JPH07177126A - Multiplex communication equipment - Google Patents

Abstract

PURPOSE:To improve the synchronization holding performance by using a synchronization channel whose transmission power is increased at the start of data communication so as to send a preamble and multiplexing data channels while the transmission power is decreased after the transmission. CONSTITUTION:When a data transmission request comes from an external interface, a sender side control circuit 154 stops multiplex data channel from a multiplexer 156 and uses a multiplexer 155 to increase a preamble transmission output power and to send a preamble. After the lapse of a preamble transmission time, a preamble transmission output power is decreased similarly to the case with a data channel, a multiplex data channel is set to be an enable state for the data transmission. On the other hand, a receiver side SAW(surface acoustic wave) convolver 201 makes correlation between a reception signal and a reference code, and a synchronization circuit 206 uses the correlation output to acquire and hold the synchronization and a preamble detection circuit 204 detects the preamble to shift a phase of a clock generated in a phase hold circuit 208 and to acquire the synchronizing signal and to hold it.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multiplex communication device for multiplexing and transmitting a plurality of spread code channels.

[0002]

2. Description of the Related Art Conventionally, in a spread spectrum communication apparatus using a direct spread system, a synchronization acquisition circuit using a SAW (surface acoustic wave) convolver is used as a correlator to shorten the synchronization acquisition time. ing.

Further, in a narrow band radio such as a car telephone, TDMA (Time Division Mul) is used.
In a multiple access system, a clock is reproduced from a signal that is periodically transmitted in a burst manner, and the phase of the reproduced clock is held until the next burst is received, thereby adopting a burst synchronization method for speeding up synchronization.

[0004]

DISCLOSURE OF INVENTION Problems to be Solved by the Invention In a spread spectrum communication device, a CDM (Code Division Multi) is used.
In the case of a TDMA system using an (iplex), the SAW convolver is used to perform synchronization acquisition as in the conventional example, but the output of the SAW convolver depends on the cross-correlation of multiple communication channels with respect to the synchronization channel. There is a problem that an interference peak is output.

[0005]

According to the present invention, a means for transmitting a synchronous preamble at the start of data communication, a means for increasing the transmission power of a synchronization channel at the time of transmitting the preamble, a means for multiplexing a data channel after transmitting a preamble, and In a configuration of a transmission control device having a means for reducing the transmission power of a synchronization channel, a correlator and a synchronization circuit for performing synchronization acquisition holding using the correlation output, means for detecting a preamble and synchronization acquisition during the period. By configuring a reception control device that has a means for performing and a means for retaining the phase information of the clock after receiving the preamble, it is possible to suppress the influence of multiple intersymbol interference, improve the synchronization retention performance, and improve the communication quality. The effect is obtained. Further, according to the present invention, the burst synchronization can be realized, the preamble transmission time can be shortened, and the throughput can be improved.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a timing chart showing a transmission signal and a reception signal, and FIGS.

In FIG. 1, 101 is a preamble transmission time for performing burst synchronization, 102 is a transmission time of a spread code multiplexed data channel, and 103 is a preamble transmission power width in the preamble transmission time. , 104 are the transmission power width of each multiplex channel in the data transmission time. Reference numeral 105 denotes a detection waveform of the SAW element output (for example, SAW convolver or less convolution output) at the preamble reception time in the receiving device,
Reference numeral 106 denotes a detection waveform of the convolution output when the data channels are multiplexed. Reference numeral 107 is a preamble reception detection signal.

In the transmitter of FIG. 2A, reference numeral 151 denotes a spreading code PN for preamble and multiple data channel.
Code generators for generating _{0 to} PN _n , 152 _{1 to} 152 _n are logic circuits for exclusive ORing the spread codes PN _{1 to} PN _n and transmission data D _{1 to} D _n , and 153 is a logic circuit 152 _{1 to} 152. _n
Adder 154 adds multiplier outputs 155, 15
6, a control circuit for giving a predetermined coefficient to 6, 155 is a multiplier for adjusting the transmission power of the preamble, 156 is a multiplier for adjusting the transmission power of the multiple data channel, 15
7 is an adder for adding the outputs of the multipliers 155, 156,
Reference numeral 58 is a D / A converter that performs digital / analog conversion on the output of the multiplier 157, 159 is a multiplier that multiplies the output of the D / A converter and the output of the oscillator 160, 161 is a transmission amplifier, and 162 is an antenna.

In the receiver shown in FIG. 2B, 201 is a SAW (surface acoustic wave) element for correlating a received signal and a reference signal, for example, a SAW convolver or a SAW matched filter. Described in the example of using. Reference numeral 202 denotes a SAW convolver received signal, 203 is an envelope detection circuit for detecting the envelope of the convolution output, 204 is a preamble detection circuit for detecting the preamble sent for synchronization acquisition, 205 Is a peak detection circuit for detecting the peak timing of the convolution output, 2
Reference numeral 06 is a synchronization circuit for synchronizing the timing of the reception convolution output and the reference spreading code, 207 is a code generating circuit for generating a plurality of spreading codes, and 208 is a phase for holding the clock phase after burst synchronization acquisition. It is a hold circuit. The actual operation will be described below.

FIG. 3 is a flow chart showing the operation of the transmitter.

First, when there is a data transmission request from an external interface (not shown), the transmission apparatus of FIG. 2A transmits the preamble for the preamble transmission time 101 (S301). At this time, the transmitter stops the multiple data channel (or lowers the transmission power) and raises the preamble transmission output power 103 for transmission (S30).
2).

Then, after the preamble transmission time 101 has elapsed (S301), the transmission device stops the transmission of the preamble or lowers the output power of the preamble transmission to the same level as the data channel and outputs it, thereby enabling the multiple data channel and transmitting the data. Step 102 is performed (S303). Transmission power per data channel at this time 10
A value obtained by dividing the total transmission power by the number of multiplex channels is assigned as 4.

In the receiver shown in FIG. 2B which receives this signal, the received signal is first given to the received signal input 202 of the SAW convolver 201. The spreading code generator 207 is connected to the other input of the SAW convolver 201.
The reference spread code generated by the input is input. The two signals are correlated in the SAW convolver, and when the signs of the two coincide with each other, a correlation peak appears as a convolution output.

As the convolution output at this time, within the preamble transmission time 101, a large level output 105 is obtained for each code period because the multiple data channels are stopped and the transmission power is high. Also, as the convolution output at the time of the data transmission time 102, as shown by 106, an output having no periodicity due to the inter-multiple-code interference (when the preamble is transmitted with low power, the cyclic correlation output due to the preamble is also )Come out.

The convolution output is output to the preamble detection circuit 204 and the peak detection circuit 205 after the envelope is detected by the envelope detection circuit 203. First, in the preamble detection circuit 204 which has received this convolution output, the internal comparator compares the convolution output with the preset threshold level.

If this output exceeds the threshold level, the preamble detection circuit 204 changes the hold instruction signal 107 to High and sends it to the phase hold circuit 208 as a burst synchronization acquisition mode signal. This preamble detection may be performed by integrating the convolution output instead of directly compiling the convolution output.

On the other hand, the peak detection circuit 2 which receives the detection output
05 detects the position of the peak of the convolution output and then outputs the phase information to the synchronization circuit 206. Upon receiving this signal, the synchronization circuit 206 receives the spread code generation circuit 2
Spread code generation timing signal (G) output from 07
And the difference information is sent to the peak hold circuit 208. When the signal 107 from the preamble detection circuit 204 indicates High as the synchronization acquisition signal when receiving the difference information, the phase of the clock generated in the phase hold circuit 208 is shifted according to the phase difference information to acquire the synchronization. And then hold the synchronization.

This synchronization acquisition and synchronization holding operation is performed only when the signal 107 from the preamble detection circuit 204 is High. When this signal changes to Low, the phase hold circuit 208 ignores the phase difference information from the synchronization circuit, and holds the clock phase, for example, holds the VCO (voltage controlled oscillator) voltage. This is kept held until the next preamble is detected, and the same operation is repeated again when the preamble is detected.

In the above-mentioned embodiment, the case where the phase hold of the clock is immediately performed after performing the synchronous acquisition and holding operation at the time of receiving the preamble has been described. However, the period of the preamble can be detected after the acquisition of the synchronization. Therefore, the cross-correlation peak of the data channel can be removed by masking the convolution output except for the position of at least one code chip before and after the period, and the phase comparison is always performed during signal reception. Things are possible.

FIG. 3 is a block diagram of a receiver according to another embodiment, and since the constituent elements are the same as those in FIG. 2B, the description thereof will be omitted.

As another embodiment, a case where the preamble detection circuit 204 is added after the peak detection circuit 205 will be described. The comparator in the preamble 204 is shared with the comparator included in the peak detection circuit 205, and the threshold level thereof is set to a level exceeding only when the preamble is received. Therefore, the peak information is sent to the preamble detection circuit 204 only when the preamble is received.

This peak signal wave is sent to the preamble detection circuit 204 as a digital signal. The edge information of the peak signal is sent to the synchronizing circuit 206 via the preamble detection circuit 204 and monitored inside the preamble detection circuit 204. If the peak signal is not detected for each code period, the phase hold circuit is used. 208
A clock phase hold signal 107Low is output with respect to.

As described above, in the present embodiment, in order to surely acquire the synchronization when the code division multiple access is performed,
On the transmitting side, during transmission of the preamble, the transmission power of the synchronization channel is increased and the transmission power of the multiplexed channel is decreased,
After transmitting the preamble, the transmission power of the synchronization channel is lowered and the transmission power of the multiplexed channel is raised. On the other hand, on the receiving side, synchronization is acquired during the preamble and holds the synchronization clock after receiving the printable.

[0024]

As described above, according to the present invention, the means for stopping the code division multiplexing channel at the start of data communication and transmitting the synchronization preamble, the means for increasing the transmission power of the synchronization channel at the time of transmitting the preamble, and the preamble transmission In a configuration of a transmission control device having means for multiplexing the subsequent data channel and means for reducing the transmission power of the synchronization channel after transmitting the preamble, and a correlator and a synchronization circuit for performing synchronization acquisition and holding using the correlation output, the preamble The influence of multiple intersymbol interference can be suppressed by configuring a reception control device having a means for detecting a preamble at the time of reception, a means for performing synchronization acquisition during the period, and a means for holding phase information of a clock after receiving the preamble. It becomes possible to prevent the malfunction of the synchronization acquisition operation and the synchronization holding operation and improve the communication quality. The effect of said can be obtained. Also,
According to the present invention, burst synchronization can be realized, high-speed synchronization acquisition can be realized, and high-speed, high-throughput data transmission can be achieved by shortening the preamble transmission time.

Further, by increasing the transmission power at the time of transmitting the preamble, the effect that the preamble can be easily detected and the circuit can be downsized can be obtained.

By changing the position of the preamble detection circuit and sharing a part of the operation with the peak detection circuit, the preamble detection circuit can be digitized and downsized, and the state of the external interface, etc. As a result, it becomes possible to control the transition to the synchronous acquisition operation, and the effect that the protocol can be flexibly dealt with is also obtained.

[Brief description of drawings]

FIG. 1 is a timing chart showing a transmission signal and a reception signal according to an embodiment.

FIG. 2 is a block diagram of the inside of a synchronization unit of the transmission / reception device of the embodiment.

FIG. 3 is a flowchart of a transmitting device according to an embodiment.

FIG. 4 is a block diagram of a receiving device according to another embodiment.

[Explanation of symbols]

101 Preamble Transmission Time for Performing Burst Synchronization 102 Transmission Time of Spread Code Multiplexed Data Channel 103 Preamble Transmission Power Width at Preamble Transmission Time 104 Transmission Power Width of Each Multiplex Channel at Data Transmission Time 105 Within Receiver And detection waveform of convolution output of preamble reception time 107 preamble reception detection signal 151 code generator 154 control circuit 155 multiplier 156 multiplier 201 SAW convolver 203 envelope detection circuit 204 preamble detection circuit 205 peak detection circuit 206 peak detection circuit 206 synchronization circuit 207 Code generation circuit 208 Phase hold circuit

Claims (4)

[Claims] 1. A multiplex communication apparatus for multiplexing and transmitting a plurality of spread code channels, means for transmitting a preamble using a synchronization channel at the start of data communication, means for multiplexing a data channel after transmitting a preamble, and Increase the transmission power of the sync channel while sending the preamble,
A multiplex communication device having means for reducing transmission power of a synchronization channel after transmitting the preamble. 2. A multiplex communication device for multiplexing and transmitting a plurality of spread code channels, comprising a correlator and a synchronization circuit for performing synchronization acquisition and holding using the correlation output, and means for detecting a preamble, A multiplex communication device having means for performing a synchronization acquisition operation at the time of receiving a preamble, and means for holding phase information of a clock after receiving the preamble. 3. The multiplex communication device according to claim 2, wherein a SAW element is used as a correlator in the above configuration. 4. In a multiplex communication apparatus using a plurality of spreading code channels, a means for transmitting a preamble using a synchronization channel, a means for multiplexing a data channel after transmitting a preamble, and a transmission power of a multiple data channel during transmission of a preamble. Multiplexing device characterized by having means for lowering.