
Each generates n signals was made with the spread spectrum (SS ₁ ~ SS _n) by multiplying each of the respective spreading codes having respectively, each signal was made of these spread spectrum (SS ₁ ~
SS _n ) , and the signal with the higher required quality has a higher transmission.
The signal having low power and having low power has low transmission power.
The respective signals (SA _{1 to} SA _n ) whose powers have been adjusted are synthesized and transmitted as a radio signal in the same frequency band, and the radio receiving station receives the radio signal received from the radio transmitting station. A spread spectrum radio communication system, wherein each of the plurality of spread codes is subjected to spectrum despreading. 2. The radio transmission station transmits _n information signals to be transmitted having n different transmission qualities having transmission rates of V ₁ , V ₂ ,..., V _n (n is an integer of 2 or more).
, And each of the divided information signals has n different types of spreading codes: V ₁ · K ₁ = V ₂ · K ₂ =... = V _n · K _n spreading factor satisfies the following condition: _{K 1, K 2, ...,} K n (≠ 1)
Each generates n signals was made with the spread spectrum (SS ₁ ~ SS _n) by multiplying each of the respective spreading codes having respectively, each signal was made of these spread spectrum (SS ₁ ~
SS _n ) , and the signal with the higher required quality has a higher transmission.
The signal having low power and having low power has low transmission power.
The respective signals (SA _{1 to} SA _n ) whose powers have been adjusted are synthesized and transmitted as a radio signal in the same frequency band, and the radio receiving station receives the radio signal received from the radio transmitting station. Respectively, performing spectrum despreading using each of the plurality of spreading codes, demodulating each signal obtained as a result of these spectrum despreading, and transmitting each signal obtained by the demodulation to the information signal in the radio transmitting station. A spread spectrum wireless communication system characterized in that the signals are combined in accordance with the reverse procedure of the divided procedure.