KR960009454A - Data Transceiver of Spread Spectrum Communication System using Pilot Channel - Google Patents

Abstract

In a spread spectrum communication system, a data transceiver of a pilot channel system spread spectrum communication system using one PN code generator is disclosed. According to the present invention, the pilot forms only one channel signal component, the data forms only a Q channel signal component, and the I and Q channel signal components are all multiplied by the output of the same PN code generator, thereby simplifying the configuration of the receiver. There is. In addition, the present invention does not cause deterioration of code acquisition characteristics due to cross correlation since the pilot signal component is not disturbed by the data signal component without two combiner configurations and processes for combining the spread spectrum and analog converted signal. Does not work.

Description

Data Transceiver of Spread Spectrum Communication System using Pilot Channel

Since this is an open matter, no full text was included.

3 is a block diagram of a data transmitter of a spread spectrum communication system according to the present invention.

4 is a block diagram of a data receiver of a spread spectrum communication system according to the present invention.

Claims (9)

In a spread spectrum communication system, Walsh code generation means for generating and outputting first and second Walsh codes having respective code systems, a predetermined pilot signal and data to be transmitted are received, and the first and second Walsh codes are input. A Walsh modulator for outputting a Walsh modulated pilot signal and data by multiplying the pilot signal and data, a PN code generating means for generating and outputting a predetermined PN code, and the Walsh modulated pilot signal and data A band spreading means for spreading and outputting the two Walsh-modulated input signals as the PN code, respectively, and a finite impulse response filtering means for outputting each of the band-spread pilot signals and data by unique impulse response filtering; And analogize the spread spectrum signal and data filtered out from the finite impulse response filtering means. Digital-analog conversion means for converting and outputting a signal; low-pass filtering means for receiving the analog-converted pilot signal and data and low-pass filtering them respectively; and outputting the low-pass filtered pilot signal and data and a predetermined intermediate frequency signal. receives the input, the pilot bit input signal and multiplies the I- phase component of cosω _IFT of an intermediate frequency by multiplying the in-phase component of Q- sinω _IFT of said data input signal and the intermediate frequency IF signal mixed with the pilot signal and a data bit And an intermediate frequency mixing means for outputting each, a combining means for receiving the intermediate frequency mixed pilot signal and data, and combining the two input signals to output the combined signal; an output signal of the combining means and a predetermined radio frequency signal cosω _RFT A mixing means for multiplying and outputting the two input signals, and And a band filtering means for receiving an output signal and band-filtering and outputting the output signal, and an amplifying means for receiving the band-filtered signal and amplifying the signal according to a predetermined amplification ratio. Data transmitter. The first multiplier according to claim 1, wherein the spreading means receives the Walsh-modulated pilot signal and the PN code, multiplies the two input signals, and outputs the multiplied-band spread pilot signal, and the Walsh-modulated data. And a second multiplier receiving the PN code and multiplying the two input signals and outputting the spread data as band spread data. The finite impulse response filtering unit according to claim 2, wherein the finite impulse response filtering unit comprises: a first finite impulse response filter for receiving the output signal of the first multiplier and filtering and outputting the finite impulse response; and a finite impulse for receiving the output signal of the second multiplier; A data transmitter of a spread spectrum communication system using a pilot channel, characterized in that it comprises a second finite impulse response filter for outputting response filtering. In the spread spectrum communication system, a first Walsh code generator for generating and outputting a first Walsh code, a second Walsh code generator for generating and outputting a second Walsh code, a pilot signal and the first Walsh code are received. A first multiplier for multiplying two input signals and outputting a Walsh-modulated pilot signal, a second multiplier receiving the desired data and the second Walsh code and multiplying the two input signals and outputting the Walsh-modulated data; A second multiplier for receiving the data desired to be transmitted and the second Walsh code and multiplying the two input signals to output Walsh-modulated data, PN code generating means for generating and outputting a predetermined PN code, and the Walsh-modulated pilot A third multiplier configured to receive a signal and the PN code and to multiply the two input signals to output a spread spectrum pilot signal, the Walsh-modulated data and the PN code And a fourth multiplier for multiplying the two input signals and outputting the spread spectrum data, a first finite impulse response filter receiving the output signal of the third multiplier and filtering and outputting a finite impulse response filter; A second finite impulse response filter which receives the output signal of the multiplier and filters and outputs the finite impulse response filter, a first digital-analog converting means for converting and outputting the output of the first finite impulse response filter into an analog signal, and a second finite impulse Second digital-to-analog conversion means for converting and outputting the output of the response filter into an analog signal, first and second LPFs for low-pass filtering and outputting the outputs of the first and second digital-to-analog conversion means, respectively, A low-pass filtered pilot signal is input from the cosω _IFT , which is an I-phase component of a frequency, and the first LPF, and the intermediate frequency is multiplied by the two input signals. A fifth multiplier outputting a mixed pilot signal, low-pass filtered data from sinω _IFT , which is a Q-phase component of an intermediate frequency, and the second LPF, and multiplying the two input signals to output intermediate mixed data; Receiving a sixth multiplier, the intermediate frequency mixed pilot signal and data, combining means for combining and outputting the two input signals, an output signal of the combining means, and a predetermined radio frequency signal cosω _RFT , Mixing means for multiplying and outputting the two input signals, band filtering means for receiving the output signal of the mixing means and outputting the band-filtered signal, and amplifying and transmitting the band-filtered signal according to a predetermined amplification ratio. A data transmitter of a spread spectrum communication system using a pilot channel, characterized in that the configuration. In the spread spectrum communication system, Low noise amplification means for amplifying and outputting the received signal received through the antenna, Band pass filtering means for receiving the output signal of the low noise amplifying means and band-filtered output and the band-filtered signal And cosω _RFT , which is a radio frequency signal, and multiplies the two input signals and converts the signal into a signal of an intermediate frequency component, and cosω, which is an I-phase component of the output signal of the first mixing means and the intermediate frequency. A second mixing means for receiving an _RFT and a cosω _IFT , which is a Q-phase component of an intermediate frequency, multiplying the two intermediate frequency signals by an input signal from the first mixing means, and outputting two mixed signals respectively; A low pass filtering means for receiving a low pass filtering signal and outputting each signal, and converting the two low pass filtered signals into a digital signal; And a PN code generator for receiving a predetermined PN clock, and generating and outputting a PN code in synchronization therewith, the two digitally converted signals and the PN code, respectively. Despreading means for multiplying the converted signal by the PN code and converting the resultant signal into I (t), which is an inversely processed I channel signal, and Q (t), which is a Q channel signal, and I (t) and Q ( t) an initial synchronization and synchronization tracking means for receiving the PN code synchronization and synchronization tracking of the two input signals and outputting a synchronization tracking result signal corresponding to the result, and receiving the synchronization tracking result signal, PN clock control means for outputting a corresponding clock control signal, PN clock generation means for receiving the clock control signal and generating and outputting a PN clock controlled to the input signal to control the generation of a PN code; It is composed of synchronous demodulation means for receiving I (t) and Q (t) and checking the PN code synchronization of the two input signals and outputting the two input signals as synchronous demodulated data when it is confirmed that the PN code synchronization has been achieved. And a data receiver of a spread spectrum communication system using a pilot channel. 6. The apparatus of claim 5, wherein the demodulation and demodulation means receives first and second Walsh code generators for generating and outputting first and second Walsh codes, and inputs I (t) and the first Walsh code. A first multiplier for multiplying and outputting an input signal, a second multiplier for receiving the Q (t) and the first Walsh code, multiplying and outputting the two input signals, and the I (t) and the second wall seed A third multiplier configured to receive and multiply the two input signals and output the multiplier, a fourth multiplier to receive the Q (t) and the second wall seed and multiply the two input signals and output the multiplied input signals; Receiving an output signal of a multiplier, respectively, the first accumulator and the second accumulator for accumulating and outputting the input signals, respectively, and the output signal of the third and fourth multiplier, respectively, and accumulate the input signals A third accumulator and a fourth accumulator to output, and the first and fourth accumulators A fifth multiplier that receives an output signal of an adder and multiplies the two input signals and outputs the output signal of the second and third accumulators, and a sixth multiplier that multiplies and outputs the two input signals; A subtractor for receiving the output signals of the fifth and sixth multipliers, calculating and outputting a difference between the two input signals, and receiving the output signal of the subtractor, detecting the phase of the data from the input signal, and outputting the final demodulated data. And a data receiver of a spread spectrum communication system using a pilot channel, characterized in that it is composed of a determinant. In the spread spectrum communication system, a low noise amplifier for amplifying and outputting a received signal received through an antenna, a band pass filter for receiving the low noise amplifying means and band-filtered output the output signal, and the band-filtered signal and wireless It receives a cosω _RFT which is a frequency signal, receives a first multiplier that multiplies the two input signals and converts the signal into an intermediate frequency signal, and receives the output signal of the first multiplier and cosω _RFT which is an I-phase component of the intermediate frequency. A second multiplier for multiplying and outputting the two input signals, a third multiplier for receiving the output signal of the first multiplier and sinω _IFT , which is a Q-phase component of an intermediate frequency, and multiplying the two input signals and outputting the second multiplier; And first and second low pass filters which receive the output signals of the third multiplier, respectively, and output them by low pass filtering, and the two low-pass filtered signals. First and second analog-to-digital conversion means for receiving and converting into a digital signal, and outputting a predetermined PN clock, and a PN code generator for generating and outputting a PN code in synchronization with the first and second analog-to-digital conversion means. A fourth multiplier configured to receive an output signal of the PN code and multiply the two input signals, and output an I (t) signal which is a despread I-channel signal; an output signal of the second analog-to-digital conversion means and the PN code; Receiving a code, multiplying the two input signals, and outputting Q (t) which is a Q channel signal despread, and receiving I (t) and Q (t) from the fourth and fifth multipliers; An initial sync and a sync tracker for synchronizing and synchronizing the PN codes of two input signals and outputting a sync trace result signal corresponding to the result, and receiving the sync trace result signal and outputting a clock control signal corresponding to the input signal doing A PN clock controller, a PN clock generator for receiving the clock control signal and generating and outputting a PN clock which is controlled by the input signal to control the generation of the PN code, and a first and second Walsh codes generated and outputted. A second Walsh code generator, the I (t) and the first Walsh code are input, a sixth multiplier that multiplies and outputs the two input signals, and receives the Q (t) and the first Walsh code, A seventh multiplier to multiply and output the two input signals, an eighth multiplier to receive the I (t) and the second Walsh code, multiply and output the two input signals, and the Q (t) and the second A first accumulator for receiving a Walsh code, multiplying the two input signals, and outputting the output signals of the sixth and seventh multipliers, and accumulating and outputting the input signals, respectively; And output signals of the eighth and ninth multipliers. A third accumulator and a fourth accumulator, each of which receives the input signals and accumulates the input signals, and outputs the output signals of the first and fourth accumulators and multiplies and outputs the two input signals; An output signal of the second and third accumulators is input, an eleventh multiplier that multiplies the two input signals, and an output signal of the tenth and eleventh multipliers, and calculates and outputs a difference between the two input signals; And a determiner configured to receive a subtractor and an output signal of the subtractor, detect a phase of the data from the input signal, and determine a final demodulated output of the data. In a spread spectrum communication system, first and second Walsh code generating means for generating and outputting first and second Walsh codes having respective code systems, a predetermined pilot signal and data to be transmitted are received, and receiving the first and second Walsh codes. Walsh modulating means for receiving a Walsh code and multiplying the pilot signal and data to output a Walsh modulated pilot signal and data, a first PN code generating means for generating and outputting a predetermined PN code, and the Walsh modulated pilot A band spreading means for receiving a signal and data as the PN code and spreading the two Walsh-modulated input signals, respectively, and a finite impulse response for filtering the spread spectrum signal and data by finite impulse response filtering; Analyzing the spreading pilot signal and data filtered by the filtering means and the finite impulse response filtering means. Digital to analog conversion means for converting and outputting the signal, first low pass filtering means for receiving the analog-converted pilot signal and data and low-pass filtering and outputting the low-pass filtered pilot signal and data; receive input an intermediate frequency signal, wherein the pilot bit input signal and multiplies the I- phase component of cosω _IFT of an intermediate frequency by multiplying the in-phase component of Q- sinω _IFT of said data input signal and the intermediate frequency IF signal mixed with the pilot bit Intermediate frequency mixing means for outputting signals and data, respectively; Coupling means for receiving the intermediate frequency mixed pilot signal and data, combining the two input signals and outputting; Output signal and the predetermined radio frequency of the combining means It receives the input signal cosω _RFT, and first mixing means for the two output by multiplying the input signal, the first A data transmitter including first band filtering means for receiving an output signal of the summation means and band-filtering the output signal, and first amplifying means for receiving the band-filtered signal and amplifying the signal according to a predetermined amplification ratio and transmitting the same through an antenna; A second amplifying means for amplifying and outputting a received signal received through an antenna; a second band filtering means for receiving an output signal of the low noise amplifying means and band-filtering and outputting the band-filtered signal and a radio frequency signal; A second mixing means for receiving the cosω _RFT and multiplying the two input signals into a signal of an intermediate frequency component, a cosω _IFT which is an I-phase component of an output signal of the second mixing means and an intermediate frequency, and an intermediate frequency. Receives sinω _IFT , which is the Q-phase component of, and multiplies two intermediate frequency signals by an input signal from the second mixing means A third mixing means for outputting a mixed signal, a second low pass filtering means for receiving the two mixed signals and performing low pass filtering, respectively, and an analog for receiving the two low pass filtered signals and converting them into a digital signal and outputting the respective signals; Digital conversion means, a second PN code generating means for receiving a predetermined PN clock and generating and outputting a PN code in synchronization therewith, receiving the two digitally converted signals and the PN code, and receiving the PN signals in the two digitally converted signals. Despreading means for multiplying the code and converting and outputting the despread I-channel signal I (t) and Q (t) channel signal Q (t), respectively, and despreading means for I (t) and Q (t). Initial synchronization and synchronization tracking means for receiving the PN code synchronization and synchronization tracking of the two input signals and outputting a synchronization tracking result signal corresponding to the result; and receiving the synchronization tracking result signal, PN clock control means for outputting a corresponding clock control signal, PN clock generation means for receiving the clock control signal and generating and outputting a PN clock that is controlled by the input signal and controls generation of a PN code, and I (t And Q (t), and checking the PN code synchronization of the two input signals and outputting the two input signals as synchronous demodulated data when it is confirmed that the PN code synchronization has been achieved. A data transceiver of a spread spectrum communication system using a pilot channel, characterized in that the configuration. 9. The apparatus of claim 8, wherein the synchronous demodulation means comprises: first and second Walsh code generators for generating and outputting third and fourth Walsh codes respectively corresponding to the first and second Walsh codes, and the I (t) And a first multiplier for receiving the first Walsh code, multiplying and outputting the two input signals, and receiving the Q (t) with I (t) and Q (t) and the first Walsh code. A second multiplier for multiplying and outputting an input signal, a third multiplier for receiving the I (t) and the second Walsh code, multiplying and outputting the two input signals, and a second multiplying code of the Q (t) and the second Walsh code A fourth multiplier for multiplying and outputting the two input signals, a first multiplier for receiving output signals of the first and second multipliers, and accumulating and outputting the input signals, respectively; Receive the output signals of the third and fourth multipliers, respectively, and accumulate the input signals, respectively. A third accumulator and a fourth accumulator to be outputted, a fifth multiplier receiving the output signals of the first and fourth accumulators, and multiplying the two input signals and outputting the output signals of the second and third accumulators. And a sixth multiplier for outputting the two input signals, an output signal of the fifth and sixth multipliers, a subtractor for calculating and outputting a difference between the two input signals, and an output signal of the subtractor. A data transceiver of a spread spectrum communication system using a pilot channel, characterized in that it is configured to receive an input, and detects the phase of the data from the input signal to the final demodulation output of the data. ※ Note: The disclosure is based on the initial application.