JP2764150B2 - Spread spectrum communication receiver and repeater - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a spread spectrum communication receiver and a relay apparatus for improving path diversity characteristics.

BACKGROUND ART In a spread spectrum communication system such as CDMA (Code Division Multiple Access), usually, a transmitting side performs a plurality of modulations, and a receiving side also performs a plurality of demodulations corresponding thereto to transmit an information code. . That is, the transmitting side converts the primary modulated wave obtained by modulating the information code with PSK or the like,
The information code is spread over a wide frequency band and transmitted by performing secondary modulation with a spreading code such as a high-speed pseudo-random code. On the other hand, the receiving side despreads (secondarily demodulates) the received signal using the same and synchronized spreading code as the transmitting side, thereby converting the received signal in a wide frequency band into an information code band. Then, primary demodulation corresponding to the primary modulation is performed to restore the original information code.

When such a spread spectrum communication method is applied to mobile communication, a signal transmitted from a base station or a mobile station is reflected by an obstacle such as a building existing on a transmission path.
For this reason, this signal is received as a multiplexed wave, but the constituent waves (delayed waves) constituting it arrive at different times. This is because the delay time of the transmission path of each delayed wave differs. If the delay time variance of the transmission path is larger than one code time (one chip time) of the spread code, on the receiving side, the fluctuation of each delay wave component extracted at the chip time interval may be treated as uncorrelated. it can. In other words, the amplitude and phase of each delayed wave component show independent fluctuations. Therefore, if the phases of these independent delayed wave components are combined and combined, or those having the maximum amplitude are selected, the average reception level can be increased. This is the well-known RAKE reception, and improvement in transmission characteristics can be expected due to the path diversity reception effect.

FIG. 1 is a block diagram showing a configuration of a conventional spread spectrum communication receiver for performing path diversity reception (RAKE reception). In FIG. 1, 1-1 to 1-N are correlators. The correlator 1-k (k = 1 to N) receives the spread spectrum signal 100 in which the pilot signal is inserted, and performs despreading for each delayed wave using the same spreading code. Here, the pilot signal is a transmission path measurement signal (sounde
r). The output of the correlator 1-k is supplied to a detector 2-k for detecting each delayed wave. Detector 2-
The output of k is supplied to the weighting circuit 3-k and the power detector 4-k. The power detector 4-k detects power for each delayed wave component and uses the detected power as a coefficient of the weighting circuit 3-k. The weighted signals are combined by the combining circuit 5. The combined signal is sent to a sign determination circuit 6 where the sign is determined. Here, when weighting is performed using all the outputs of the power detector 4-k, maximum ratio combining diversity is obtained, and selection of only the detection signal having the highest power results in selection diversity.

By the way, in the conventional spread spectrum communication system,
There were the following disadvantages.

(1) In the above-described configuration in which detection is performed independently for each delayed wave, if the signal-to-noise power ratio (SNR) or the signal-to-interference power ratio (SIR) of the delayed wave is low, the operation of the detector does not work. Become stable.

(2) In spread spectrum communication, for each information code
Since the SIR fluctuates greatly, even if weighting is performed based on the received signal power, optimal combining cannot be performed. Therefore, a sufficient diversity effect cannot be obtained.

(3) In cellular mobile communication, a plurality of radio base stations are arranged to cover a wide service area. However, a reception electric field is weak in a service area, such as in a tunnel, and communication quality is degraded. There is a place to do. In such a place, communication cannot be performed. As a countermeasure for such a blind spot, there is a method of installing a new base station, but it is not economical because the base station device and the scale are large.

(4) In order to decompose a multiplex wave into each delay wave, the delay time difference of the transmission path must be larger than one chip time, but such a delay time difference is not always obtained in all areas. For example, the bandwidth of the primary modulation is 16kHz,
The spreading code amounts to about 0.5 microsecond. Therefore, when the delay time difference of the transmission path is equal to or less than this value, the multiplex wave cannot be separated into each delay wave. For this reason, fading occurs as in TDMA, and the characteristics of CDMA are lost.

DISCLOSURE OF THE INVENTION Accordingly, an object of the present invention is to provide a relay apparatus for spread spectrum mobile communication capable of improving the communication quality of blind spots and each area while securing the excellent characteristics of the original CDMA. And

It is another object of the present invention to provide a spread spectrum communication receiver capable of performing stable detection characteristics and optimal weighting for each delayed wave component.

A relay device according to the present invention is a relay device that relays a transmission / reception signal between a mobile station and a base station of a mobile communication system that performs spread spectrum communication, wherein the first reception device receives a radio wave from the base station. An antenna, and a reception signal supplied from the first reception antenna,
A first delay unit for providing a fixed delay; and a first delay unit for transmitting an output of the first delay unit to the mobile station.
A transmitting antenna, a second receiving antenna for receiving a radio wave from the mobile station, and a receiving signal supplied from the second receiving antenna,
A second delay unit for providing a constant delay, a second delay unit for transmitting an output of the second delay unit to the base station
Wherein the delay time of the first and second delay units is set to one chip time or more of the spreading code.

The relay device further amplifies a signal output from the first delay device and supplies the amplified signal to the first transmission antenna; and amplifies a signal output from the second delay device. And a second amplifier for supplying the signal to the second transmission antenna.

The first receiving antenna and the second transmitting antenna are composed of the same antenna, and the antenna is connected to a first circulator for separating a reception signal and a transmission signal from an input of the first delay unit. Terminal and an output terminal of a second amplifier, and the second receiving antenna and the first
Are composed of the same antenna, which is connected via a second circulator for separating a received signal and a transmitted signal to an input terminal of the second delay unit and an output terminal of the first amplifier. And may be connected to.

The relay apparatus further includes: a third receiving antenna that receives a radio wave from the base station; and a receiving signal from the third receiving antenna and an output signal of the first delay unit, and A first combining unit that supplies the first amplifier, a fourth receiving antenna that receives a radio wave from the mobile station, a receiving signal from the fourth receiving antenna, and an output signal of the second delay unit. And a second synthesizing unit for synthesizing and supplying the second amplifier to the second amplifier.

The relay device further amplifies a reception signal from the first reception antenna and supplies the amplified signal to the first delay unit, and amplifies a reception signal from the second reception antenna. And a second amplifier that supplies the second delay unit.

The first receiving antenna and the second transmitting antenna are composed of the same antenna, and the antenna receives an output of the second delay unit via a first circulator for separating a received signal and a transmitted signal. And the second receiving antenna and the first transmitting antenna are connected to a terminal and an input terminal of the first amplifier, and the second receiving antenna and the first transmitting antenna comprise the same antenna, and the antenna is provided for separating a received signal from a transmitted signal. The output terminal of the first delay device and the input terminal of the second amplifier may be connected via a second circulator.

The relay apparatus further includes: a third unit that transmits an output of the first amplifier to the mobile station.
And a fourth antenna for transmitting the output of the second amplifier to the base station.
And a transmitting antenna.

A spread spectrum communication receiver according to the present invention comprises: a plurality of correlators for despreading each delayed wave of a received spread spectrum signal using the same spreading code; and each delay output from each of the correlators. A plurality of detectors for respectively detecting wave components; a plurality of weighting circuits for weighting outputs of the respective detectors by applying weighting coefficients; a combining circuit for combining outputs of the weighting circuits; A sign judgment circuit for judging the sign of the output of the combining circuit; and estimating means for estimating each transfer function of the transmission path for each of the delay wave components based on the output of the sign judgment circuit and the output of each correlator. And a weighting coefficient control circuit that estimates the amplitude of only the desired wave component for each of the delayed wave components based on the estimated transfer functions, and forms the weighting coefficient based on the amplitude. The features.

The estimating means includes a plurality of multipliers that multiply the output of the sign determination circuit by the estimated transfer functions, and a plurality of multipliers that take a difference between each output of the correlator and each of the multipliers and output as an estimation error. The image processing apparatus may further include a subtractor, and an arithmetic circuit that performs an adaptive algorithm for sequentially estimating the transfer functions from the output of the sign determination circuit and the estimation error output from the subtractor.

The weighting coefficient control circuit may use a square of the estimated absolute value of each transfer function as a weighting coefficient for each of the delay wave components.

The weighting coefficient control circuit may determine the weighting coefficient based on a ratio between an amplitude of a desired wave component for each of the delayed wave components and the estimation error.

A spread spectrum communication system according to the present invention, a relay device that relays a transmission / reception signal between a mobile station and a base station of a mobile communication system that performs spread spectrum communication,
A spread spectrum communication system provided in the mobile station and the base station, and comprising a spread spectrum communication receiver for receiving a transmission signal from the relay device, wherein the relay device receives a radio wave from the base station. A first receiving antenna, and a received signal supplied from the first receiving antenna,
A first delay unit for providing a fixed delay; and a first delay unit for transmitting an output of the first delay unit to the mobile station.
A transmitting antenna, a second receiving antenna for receiving a radio wave from the mobile station, and a receiving signal supplied from the second receiving antenna,
A second delay unit for providing a constant delay, a second delay unit for transmitting an output of the second delay unit to the base station
And a delay time of the first and second delay units is set to be equal to or longer than one chip time of a spread code, and the spectrum communication receiver, for each delayed wave of the received spread spectrum signal, A plurality of correlators for performing despreading using the same spreading code, a plurality of detectors for detecting each of the delayed wave components output from each of the correlators, and weighting the output of each of the detectors A plurality of weighting circuits for performing weighting by applying a coefficient; a combining circuit for combining the outputs of the weighting circuits; a sign determining circuit for determining the sign of the output of the combining circuit; and an output of the sign determining circuit. Estimating means for estimating each transfer function of the transmission path for each of the delay wave components based on the output of each of the correlators; and estimating means for each of the delay wave components based on the estimated transfer functions. Wave component only Estimate the width, characterized by comprising a weighting coefficient control circuit for forming said weighting factor by its amplitude.

According to the present invention, the signal transmitted from the relay device includes:
Delay dispersion greater than one chip time is forced. For this reason, a RAKE reception effect is obtained, dead areas can be eliminated, and transmission quality in the area can be improved.

In a spread spectrum communication receiver that performs path diversity combining (RAKE reception), detection and weighting are performed using the result of code determination of a signal after diversity combining. That is, detection and weighting are performed using the desired power or SIR estimated using the result of the code determination. As a result, compared to the conventional technology that simply weighted the received power, which is the sum of the desired signal and the interference signal, a stable detection result can be obtained, and the characteristics are improved by the path diversity reception. can do.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a configuration example of a conventional spread spectrum communication receiver for performing path diversity (RAKE) reception.

FIG. 2 is a block diagram showing one embodiment of the spread spectrum communication relay apparatus according to the present invention.

3A and 3B are block diagrams showing another embodiment of the spread spectrum communication relay apparatus according to the present invention.

FIG. 4 is a block diagram showing one embodiment of a spread spectrum communication receiver adopting the RAKE receiving method according to the present invention.

FIG. 5 is a block diagram showing a specific configuration from the detector of the embodiment of FIG. 4 to the code determination circuit.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Embodiment 1 FIG. 2 is a block diagram showing an embodiment of a mobile communication system according to the present invention.

In the figure, a base station 10 covers an area (wireless zone) 9 and performs CDMA communication with mobile stations 16 and 17 in the area 9. The base station 10 includes a transmission / reception antenna 11 and a radio device 12, and is connected to an exchange 14 via a multiplex line 13. The relay device 20 according to the present invention is installed in a blind spot or an area where transmission quality is desired to be improved.

The relay apparatus 20 includes base station antennas 21 and 22, and mobile station antennas 28 and 29. Antenna 21
And 28 are for both transmission and reception, and antennas 22 and 29 are for reception only. Radio waves transmitted from base station 10 at carrier frequency f2 are received by antennas 21 and 22. The received wave S1 of the antenna 21 is supplied to a combiner 25 through a circulator 23 for separating transmission and reception and a delay unit 24. here,
The delay unit 24 gives the received wave S1 a delay equal to or longer than the code time (chip time) of the spread code sequence of the spread spectrum communication, and supplies the delayed signal S1d to the combiner 25. Meanwhile, antenna 2
The second received wave S2 is supplied directly to the combiner 25 and is combined with the signal S1d. This composite signal is amplified by the amplifier 26,
As S3, the signal is guided to the mobile station antenna 28 via the transmission / reception circulator 27 and transmitted to the mobile station.
As described above, the combined signal S3 of the signal S1d delayed by the delay unit 24 and the signal S2 without delay is transmitted from the relay device 20.

The radio wave transmitted from the antenna 28 of the relay device 20 is received by the transmission / reception antenna 31 of the mobile station 16. This antenna 31
Further receives the radio wave transmitted from the transmission / reception antenna 11 of the base station 10. That is, the mobile station 16
The three signals of the signal delayed at 20, the signal not delayed, and the signal directly transmitted from the base station 10 are received. These signals are transmitted to the radio 32 of the mobile station 16.
Supplied to The radio 32 performs secondary demodulation (despreading) by taking a correlation with the assigned spreading code, and after receiving RAKE,
First-order demodulation is performed to obtain data transmitted from the base station 10 to the mobile station 16.

On the other hand, the transmission data from the mobile station 16
Next, the signal is secondarily modulated and transmitted from the transmitting / receiving antenna 31 as a radio wave having the carrier frequency f1. This radio wave is transmitted to the relay device 20
At the mobile station antennas 28 and 29. antenna
The 28 received waves S5 are supplied to a combiner 36 through a circulator 27 for transmission / reception separation and a delay unit 35. Here, the delay unit 35 gives the received wave S5 a delay longer than the code time (chip time) of the spread code sequence of the spread spectrum communication, and supplies the delayed signal S5d to the combiner 36. On the other hand, the received wave S6 of the antenna 29 is directly supplied to the combiner 36 and combined with the signal S5d. This synthesized signal is amplified by the amplifier 37, and the signal S7
Are transmitted to the base station antenna 21 via the transmission / reception circulator 23 and transmitted to the base station. As described above, from the relay device 20, the combined signal S7 of the signal S5d delayed by the delay unit 35 and the signal S6 without delay is transmitted from the base station 10
Sent to

The radio wave transmitted from the antenna 21 of the relay device 20 is received by the transmission / reception antenna 11 of the base station 10. This antenna 11
Further receives the radio wave transmitted from the transmission / reception antenna 31 of the mobile station 16. That is, the base station 10
The three signals of the signal delayed at 20, the signal not delayed, and the signal transmitted directly from the mobile station 16 are received. These signals are transmitted to the radio 12 of the base station 10.
Supplied to The radio device 12 performs secondary demodulation (despreading) by taking a correlation with the assigned spreading code, and after receiving RAKE,
Primary demodulation is performed to obtain data transmitted from the mobile station 16 to the base station 10.

Thus, by setting each delay time of the delay units 24 and 35 to be equal to or longer than the chip time of the spread spectrum code,
A sufficient RAKE reception effect can be obtained for signals received through two or more signal paths.

In the relay device of the first embodiment, two reception antennas and one transmission antenna are used for each of the base station and the mobile station, but the present invention is not limited to this. For example, 3
One or more receiving antennas and one or more transmitting antennas may be combined. The point is that for the same received signal, there are provided a plurality of signal paths from the receiving antenna to the transmitting antenna, and a delay equal to or longer than the chip time of the spread code is given to these signal paths.

Alternatively, contrary to the first embodiment, one receiving antenna and two transmitting antennas may be used. The second embodiment is a relay device having such a configuration.

Second Embodiment FIG. 3A is a block diagram illustrating a configuration of a second embodiment. In the figure, antennas 21 and 22 are base station antennas, and antennas 28 and 29 are mobile station antennas. Also, antennas 21 and 28 are transmission-only antennas,
The antennas 22 and 29 are both transmitting and receiving antennas. The reception wave S1 of the antenna 22 is transmitted to the circulator 23 and the amplifier.
The signal is supplied to an antenna 28 via 26 and transmitted to a mobile station. The received wave S1 output from the amplifier 26 is
Delayed by the delay unit 24. The delayed signal S1d is supplied to the antenna 29 via the circulator 27 and transmitted to the mobile station. In this way, the relay apparatus 20 transmits the delayed signal S1d and the signal S1 that has not been delayed to the mobile station. The delay time of the delay unit 24 is set to one chip time or more, as in the first embodiment.

On the other hand, the received wave S5 of the mobile station antenna 29 is supplied to the antenna 21 via the circulator 27 and the amplifier 37, and transmitted to the base station. The received wave S5 output from the amplifier 37 is delayed by the delay unit 35. The delayed signal S5d is supplied to the antenna 22 via the circulator 23 and transmitted to the base station 10. in this way,
From the relay device 20, the delayed signal S5d and the signal S5 that has not been delayed are transmitted to the base station 10. The delay time of the delay unit 35 is set to one chip time or more, as in the first embodiment.

When the relay devices of the first and second embodiments are used in blind spots, they are installed at points where the blind spots can be seen. These relay devices receive and amplify a transmission wave from a base station and transmit it to a blind spot. In addition, the mobile station receives and amplifies a transmission wave from a mobile station in a blind area and transmits the amplified signal to the base station. These relay devices have a plurality of signal paths between a receiving antenna and a transmitting antenna, and forcibly generate and transmit a multiplex using a delay unit. Since these multiplex waves have a time lag of one chip time or more, they are decomposed by RAKE reception,
Their phases can be aligned. Therefore, it is possible to perform communication while maintaining good quality by the RAKE reception effect in the mobile station and the base station both in the blind spot and in the further places.

Third Embodiment In the first and second embodiments, two series of signals, a delayed signal and a non-delayed signal, are generated and transmitted in the relay device 20. However, considering that there is a signal directly transmitted and received between the base station 10 and the mobile station 16 in a place other than the blind spot, the relay apparatus 20 creates and transmits only a delayed signal. However, two sequences of signals are obtained on the receiving side. Therefore, if such a relay device is installed in a place other than the blind spot, the transmission characteristics can be considerably improved.

FIG. 3B is a block diagram showing such a relay device. In the figure, antenna 21 is a base station antenna, and antenna 29 is a mobile station antenna. These antennas 21 and 29 are both transmitting and receiving antennas.

The received wave S1 of the base station antenna 21 is
Is supplied to the delay unit 24 via the. The delay unit 24 outputs this signal
A delay of one chip time or more is given to S1 and supplied to the amplifier 26. The amplifier 26 amplifies this signal S1d, supplies it to the antenna 29 via the circulator 27, and transmits it to the mobile station.

On the other hand, the received wave S5 of the mobile station antenna 29 is supplied to the delay unit 35 via the circulator 27. The delay unit 35 gives the signal S5 a delay of one chip time or more, and supplies it to the amplifier 37. The amplifier 37 amplifies this signal S5d, supplies it to the antenna 21 via the circulator 23, and transmits it to the base station.

The device of this embodiment is used in a place other than a blind spot.
For example, it is used in a place where communication of a voice signal can be sufficiently performed, but improvement of a reception error rate of a data signal is required. In this case, the mobile station receives the direct wave from the base station and the delayed wave from the antenna 29 of the relay device, performs secondary demodulation, RAKE reception, and primary demodulation, and performs data demodulation from the base station. Get. On the other hand, the base station receives the direct wave from the mobile station and the delayed wave from the antenna 21 of the relay device,
RAKE reception and primary demodulation are performed to obtain data from the mobile station. Thereby, the error rate of data transmission can be reduced. It goes without saying that the relay devices of the first and second embodiments can also be used in such a place.

In mobile communication, there is a great difference in the reception level of radio waves transmitted from each mobile station to a base station. This is because the distance between the mobile station and the base station is greatly different, and a multiplex transmission path is formed by reflection of a building or the like.
For this reason, the base station needs to control the transmission level on the mobile station side so that the reception level from each mobile station matches the reference level. When the relay device of the present invention is used, a signal that has passed through the relay device and a signal that has come directly are automatically combined by RAKE reception, and the transmission level on the mobile station side is automatically controlled with the combined wave level. So you can
There is an advantage that it is not necessary to be conscious of whether or not the relay device is installed.

Next, a receiver that can perform good RAKE reception by combining with such a relay device will be described.

Embodiment 4 FIG. 4 is a block diagram showing an embodiment of a spread spectrum communication receiver according to the present invention. This receiver also employs the RAKE reception method, like the conventional receiver shown in FIG. 1, but differs in the following points.

(1) Instead of the detector 2-k (k = 1 to N), a detector
42-k is used.

(2) A weighting coefficient control circuit 40-k is provided instead of the power detector 4-k.

(3) The output of the code determination circuit 6 is supplied to the detector 42-k and the weighting coefficient control circuit 40-k, and is used as a reference for detection and weighting.

In the receiver of FIG. 4, each delayed wave ik output from each correlator 1-k is supplied to a detector 42-k, and is detected for each delayed wave. The output of the detector 42-k is supplied to a weighting coefficient control circuit 40-k, where a weighting coefficient is calculated for each delay wave component. That is, the weighting coefficient control circuit 40-k compares the sign determination result with the detector output, detects a desired wave component included in the detector output, and determines the weighting coefficient, as described later in detail. decide. As a method of determining the weighting coefficient, weighting by a desired wave component or weighting by SIR is used. The signals weighted by the weighting coefficients thus obtained are synthesized by the synthesizing circuit 5, and the sign judgment circuit 6 judges the sign.

FIG. 5 is a block diagram of the detector 42 to the sign determination circuit 6 shown in FIG.
FIG. 3 is a circuit diagram showing a more specific configuration. In the figure, reference numeral 43 (43-1 to 43-N) is a circuit in which the detector 42 and the weighting coefficient control circuit 40 shown in FIG. Each element 43-k is divided into a subtractor 51, multipliers 52, 5
3, and an arithmetic circuit 54. The arithmetic circuit 54 includes a memory storing an adaptive algorithm and a subtraction circuit.

Here, the signal e ^j.phi amplitude 1 transmission signal, the transfer function of the transmission path when the Z _r, the received signal is represented by Z _r × e ^jΦ. The transfer function Z _r represents the variation of the rotation and amplitude of the phase due to fading. The goal of the adaptive algorithm is to estimate the transfer function Z _k such that Z _k = Z _r (k = 1 to N)
It is to get. In other words, by obtaining the estimated error _{e k = (Z r -Z k} ) e jΦ is minimized Z _k. Hereinafter, a procedure for sequentially estimating the optimum Z _k from the judgment value fed back from the sign judgment circuit 6 and the estimation error e _k will be described. The details of this method are described in Simon Haykin, “Adaptive Filter Theory”, Pre
ntice Hall, 1986, (ISBN0-13-004052-5) pp. 381-3
85.

(1) by the multiplier 52, the input signal ^{_{i = Z r × e jΦ 1}} /
Multiplying the Z _k. The result is e _k = (Z _r / Z _k ) e ^jΦ . If the estimation is complete, _Zr = _Zk , and the transmission signal e ^{j Φ} is obtained. In practice, the estimation is incomplete due to noise or the like.

(2) The output of the multiplier 52 is supplied to the weighting circuit 3-k,
Weighting is performed using the square | Z _k | ² of the absolute value of the estimated transfer function Z _k as a weighting coefficient. As a result, maximum ratio combining diversity is executed.

(3) the output ^Z _r Z _k ^* e jΦ of each weighting circuit 3-k, adds the synthesizing circuit 5. As a result, a weighted combination, which is a condition of the maximum ratio combining diversity, is performed.

(4) The sign of the output of the synthesis circuit 5 is judged by the sign judgment circuit 6. If there is no bit error, ^ejΦ is obtained.

(5) The estimated received signal is created by the multiplier 53. That is, the output of the sign determination circuit 6 is multiplied by the estimated transfer function Z _k ,
The product Z _k × ^ejΦ is used as an estimated reception signal.

(6) The subtracter 51 subtracts the estimated received signal Z _k × e ^jΦ from the input signal Z _r × e ^jΦ to obtain the estimation error e _k .

(7) Update the estimated transfer function Z _k so that the estimated error e _k is further reduced. This is a recursive least squares method (RL
This is performed using an adaptive algorithm according to S). In addition,
Other adaptive algorithms can be used.

(8) Returning to the above (1), the same processing is repeated.

Thus, the transfer function Z _r of transmission lines by the adaptive algorithm is estimated, the estimated value Z _k is determined. The larger the ratio of the detection output of each delayed wave to the result of the code determination for a given delayed wave, the larger the desired wave component is contained in the delayed wave. Estimate Z _k is intended to represent the ratio of the detection output of each delay wave with respect to the code decision result indicates the magnitude of the desired signal component contained in the delayed wave. Accordingly, by using the estimated value Z _k, it is possible to measure the SNR or SIR for each delayed wave. In the present invention, since to perform weighting using the estimated value Z _k, than weighting by the conventional detector output of power, it is possible to perform appropriate weighting. As a result, characteristics can be improved by RAKE reception.

In this embodiment, since the delay detection or the synchronous detection is used, the phase of the initially received information symbol is uncertain and cannot be demodulated. However, in the case of the delay detection method, a preamble which is a known information symbol is usually sent, and thus the preamble code may be input as a determination result to be returned to the detector 42. In the case of the synchronous detection method, a known pilot signal having a length of one symbol or more to be inserted to obtain the absolute phase of the received signal may be used. That is, the code of the pilot signal may be fed back to detector 42 as the determination result.

In the above embodiment, the weighting circuit 3-i
Is supplied with the square of the absolute value of the estimated transfer function Z _k | Z _k | ² , thereby performing weighting with the power of the desired desired wave. However, the present invention is not limited to this. For example, the square of the absolute value of the estimated transfer function Z _k | a ² | Z _k | square of ² the absolute value of the estimation error e _k | e _k | ² divided by the value ^{_{| Z k | 2 / | e}} k If used, it can be weighted by SIR.

Further, if the above-described relay device according to the present invention is combined with this receiver, good communication can be performed between a mobile station and a base station in a blind spot.

Continuation of the front page (72) Inventor Tomohiro Toi 9-2-2-12 Sugita, Isogo-ku, Yokohama-shi, Kanagawa Prefecture Tomioka First Single Dormitory A-408 (56) References JP-A-2-4032 (JP, A) 1-1103336 (JP, A) JP-A-63-74234 (JP, A) US Pat. No. 4,550,414 (US, A) US Pat. No. 4,291,410 (US, A) IEICE Technical Report Vol. 92, No. 446 (SST92-70) "Weighted average RAKE method with forgetting factor and its simplification" (58) Fields investigated (Int. Cl. ⁶ , DB name) H04J 13/00 H04B 7/15 H04B 7/26

Claims (21)

(57) [Claims] 1. A relay device for relaying a transmission / reception signal between a mobile station and a base station of a mobile communication system performing spread spectrum communication, comprising: a first receiving antenna for receiving a radio wave from the base station; A first delay unit that applies a fixed delay to a reception signal supplied from the first reception antenna; a first transmission antenna that transmits an output of the first delay unit to the mobile station; A second receiving antenna that receives a radio wave from a mobile station; a second delay unit that applies a fixed delay to a received signal supplied from the second receiving antenna; and an output of the second delay unit. And a second transmitting antenna for transmitting to the base station, wherein a delay time of the first and second delay units is set to be equal to or longer than one chip time of a spreading code. 2. The relay apparatus further includes: a first amplifier for amplifying a signal output from the first delay unit and supplying the amplified signal to the first transmission antenna; and an output from the second delay unit. The relay device according to claim 1, further comprising: a second amplifier that amplifies the obtained signal and supplies the amplified signal to the second transmission antenna. 3. The first receiving antenna and the second transmitting antenna are composed of the same antenna, and the antenna is connected to the first antenna via a first circulator for separating a received signal and a transmitted signal. And the second receiving antenna and the first transmitting antenna are connected to the input terminal of the delay unit and the output terminal of the second amplifier, and the second receiving antenna and the first transmitting antenna are the same antenna. Second for separation
3. The relay device according to claim 2, wherein the relay device is connected to an input terminal of the second delay device and an output terminal of the first amplifier via the circulator. 4. The relay device further includes: a third receiving antenna for receiving a radio wave from the base station; and a receiving signal from the third receiving antenna and an output signal of the first delay unit. First combining means for combining and supplying the combined signal to the first amplifier; a fourth receiving antenna for receiving a radio wave from the mobile station; a receiving signal from the fourth receiving antenna and the second delay 4. A relay device according to claim 3, further comprising: a second synthesizing unit for synthesizing an output signal of the amplifier and supplying the synthesized signal to the second amplifier. 5. The relay apparatus further comprises: a first amplifier for amplifying a reception signal from the first reception antenna and supplying the amplified signal to the first delay unit; and a reception from the second reception antenna. The relay device according to claim 1, further comprising: a second amplifier that amplifies a signal and supplies the amplified signal to the second delay device. 6. The first receiving antenna and the second transmitting antenna comprise the same antenna, and the antenna is connected to the second antenna via a first circulator for separating a received signal and a transmitted signal. And the second receiving antenna and the first transmitting antenna are connected to the output terminal of the delay unit and the input terminal of the first amplifier, and the second receiving antenna and the first transmitting antenna are the same antenna. 6. The relay according to claim 5, wherein the relay is connected to an output terminal of the first delay unit and an input terminal of the second amplifier via a second circulator for separating the signal. apparatus. 7. The relay device, further comprising: a third transmitting antenna for transmitting an output of the first amplifier to the mobile station; and a fourth transmitting antenna for transmitting an output of the second amplifier to the base station. The relay device according to claim 6, further comprising: a transmission antenna. 8. A plurality of correlators for despreading each delayed wave of a received spread spectrum signal using the same spreading code, and detecting each delayed wave component output from each correlator. A plurality of detectors, a plurality of weighting circuits for performing weighting by applying a weighting coefficient to the output of each of the detectors, a combining circuit for combining the outputs of the weighting circuits, and an output of the combining circuit. A code determination circuit that performs a code determination; an estimation unit that estimates each transfer function of a transmission path for each of the delayed wave components based on an output of the code determination circuit and an output of each of the correlators; A weighting coefficient control circuit for estimating the amplitude of only the desired wave component for each of the delayed wave components based on the respective transfer functions, and forming the weighting coefficient based on the amplitude. Diffusion Shin receiver. 9. A plurality of multipliers for multiplying an output of the sign determination circuit by each of the estimated transfer functions,
A plurality of subtractors that take the difference between each output of the correlator and each of the multipliers and output as an estimation error; and the transfer functions from the output of the sign determination circuit and the estimation error output from the subtractor. 9. The spread spectrum communication receiver according to claim 8, further comprising: an arithmetic circuit for performing an adaptive algorithm for successive estimation. 10. The spread spectrum communication reception according to claim 9, wherein said weighting coefficient control circuit sets a square of an absolute value of each of said estimated transfer functions as a weighting coefficient for each of said delayed wave components. Machine. 11. The weighting coefficient control circuit determines the weighting coefficient based on a ratio between the amplitude of a desired wave component and the estimation error for each of the delayed wave components. 10. The spread spectrum communication receiver according to 9. 12. A relay device for relaying a transmission / reception signal between a mobile station and a base station of a mobile communication system for performing spread spectrum communication, and a transmission signal provided in the mobile station and the base station and transmitted from the relay device. A spread spectrum communication system comprising a spread spectrum communication receiver for receiving radio waves, wherein the relay device receives a radio wave from the base station.
, A first delay unit that applies a fixed delay to a reception signal supplied from the first reception antenna, and a first transmission that transmits an output of the first delay unit to the mobile station. An antenna; a second reception antenna for receiving a radio wave from the mobile station; a second delay unit for providing a fixed delay to a reception signal supplied from the second reception antenna; A second transmission antenna for transmitting the output of the transmitter to the base station, wherein the delay times of the first and second delay units are set to one chip time or more of a spreading code, A plurality of correlators for despreading each delayed wave of the received spread spectrum signal using the same spreading code; and a plurality of detections for detecting each delayed wave component output from each of the correlators. And each of the detectors A plurality of weighting circuits for performing weighting by applying a weighting coefficient to the output; a combining circuit for combining outputs of the weighting circuit; a sign determining circuit for determining a sign of an output of the combining circuit; Estimating means for estimating each transfer function of a transmission path for each of the delay wave components based on an output of a circuit and an output of each of the correlators; and each of the delay waves based on the estimated transfer functions. A weighting factor control circuit for estimating the amplitude of only the desired wave component for each component and forming the weighting factor based on the amplitude. 13. The relay apparatus further includes: a first amplifier for amplifying a signal output from the first delay unit and supplying the amplified signal to the first transmission antenna; and an output from the second delay unit. 13. The spread spectrum communication system according to claim 12, further comprising: a second amplifier that amplifies the obtained signal and supplies the amplified signal to the second transmission antenna. 14. The first receiving antenna and the second transmitting antenna are composed of the same antenna, and the antenna is connected to the first antenna via a first circulator for separating a received signal and a transmitted signal. And the second receiving antenna and the first transmitting antenna are connected to the input terminal of the delay unit and the output terminal of the second amplifier, and the same antenna is used,
The antenna is connected to an input terminal of the second delay device and an output terminal of the first amplifier via a second circulator for separating a reception signal and a transmission signal. 14. The spread spectrum communication system according to claim 13, wherein: 15. The relay device, further comprising: a third receiving antenna for receiving a radio wave from the base station; and a receiving signal from the third receiving antenna and an output signal of the first delay unit. First combining means for combining and supplying the combined signal to the first amplifier; a fourth receiving antenna for receiving a radio wave from the mobile station; a receiving signal from the fourth receiving antenna and the second delay 15. The spread spectrum communication system according to claim 14, further comprising: a second combining unit that combines the output signal of the amplifier and supplies the combined signal to the second amplifier. 16. The relay device, further comprising: a first amplifier for amplifying a reception signal from the first reception antenna and supplying the amplified signal to the first delay unit; and a reception from the second reception antenna. 13. The spread spectrum communication system according to claim 12, further comprising: a second amplifier for amplifying a signal and supplying the amplified signal to the second delay unit. 17. The first receiving antenna and the second transmitting antenna are composed of the same antenna, and the antenna is connected to the second antenna via a first circulator for separating a received signal and a transmitted signal. And the second receiving antenna and the first transmitting antenna are connected to the output terminal of the delay unit and the input terminal of the first amplifier, and the second receiving antenna and the first transmitting antenna are the same antenna. 17. The spectrum according to claim 16, wherein the output of the first delay unit and the input of the second amplifier are connected to each other via a second circulator for isolating the spectrum. Spreading communication system. 18. The relay device, further comprising: a third transmitting antenna for transmitting an output of the first amplifier to the mobile station; and a fourth transmitting antenna for transmitting an output of the second amplifier to the base station. Claims characterized by comprising a transmitting antenna.
18. The spread spectrum communication system according to 17. 19. The estimating means calculates a difference between each output of the correlator and each of the multipliers, the plurality of multipliers multiplying the output of the sign judgment circuit by each of the estimated transfer functions, and obtains an estimation error. And an arithmetic circuit for performing an adaptive algorithm for sequentially estimating each transfer function from the output of the sign determination circuit and the estimation error output from the subtractor. 13. The spread spectrum communication system according to claim 12. 20. The spread spectrum communication system according to claim 19, wherein said weighting coefficient control circuit sets a square of an absolute value of each of said estimated transfer functions as a weighting coefficient for each of said delayed wave components. . 21. The weighting coefficient control circuit, wherein the weighting coefficient control circuit determines the weighting coefficient based on a ratio between an amplitude of a desired wave component and the estimation error for each of the delayed wave components. 20. The spread spectrum communication system according to 19.