KR970019576A - Symbol Timing Recovery Method and Apparatus for GA-VSB System - Google Patents

Abstract

The present invention relates to a method and a device for recovering symbol timing of a GA-VSB system, in particular by detecting two data near a zero point, a _n and a _n-2 , and a _n-1 or -a _{n. Since} the sampling point is moved by driving PLL using _-1 as a control signal, GA-VSB which can respond quickly to channel change by performing symbol timing recovery by symbol unit of segment synchronization signal instead of 1 segment unit. In addition to providing a method for recovering the symbol timing of the system and a device therefor, in association with the symbol timing recovery apparatus by the correlation calculation, the system uses a zero-crossing detection method at the beginning of the system and a correlation calculation when the system is stable. It is possible to switch in a way, and to respond quickly to channel changes, and to obtain accurate timing information when the system is stable, the core of the GA-VSB system It provides a timing recovery method and apparatus.

Description

Symbol Timing Recovery Method for GA-VSB System

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

4 is a block diagram of a symbol timing recovery apparatus of a GA-VSB system according to the present invention;

FIG. 5 is a waveform diagram for explaining a control signal of a controller in the symbol timing recovery apparatus of the GA-VSB system of FIG.

6 is a block diagram of an application example of a symbol timing recovery apparatus of the GA-VSB system according to the present invention.

Claims (11)

A symbol timing recovery method for a GA-VSB system, comprising: a first step of performing quadrature demodulation on input analog data to output a phase invariant component and a quadrature phase component; A second step of digitally converting the quadrature component output in the first step by twice the sampling frequency (= 2f _s ); A third step of delaying the digitally converted data in the second step by a half period of a sampling period (1 / fs = T); A fourth step of delaying the data delayed in the third step by a half period of a sampling period (1 / fs = T) again; The PLL is driven to increase or decrease the sampling frequency based on the zero-crossing detection result from the data digitally converted in the second step, the half-cycle delayed data in the third step, and the data delayed by one cycle in the fourth step. Symbol timing recovery method of the GA-VSB system, characterized in that it comprises a fifth step. The sampling period according to claim 1, wherein the fifth step is the non-delayed data a _n , which is two data near the zero point, and one period of the sampling period, which is delayed data a _n-2 and the sampling period therebetween. And determining a PLL control signal according to a zero-crossing point detection result from the half-cycle delayed data (a _n-1 ) of the GA-VSB system. The method of claim 2, wherein in the fifth step, three data consisting of two data (a _n, a _n-2 ) near the zero point and data (a _n-1 ) therebetween for detecting the zero-crossing point are collected. A symbol timing recovery method of a GA-VSB system, characterized in that the extraction is performed every one period of the sampling cycle. 4. The method of claim 3, wherein the fifth step determines a sign of a control signal for determining to increase or decrease a sampling frequency by a _n-1 , and increases the sampling frequency when the sign of the control signal is (+). When the sampling point is moved forward and the control signal is negative, the sampling frequency is decreased. When the sampling point is moved backward, the sign of a _n is positive and the sign of a _n-2 is negative. If a _n-1 is determined to be a control signal and a _n is negative and a _n-2 is negative, -a _n-1 is determined to be a control signal to drive the PLL. Symbol timing recovery method of the GA-VSB system characterized in that. 4. The method of claim 3, wherein the fifth step determines a sign of a control signal for determining to increase or decrease a sampling frequency by a _n-1 , and increases the sampling frequency when the sign of the control signal is (-). When the sampling point is moved forward and the control signal is negative, the sampling frequency is decreased and the sampling point is moved backward. The sign of a _n is positive and the sign of a _n-2 is negative. it indicates the sign of the decision to a _n-1 as a control signal, and a _n (-) is characterized in that to determine a a _n-1 as the control signal driving the PLL when the sign of a _n-2 (+) Symbol timing recovery method of a GA-VSB system. A symbol timing recovery apparatus of a GA-VSB system, comprising: a quadrature demodulator for quadrature demodulating input analog data to output a phase invariant component and a quadrature phase component; A first A / D converter for digitally converting quadrature phase components in the output of the quadrature demodulator by twice the sampling frequency (= 2f _s ); A first delayer for delaying the data output from the first A / D converter by a half period of a sampling period; A second delayer outputting the data delayed by one cycle by delaying the data delayed by the first delay by a half cycle of a sampling cycle; PLL control based on a zero-crossing detection result from non-delayed data digitally converted by the first A / D converter, half-cycle delayed data by the first delayer, and one cycle delayed data output from the second delayer. A first controller which outputs a signal; And a phase synchronization loop (PLL) for increasing or decreasing a sampling frequency according to a control signal output from the control unit. The sampling period according to claim 6, wherein the first control unit is non-delayed data (a _n ), which is two data near a zero point, and one period of sampling period (a _n-2 ), and a sampling period between them. And determining a PLL control signal according to a zero-crossing point detection result from the half-cycle delayed data (a _n-1 ) of the GA-VSB system. The method of claim 7, wherein the first control unit comprises three data consisting of two data (a _n, a _n-2 ) near the zero point and data (a _n-1 ) therebetween for detecting a zero-crossing point. Symbol timing recovery apparatus of the GA-VSB system, characterized in that for extracting every sampling period. The method of claim 8, wherein the first control unit determines the sign of the control signal for determining to increase or decrease the sampling frequency by a _n-1 , and increases the sampling frequency when the sign of the control signal is (+) When the sampling point is moved forward and the control signal is negative, the sampling frequency is decreased. When the sampling point is moved backward, the sign of a _n is positive and the sign of a _n-2 is negative. when one determines a a _n-1 as the control signal and the sign of a _n - GA, characterized in that the output of the -a _n-1 as a control signal when the sign of _{a n-2 (+) (} ) -Symbol timing recovery device of VSB system. The method of claim 8, wherein the first control unit determines the sign of the control signal for determining to increase or decrease the sampling frequency by a _n-1 , and increases the sampling frequency when the sign of the control signal is (-) When the sampling point is moved forward and the control signal is negative, the sampling frequency is decreased and the sampling point is moved backward. The sign of a _n is positive and the sign of a _n-2 is negative. when one determines a a _n-1 as the control signal and the sign of a _n - GA, characterized in that the output of the -a _n-1 as a control signal when the sign of _{a n-2 (+) (} ) -Symbol timing recovery device of VSB system. The apparatus of claim 9 or 10, wherein the symbol timing recovery apparatus comprises: a second A / D converter configured to sample a phase invariant component output from the quadrature demodulator at a sampling frequency; A segment sync detector for detecting a segment sync signal by calculating a correlation between the data output from the second A / D converter and a sync pattern comparison signal; A second controller which extracts timing information from the segment sync signal detected by the segment sync detector and outputs a control signal for driving the PLL; And a switching unit for selecting a control signal output from the first control unit at an initial stage of the system and a control unit for selecting a control signal output to the second control unit in a ballast of the system. Timing recovery device. ※ Note: The disclosure is based on the initial application.