KR960000145B1 - Spread spectrum system - Google Patents

Abstract

a memory to memorize at least one sub-decode control data; a controller for controlling input/output of the data and an overall operation of the transmission/reception apparatus; an encoder for encoding a transmission signal from the controller under control of the controller; a modulator for modulating an encoded signal to a PN code; a transmission/reception divider for transmitting a signal modulated in the above through an antenna, and receiving a spread spectrum signal from outside; a spread spectrum demodulation for inputting the signal from outside and demodulating the signal through the spread spectrum process; and a decoder for decoding the signal encoded in the encoder by inputting the output signal of the demodulator under control of the controller.

Description

Transceiver and communication path setting method of band volcano communication system

1 is a block diagram of a transceiver in a conventional spread spectrum communication system.

2 is a flowchart illustrating a communication channel setting process of a conventional spread spectrum communication system.

3 is a block diagram of a transceiver of a spread spectrum communication system according to an embodiment of the present invention.

4 is a flowchart illustrating a communication channel setting process of a spread spectrum communication method according to an embodiment of the present invention.

The present invention relates to a spread spectrum communication system, and more particularly, to a transceiver of a spread spectrum system.

In general, a spread spectrum communication system using a PN code uses different PN phase offsets as a method of distinguishing between mobile stations. However, this PN phase offset may occur when the phase coincides with the transmission data of another mobile station reaching the base station receiver at some point due to an error of the local clock in the mobile station transceiver. The call signal is output.

Therefore, in order to make up for the shortcomings, the conventional spread spectrum communication system transmits a base station by mixing a Walsh code for distinguishing a corresponding mobile station from an output signal. Since the Walsh Code is a well-known technique, description thereof is omitted.

1 is a block diagram of a transmission / reception device of a conventional spread spectrum communication system mobile station.

The central processing unit 10 controls the overall operation of the mobile station in response to a predetermined program, and outputs and processes transmission data and receives reception data. The ROM 12 is connected to the central processing unit 10 and stores a predetermined program. RAM 14 is connected to the central processing unit 10 to store and delete various data generated during the whole process.

The click generator 16 generates and outputs a click signal (local click) having a predetermined period.

The transmitter 20 transmits the spread signal by the PN code generator 22 and the PN code generator 22 which generate a PN code for spreading the transmission data output from the central processing unit 10. A transmission frequency synthesizer 26 which is controlled by the central processing unit 10 to carry a predetermined carrier on the spread signal, and a strategic amplifier 28 which amplifies and outputs the frequency synthesized signal at a predetermined amplification ratio. . The transmission frequency synthesizer 26 and the strategic amplifier 28 were constructed. The configuration of the transmission frequency synthesizer 26 and the power amplifier 28 is an RF modulator in a general spread spectrum communication system.

The duplexer 30 outputs a transmission signal amplified and output from the power amplifier 28 in the transmission unit 20 through an antenna, and outputs a reception signal received through the antenna to the reception unit 40.

Receiving unit 40 is a low noise amplifier 41 for receiving a received signal output from the duplexer 30 and a low noise amplification, and the central processing unit 10 is controlled to separate the signal spread from the amplified signal A reception frequency synthesizer 26 for multiplying the received signal by a carrier wave, a reception PN code generator 43 for despreading the received signal with a PN code, and receiving the despread signal for PN code despreading. Synchronization tracking circuit 45 for receiving a predetermined clock from the clock generator 16 to control the PN code generator 43 and the clock generator 16 to generate synchronization, and generating a predetermined wash code. And a Walsh code generator 46 for receiving the predetermined clock signal from 16) and performing Walsh code decoding.

2 is a communication channel setting flowchart of a mobile station having the configuration of FIG.

Hereinafter, a process of establishing a communication path of a conventional spread spectrum communication system will be described with reference to FIG. 3 based on the configuration of FIG. 1.

In the conventional mobile station having the configuration of FIG. 1 described above, in FIG. 2A of FIG. 2, the central processing unit 10 controls the reception frequency synthesizer 42 to achieve arbitrary frequency tuning with the received signal. Thereafter, in step 2b, the PN code generator 43 multiplies the input signal by the PN code to despread it. In addition, in step 2c, the synchronization tracking circuit 45 searches for the despread signal and searches for synchronization. At this time, if the synchronization is not achieved, the central processing unit 10 searches for the received data to recognize that the synchronization is not matched, and in step 2h controls the receiving frequency synthesizer 42 to select and tune to another frequency.

However, if the synchronization is matched in step 2c, the Walsh code generator 46 performs Walsh code decoding on the signal confirmed by the PN code generator 43 in step 2d to search whether the received signal is a self-call signal. At this time, if it is not a self-call signal, it loops in step 2h to search and tune to a new frequency band. However, if it is a self-call signal in step 2e, the central processing unit 10 receives the reception data output in step 2e and transmits a response signal through the transmitter 20 in step 2f. Thereafter, the central processing unit 10 exchanges information for a call with the base station at the synchronized frequency in step 2g.

However, the above-mentioned spread spectrum communication method has a disadvantage in that, in the direct call between mobile stations, the identification method of the self-call signal is the only PN offset decoding method in which the problem caused by the aforementioned local clock is presented.

Accordingly, another object of the present invention is to provide a transmission / reception apparatus capable of communicating by mixing Walsh code with transmission data during communication between mobile stations in a method for establishing a communication path of a spread spectrum communication system.

Another object of the present invention is to provide a method for establishing a communication path by encoding a transmission signal in a Walsh code when a communication request between mobile stations is requested in a communication path setting method of a spread spectrum communication system.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram of a transceiver of a spread spectrum communication system according to an embodiment of the present invention, in which a transmitting side Walsh code generator 121 is added to a transceiver of a known spread spectrum communication system having the configuration of FIG. It can be configured as follows.

The central processing unit 110 controls the overall operation of the mobile station in response to a predetermined program, and outputs and processes transmission data and receives reception data. The ROM 112 is connected to the central processing unit 110 and stores a predetermined program. RAM 114 is connected to the central processing unit 110 to store and delete various data generated during the entire process.

The clock generator 116 generates and outputs a clock signal (local clock) having a predetermined period.

The transmitter 120 includes a Walsh code generator 121 for Walsh code encoding the received data output from the central processing unit 110, a transmission PN code generator 116 for spreading the Walsh code encoded signal into a PN code, Transmitting a signal controlled by the central processing unit 110 and transmitted by the PN code generator 122 to transmit a signal that is controlled by the central processing unit 110 and spread by the PN code generator 122. And a transmission frequency synthesizer 126 for carrying a predetermined carrier on the spread signal, and a power amplifier 128 for amplifying and outputting the frequency synthesized signal at a predetermined amplification ratio. The power amplifier is an RF modulator in a general spread spectrum communication system.

The duplexer 130 outputs a transmission signal amplified and output from the power amplifier in the transmission unit 120 through an antenna and outputs a reception signal received through the antenna to the reception unit 140.

The receiving unit 140 is controlled by the central processing unit 110 to separate the signal from the low noise amplifier 141 that receives the output signal from the duplexer 130 and low noise amplification, and the signal amplified from the amplified signal The PN code generator 143 and the clock generator may receive a predetermined clock from a reception frequency synthesizer 126 that multiplies the received signal by a carrier wave and a reception PN code generator 116 that inverts the received signal into a PN code. A synchronous tracking circuit 145 for controlling 116 and a control operation to the central processing unit 110, receiving a predetermined clock signal from the clock generator 116 to generate a Walsh code, and performing a Walsh code decoding on the received despread signal. Is composed of a Walsh code generator 46.

4 is a block diagram illustrating a spread spectrum communication receiver according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIG. 4 based on the configuration of FIG. 3 described above.

In the mobile station having the configuration of FIG. 3 described above, when calling, the mobile station spreads and outputs a signal that is not Walsh code encoded. Then, the calling mobile station first performs an arbitrary frequency tuning with the received signal by controlling the receiving frequency synthesizer 142 in step 4a of FIG. 4a of FIG. 4. In step 4b, the central processing unit 110 controls the Walsh code generator 146 of the receiver to set the Walsh code to '0'. In step 4c, the PN code generator 143 of the receiver multiplies the input signal with the PN code to despread the input signal. Also, in step 4d, the synchronization tracking circuit 45 searches for the despread signal to determine whether the synchronization has been performed. In this case, if the synchronization is not achieved, the central processing unit 110 searches for the received data to recognize that the synchronization is not matched, and in step 41 controls the receiving frequency synthesizer 142 to select and tune the next frequency.

However, if it is synchronized in step 4d, in step 4e, the central processing unit 110 receives a signal confirmed by synchronization from the PN code generator, and in step 4f, it is checked whether the signal is a self-call signal. At this time, if the self-call signal is looped in step 41, the reception frequency synthesizer 142 is controlled to select and tune the next frequency. However, if it is a self-call signal in step 4f, the central processing unit 110 sets the Walsh code generator 121 of the transmitter 120 to '0' in step 4g, and the Walsh code-uncoded response is transmitted through the transmitter 120. Send a signal. In step 4h, the central processing unit 110 reads the Walsh code for setting the currency from the ROM 112. In step 4i, the central processing unit 110 spreads the Walsh code read from the ROM 112 for changing the Walsh code setting through the change transmitter 120 and outputs the spread spectrum. Note that the output signal is not Walsh code encoded. Thereafter, in step 4j, the CPU sets the Walsh code generators 121 and 146 of the transmitter 120 and the receiver 140 to the Walsh code read in step 4h. Thereafter, in step 4k, the central processing unit 110 exchanges information for a call by incubating the synchronized frequency and the matching Walsh code with the mobile station that wishes to communicate.

As described above, the present invention prevents interference from other mobile stations in case of local clock error by matching transmission / reception Walsh code settings with each other in an initial communication path setting process for preventing interference between mobile stations.

In addition, the present invention has the advantage that it is possible to prevent the signal detection of another spread spectrum communication system by Walsh-coded before spreading the transmission data used for the communication between mobile stations and Walsh-coded before spreading the other band. Furthermore, since the present invention does not go through the Walsh code decoding step when setting the initial communication path, the present invention does not need to remember Walsh code setting values of other mobile stations, and has an advantage of effectively reducing the initial communication path setting time.

Claims (4)

1. A spread spectrum communication transceiver, comprising: a memory for storing at least one sub-decoding control data for determining a predetermined operation procedure and an encoding / decoding scheme; Control means for controlling, controlling means operated by said control means, encoding means for encoding a transmission signal output from said control means, spread-spectrum modulation means for spreading the modulated output by spreading the encoded signal with a PN code; Demodulation for transmitting and receiving the spread spectrum modulated signal through an antenna, receiving and outputting an external signal spread through the antenna, and outputting the band spread spectrum demodulated output; Band despreading demodulation means for outputting, and control operation by said control means And decoding means for receiving the output signal of the spread spectrum demodulation means and decoding the output signal to the control means in correspondence with the sign of the auxiliary means. The communication apparatus according to claim 1, wherein the encoding means and the decoding means are Walsh code mixing means for generating and encoding Walsh code. A control means for storing at least one sub-decoding control data for determining a predetermined operation procedure and an encoding / decoding method, and for controlling the overall operation of various data input / output and a transmission / reception apparatus in response to the operation procedure, and in the control means. And encoding means for encoding a transmission signal outputted from the control means, band-converting modulation means for spreading the modulated signal by spreading the coded signal with a PN code, and converting the spread spectrum-modulated signal into an antenna. Transmission and reception separation means for receiving and outputting an external signal spread through the antenna and outputting through the antenna; and band despreading demodulation means for receiving the external signal outputted from the transmission and reception separation means and performing band despreading and demodulation output. The control operation is performed by receiving the output signal of the spread spectrum demodulation means In response to the encoding of the encoding means, the spread spectrum modulation and transmission is performed without decoded by the control means, and the response signal of the relative spread spectrum communication device to be communicated is converted into received data by reception and band despreading. Search for the initial communication path and search for the desired counterpart communication device; and after performing the initial communication path setting process, select the sub-decoding control data for setting the decoding method and send it to the counterpart communication device; And transmitting / receiving information data outputted from the control means after the process by means of decoding and decoding the data according to the set sub-call method through the set communication path. The method of claim 3, wherein the encoding and decoding method is a Walsh code encoding and decoding method using a Walsh code.