JPH1028077A - Communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make reception data in a base station hold the orthogonal relation of an orthogonal code and to synchronize reception signals by compression- encoding the advance/delay information of the time calculated so as to match the synchronization of the orthogonal code of the reception signals from respective mobile stations and transmitting it to the mobile stations. SOLUTION: Output is passed through a parallel/serial converter 407 and turned into serial data. To the data, noise equivalent to a time difference with the reception data from the surrounding mobile station is superimposed. The data are judged by using a judgement device 409. Noise signals are used and delay time is predicted by using a delay time control signal predicting device 411. The predicted delay time difference is encoded and transmitted from the transmitter of the base station to the respective mobile stations. The signals are turned into input signals to a receiver and the timing of the transmission signals of the respective mobile stations is adjusted. Thus, the orthogonal codes used as the spreading signals of the data in the respective mobile stations are synchronized.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a mobile communication system, and more particularly to a structure of a communication device.

[0002]

2. Description of the Related Art Conventionally, this type of system is called "T.
r Comparison ofdifferen
t DetectionAlgorithms for
OFDM-CDMA in Broadband R
IEEE VTC9 of "ayleigh fading"
5 ", page 835, FIG. 1 and FIG. This converts the input data into a Walsh matrix,
It was configured to convert and output with T. FIG. 1 shows the configuration of the modulator. FIG. 2 shows the configuration of the demodulator.

[0003]

However, in the conventional configuration, input data is spread by orthogonal codes and transmitted from a transmitter of a base station of a mobile communication system to a plurality of mobile stations in the system. At the same time, it is possible for each mobile station to receive synchronously while maintaining the orthogonal relationship by the orthogonal code of each data, but conversely, when the data transmitted from each mobile station is received by the base station, Since the distance between the station and each mobile station is different, even if the input data is spread and transmitted with orthogonal codes, the received data at the base station keeps the orthogonal relationship of the orthogonal codes and synchronizes the received signals. Can not do.

[0004]

A function of measuring the reception time of data transmitted from each mobile station by spreading with an orthogonal code at each base station at the base station, and moving the amount of deviation from the reference time for each mobile station. A function to determine for each station, a function to compress and encode time advance / delay information calculated at the base station so that the orthogonal code of the received signal from each mobile station is synchronized, and transmit the information to the mobile station, A communication apparatus, wherein the mobile station has a function of adjusting the time of data to be transmitted by spreading with an orthogonal code and transmitting the data in accordance with advance / delay information of the received time and transmitting the data.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION A preferred embodiment of the present invention (how to implement the invention), which is considered to be the best, will be briefly described with reference to the drawings, showing its operational effects.

In the configuration of the transmitter on the mobile station side according to the present invention, the input data is decomposed into a plurality of parallel data through a serial-to-parallel converter, and each is spread using a unique orthogonal code. Modulated at the carrier frequency of Therefore, the data rate of one channel is
Lower by a few minutes of the channel.

As the orthogonal code, a code such as a Walsh code is used. Modulation by orthogonal carrier frequencies
The signal can be obtained by performing an inverse discrete Fourier transform on a signal spread with a plurality of orthogonal codes, and subjecting the output to parallel-serial conversion.

[0008] In the configuration of the receiver of the base station, data spread by the unique orthogonal code transmitted from a plurality of mobile stations is simultaneously received. Each signal is subjected to discrete Fourier transform in accordance with the reception timing of the signal of each mobile station, and correlation is obtained with an orthogonal code unique to each mobile station. The correlation output is subjected to parallel-serial conversion to determine data. The delay time is calculated by the delay time signal predictor using the determination data. The delay time is a time lag from the substantially average timing of the reception timing of the reception signals from all the mobile stations.

The delay time is digitally encoded and transmitted from the base station transmitter to the mobile station receiver. The mobile station receives the delay time, determines the transmission timing while adjusting to the time corresponding to the delay time, and transmits the transmission signal.

【Example】

A specific embodiment of the present invention will be described with reference to the drawings.

First Embodiment Description of Configuration FIG. 3 is a block diagram of a transmitter on the mobile station side, showing a first embodiment of the present invention. Input data 301 is converted by a serial-to-parallel converter 302 into 1: N parallel data. The data rate of each channel converted by the serial / parallel converter 302 is 1 / N of the input data rate.

[0012] The converted data is output by the spreader 304.
It becomes a spread signal using the Walsh code 303 which is an orthogonal code. The pilot signal 314 is added to the spread signal of the channel. The pilot signal may be added to multiple channels.

The spread signal is output through a discrete inverse Fourier transform 305. As for the discrete Fourier transform output, each channel is converted into continuous data by the switch 306 and output. The output is performed in accordance with the data received from the receiver 307. The signal output according to the transmission timing is output via the D / A converter 309. The output signal is modulated by the carrier frequency and transmitted.

FIG. 4 shows the configuration of a receiver on the base station side according to a first embodiment of the present invention. A received signal 401 is demodulated by a received carrier frequency 402. Demodulated signal is A
After being converted into a digital signal by the / D converter 403 and sampled and held, the signal is converted into an N-channel parallel signal by the discrete Fourier transform 404. On the transmitting side in FIG. 3, a correlation operation with the pilot signal 415 is performed on the channel signal to which the pilot signal is added. The correlation calculation output is input to the propagation path estimation and timing extraction circuit 414.

On the other hand, each channel signal is correlated by the same orthogonal code 405 as that on the transmitting side. The output becomes serial data through the parallel-serial converter 407. This data is superimposed with noise corresponding to a time difference from data received from surrounding mobile stations. This data is used to determine
09 for data determination. The delay time is predicted using the noise signal and the delay time control signal predictor 411. The predicted delay time difference is encoded and transmitted from the transmitter of the base station to each mobile station.

This signal is supplied to the receiver 30 shown in FIG.
7, and adjusts the timing of the transmission signal of each mobile station.

2. Description of Operation FIG. 6 shows a time chart in the configuration of the modulator of FIG. The modulator is on the mobile station side. The modulator of one mobile station will be described. Let d be the data rate of input data (a)
And The data is converted into parallel data (b) by an N-channel serial / parallel converter. The data rate per channel is 1 / N d / N.

The data of each channel is converted to a Walsh code (c), which is a kind of orthogonal code assigned to each user.
To make a spread signal (d) of M times. M and N may be the same. FIG. 6 shows a case where N and M are equal for simplicity. Accordingly, the speed of the spread channel signal is d. Here, one type of Walsh code is assigned to one mobile station.

The pilot signal (e) is added to at least one of the channel signals. The channel to which the pilot is added is determined in advance. As a pilot signal, a Walsh code having an orthogonal relationship with an orthogonal code assigned to each user is selected. Here, the addition result with the pilot signal is not shown.

Each spread channel signal is subjected to discrete inverse Fourier transform (f). Here, channel 1 and channel 2
The results of the real and imaginary parts of are shown. Channel 3, channel 4
Are omitted.

The output (g) subjected to the discrete Fourier transform is converted into continuous data using a switch. The speed of the switch is d / N in this example. The timing for transmitting the output of the switch is determined according to the transmission timing signal of the delay time control signal obtained from the receiver. The transmission timing is adjusted by the delay time control, and is modulated at the transmission carrier frequency and transmitted through the D / A converter.

A time chart in the configuration of the demodulator of FIG. 4 is similar to the result of FIG. The demodulator is installed in the base station and receives signals from a plurality of mobile stations at the same time. The reception timing from each mobile station differs depending on the relative distance between the base station and the mobile station.

The operation of a received signal from one mobile station will be described. The received signal is demodulated (g) by the mixer. The demodulated signal is converted (d) into each channel signal by a discrete Fourier transform. The modulator performs a correlation operation with the pilot signal (e) on the channel to which the pilot channel has been added, estimates the propagation path of the radio channel, and determines the reception timing of the pilot signal.

Each channel signal has a Wa determined by a modulator.
A correlation operation is performed using the lsh code (c). As the correlation timing of the correlation operation, the reception timing obtained by the correlation operation with the pilot signal is used. Each channel data (b) is converted into serial data (a) by parallel-serial conversion. Perform data judgment from serial data,
Get received data.

Next, the delay time control section will be described. Since the demodulator receives signals from each mobile station at the same time, there is a deviation in the reception timing due to the relative distance between each mobile station and the base station. This deviation is added to the output of the parallel-serial converter in FIG. 4 as interference noise.

In FIG. 4, as an example of a method for evaluating the noise amount, the noise amount is obtained from the difference between the output of the parallel-serial converter and the data judgment output. The difference signal output is shown by the following equation.

(Equation 1)

The output of the parallel-serial converter is R
_k (t). This signal is input to the delay time control signal predictor 411. The delay time control signal predictor obtains the mean square of the error signal.

(Equation 2) The delay time T _dk ^{(v + 1)} is updated using the following equation.

(Equation 3) ΔT _d represents the update amount of the delay time. ν represents a subscript representing the current delay time. ν + 1 represents a subscript that determines the update amount of the delay time at the next time.

Actually, if the delay time is transmitted as it is, the amount of information becomes large. Therefore, the delay time control signal encoder compresses the information amount by advancing, delaying, or doing nothing by a fixed amount of delay time. And transmit it to each mobile station. This encoding can be freely selected depending on the system configuration.

Each mobile station shown in FIG. 3 demodulates this information with a receiver, determines the information based on a predetermined delay time width 308, adjusts the transmission timing from each mobile station, and transmits data. Send.

In the description so far, the delay time control method has been described based on the hill-climbing method. However, the same operation can be performed by using an equalizer based on the least squares method.

In the description so far, the control is performed so that each channel automatically minimizes the interference. However, a common reference time is set for all the channels, and FIG. Of the delay time control predictor 411, and the delay time control signal encoder 412 obtains the delay time signal so as to match the time, thereby performing the control.

In the description so far, the first transmission timing of each mobile station has not been described. The mobile station can perform the above-described delay time control after transmitting the data transmitted from the base station at the timing when it is received.

Further, by combining with the above-mentioned method of automatically minimizing the interference signal, the delay time can be controlled even if the relative distance between each mobile station and the base station is largely shifted.

Further, a guard interval may be used for removing interference. This is not an essential requirement of the present invention.

In the description so far, the communication apparatus using the delay time control in the multi-carrier system for spreading the spectrum of data has been described. However, the present system can be applied to the spread spectrum apparatus itself.

3. Description of Effect When configured as in the first embodiment, when data is transmitted from a mobile station to a base station, regardless of the relative distance between each mobile station and the base station, a spread signal of data is generated at each mobile station. Can be used to synchronize the orthogonal codes used. This makes it possible to configure a multicarrier communication apparatus that has excellent error characteristics and spreads data.

Description of Use Form In the present embodiment, the description has been given of an example in which the apparatus is used in a wireless line. It is possible. Further, the present invention is also applicable to a wired communication device using modem analog modulation used for a wired line instead of a wireless modulation signal.

Although the modulation is performed at the carrier frequency, it can be applied to an underwater communication device by using a vibrator.

[0039]

Since the present invention is configured as described above, it is possible to reduce the interference of the transmission signal from each mobile station received at the base station, and to realize a communication apparatus having excellent noise resistance. .

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a configuration of a conventional multicarrier modulator.

FIG. 2 is an explanatory diagram showing a configuration of a conventional multicarrier demodulator.

FIG. 3 is an explanatory diagram illustrating a configuration of a multicarrier modulator on the mobile station side according to the first embodiment.

FIG. 4 is an explanatory diagram illustrating a configuration of a multicarrier demodulator on the base station side according to the first embodiment.

FIG. 5 is an explanatory diagram illustrating a configuration of a multicarrier demodulator on a base station side according to a second embodiment.

FIG. 6 is a time chart of the transmitter of the first embodiment.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Soichi Watanabe 1799-2, Yasuda, Kashiwazaki-shi, Niigata No.203 Corp. Yasuda 203 (72) Inventor Takeo Abe 7-23 Terao Asahi Dori, Niigata City, Niigata Prefecture

Claims (1)

[Claims] A transmitter having a function of spreading input data by a predetermined code, a function of modulating and transmitting a spread signal using one or more frequency channels, and a transmitter having a function of transmitting each frequency channel signal. In a communication device composed of a receiver having a function of performing demodulation and a function of performing correlation detection using a code equivalent to that of the transmitter, the receiver receives signals from one or more transmitters at the same time. The transmitter has a function of determining a time, a function of determining a transmission time of each transmitter so that a reception time is constant, and a function of transmitting a transmission time from each transmitter to each transmitter. Is a communication device having a function of transmitting transmission data according to a transmission time transmitted from a receiver.