CA2207288C - Automatic gain control circuit and method therefor - Google Patents

Abstract

An AGC circuit of a high definition signal receiver includes a non-coherent AGC signal generator for generating a first AGC signal according to the magnitude of said IF signal, a coherent AGC signal generator for generating a second AGC
signal according to the magnitude of the segment synchronizing signal, and a selector for selecting the second AGC signal when the segment synchronizing signal is detected and the first AGC signal when the segment synchronizing signal is not detected and providing them to a tuner/IF demodulator. The amplitude of the received signal is controlled within a short period of time using the non-coherent AGC method having a fast response time before a system is stabilized and the amplitude of the received signal is controlled more correctly using the coherent AGC method after the segment synchronizing signal is detected.

Description

AUTOMATIC GAIN CONTROL CIRCUIT AND METHOD THEREFOR

Backqround of the Invention The present invention relates to a receiver for receiving a high definition signal, and more particularly, to an automatie gain eontrol eireuit of a high definition TV
(hereinafter, HDTV) reeeiver and a method therefor.
In general, in a radio frequeney (RF) signal transmitted from a transmitter, the amplitude of a signal is ehanged by various channel circumstances during transmission and is received by a receiver. In an automatic gain control (hereinafter, AGC), the amplitude of a received signal with severe ehanges in the amplitude is uniformly eontrolled to a predetermined level, which is eritieal for a digital signal processing system. When the amplitude of the received signal changes, it is not possible to reproduce the original signal since appropriate demodulation is difficult to perform in the recelver.
Meanwhile, a conventional AGC circuit used for an RF
receiver having a digital signal processor is provided in U.S.
Patent No. 5,451,948. In the eonventiQnal AGC eircuit provided in the above-mentioned patent, a sampling eloek eorresponding to a frequeney of more than two times an intermediate frequency (IF) signal is required during an analog-to-digital (A/D) conversion since the IF signal is used. Therefore, when the AGC circuit is realized, an expensive device with a very fast operation speed must be -used. Also, timing must be correctly adjusted when a front-end AGC signal is forwarded to a back-end AGC loop and an AGC
operation is not stable since an input signal is used. In particular, the AGC circuit is minimally effective when it is applied to the GA-HDTV (Grand Alliance-HDTV) system due to the characteristics of a vestigial sideband (VSB), the transfer signal standard of the GA system.

Summary of the Invention It is an object of the present invention to provide an automatic gain control (AGC) circuit for compensating for the change in amplitude of a received signal due to channel circumstances during transmission using the amplitude of a received signal and the average amplitude value of a segment synchronous signal and maintaining the amplitude at a uniform level, in a receiver for receiving a high definition signal.
It is another object of the present invention to provide an AGC method for maintaining a received signal at a uniform level using the amplitude of the received signal and the average amplitude value of a segment synchronous signal, in the receiver for receiving the high definition signal.
To achieve the first object, there is provided an automatic gain control (AGC) circuit for a receiver including a tuner/IF demodulator for receiving a high definition signal comprised of a plurality of segments each formed of a segment synchronizing signal and a predetermined number of symbols and outputting an intermediate frequency (IF) signal of a predetermined level acco~ding to an automatic gain control (AGC) signal and a synchronizing signal detector for detecting the segment synchronizing signal from the IF signal, in which a non-coherent AGC signal generator generates a first AGC
signal according to the magnitude of the IF signal, a coherent AGC signal generator generates a second AGC signal according to the magnitude of the segment synchronizing signal, and a selector selects the second AGC signal when the segment synchronizing signal is detected and the first AGC signal when the segment synchronizing signal is not detected and provides the selected signal to the tuner/IF demodulator as the AGC
signal.
To achieve the second object, there is provided an AGC
method of a receiver for receiving an HDTV signal comprised of a plurality of segments each formed of a segment synchronizing signal and a predetermined number of symbols, outputting an intermediate frequency (IF) signal having a uniform amplitude according to an AGC signal, and detecting the segment synchronizing signal from the IF signal, the AGC method comprising the steps of detecting the difference between the amplitude of an input IF signal and a previously set first reference value and generating a first AGC signal, detecting the difference between the amplitude of the segment synchronizing signal and a previously set second reference value and generating a second AGC signal, and selecting the second AGC signal when the segment synchronizing signal is detected, selecting the first AGC signal when the segment synchronizing signal is not detected, and applying the AGC
signals.

Brief Description of the Drawinqs The above objects and advantages of the present invention will become more apparent by describing in detail a preferred embodiment thereof with reference to the attached drawings in which:
FIG. 1 is a block diagram showing the whole structure of a high definition TV to which the present invention is applied;
FIG. 2 shows the structure of a data segment of the GA-HDTV format; and FIG. 3 is a circuit diagram showing the structure of anautomatic gain control circuit according to an embodiment of the present invention.

Detailed Description of the Invention In the HDTV according to the present invention, as shown in FIG. 1, a tuner/IF demodulator 102 converts a signal received through antenna (not shown) into an IF signal of a predetermined frequency. An analog-to-digital (A/D) converter 104 converts an analog IF signal supplied from the tuner/IF
demodulator 102 into a digital signal. A digital frequency and phase locked loop (DFPLL) circuit 106 restores a carrier wave using a pilot signal included in data output from the A/D
converter 104, and multiplies the restored carrier wave by the output data of the A/D converter 104 to demodulate the carrier wave to data of a baseband.
A match filter 108 matches a demodulated baseband signal output from the DFPLL 106 to a pre-transmission signal. A

symbol timing restorer 110 restores symbol timing using the output signal of the match filter 108.
A synchronizing signal detector 112 detects various synchronizing signals using the output signal of the match filter 108 and provides the synchronizing signal to respective portions. The synchronizing signal detector 112 obtains the correlation values of the data output from the match filter 108 in four symbol units, accumulates the obtained correlation values in a segment unit, and generates a segment synchronizing signal at a position in which a maximum correlation accumulative value is detected in every data segment using the fact that the correlation value of a four data segment synchronous symbol has the maximum value. FIG. 2 shows the structure of a data segment of a vestigial sideband (VSB).
In FIG. 2, 832 symbols (208 bytes) comprised of 828 symbol data and four symbol data segment synchronization comprise one data segment. The data segment synchronizing signal is inserted into a beginning portion of the respective data segments of eight-level (_7, +5, _3, and _1) digital data streams. At this time, the data segment synchronizing signal is formed of a uniform pattern in which four symbols have the values of +5, -5, -5, and +5, respectively and the remaining data has an optional level among eight-levels. FEC denotes a forward error code.
A voltage controlled oscillator (VCO) 114 outputs a symbol clock si~nal to the A/D converter 104 as a sampling clock signal, adjusting the symbol timing restored in the -symbol timing restorer 110.
Meanwhile, an NTSC removing filter 116 for preventing the deterioration of the HDTV signal due to an NTSC signal in co-channel circumstances in which the HDTV signal and the NTSC
signal are simultaneously broadcast removes carrier components of the NTSC signal from the output of the match filter 108.
An equalizer 118 removes multi-path noise generated when the transmitted signal passes through a transfer channel. The multi-path noise distorts the frequency characteristics of the HDTV signal.
A phase tracking loop (PTL) circuit 120 removes noises of a phase which are not removed in the DFPLL circuit 106, namely, the error of the phase. A Trellis decoder 122 performs slicing and convolutional decoding with respect to the output of the PTL circuit 120 in order to protect it against a burst interference such as impulse noise or an NTSC
co-channel interference.
A de-interleaver 124 de-interleaves the output of the Trellis decoder 122. A Reed-Solomon (R/S) decoder 126 corrects the error of the de-interleaved data using a parity.
A de-randomizer 128 outputs the error-corrected data to a pseudo-random sequence (PRS) code.
Meanwhile, an AGC circuit 200 responds to the amplitude of a signal output from the A/D converter 104 and a segment synchronizing signal detected from the synchronizing signal detector 112, generates an AGC signal according to the average amplitude value of the segment synchronizing signal output from the match filter 108, and provides the signal to the . ' tuner/IF demodulator 100. The tuner/IF demodulator 100 controls the amplitude of the IF signal according to the AGC
signal.
FIG. 3 is a circuit diagram of the AGC circuit of an HDTV
receiver according to an embodiment of the present invention.
A non-coherent AGC signal generator 210 of the AGC
circuit 200 of the present invention includes a first latch 211 for latching the output signal of the A/D converter 104 of FIG. 1, an absolute value circuit 212 for obtaining the absolute value of the output of the first latch 211, a first subtractor 213 for subtracting the output of the absolute value circuit 212 from a first reference value, and a first gain controller 214 for controlling the gain according to the output of the first subtractor 213.
A coherent AGC signal generator 220 includes a 4-symbol adder 221 for adding the signal output from the match filter 108 of FIG. 1 in a 4-symbol unit, a divider 222 for dividing the output of the 4-symbol adder 221 and obtaining an average, a second latch 223 for latching the output of the divider 222 according to the segment synchronizing signal detected in the synchronizing signal detector 112 of FIG. 1, a second subtractor 224 for subtracting the output of the second latch 223 from a second reference value, and a second gain controller 215 for controlling the gain according to the output of the second subtractor 224. Here, three unit symbol delays are connected in series in the 4-symbol adder 221. The 4-symbol adder 221 is comprised of an adder 221.4 for adding the outputs of the respective unit symbol delays 221.1 through 221.3.
A selector 230 comprised of a multiplexer selects the output signal of the non-coherent AGC signal generator 210 or the output signal of the coherent AGC signal generator 220. A
digital accumulator 240 accumulates the output signal of the selector 230. A digital-to-analog (D/A) converter 250 converts the output signal of the digital accumulator 240 into an analog signal. A low-pass filter 260 filters the output signal of the D/A converter 250. An amplifier 270 amplifies the filtered signal and applies the amplified AGC signal to the tuner/IF demodulator 102 shown in FIG. 1.
The operation of the apparatus shown in FIG. 3 will be described with reference to FIG. 1.
In FIG. 3, the first latch 211 of the non-coherent AGC
signal generator 210 holds the HDTV signal output from the A/D
converter 104 of FIG. 1. The absolute value circuit 212 obtains the absolute values of all the signals output from the first latch 211 and converts the signals into positive values.
The first subtractor 213 subtracts the output signal of the absolute value circuit 212 from the first reference value.
When the output signal of the absolute value circuit 212 is larger than the first reference value, the output of the first subtractor 213 has a negative value. When the output signal of the absolute value circuit 212 is less than the first reference value, the output of the first subtractor 213 has a positive value. Here, the first reference value is a constant which can be obtained through experiment.
The first gain controller 214 applies the AGC signal, in .~

which the gain of the signal output from the first subtractor 213 is controlled, to a first input terminal of the selector 230. Therefore, an AGC signal for decreasing the amplitude of the IF signal output from the tuner/IF demodulator 102 of FIG.
1 is output when the output of the first subtractor 213 has a negative value and an AGC signal for increasing the amplitude of the IF signal output from the tuner/IF demodulator 102 is output when the output of the first subtractor 213 has a positive value.
As mentioned above, the AGC signal is generated using the magnitudes of all the input signals in the non-coherent AGC
signal generator.
Meanwhile, a signal input to the 4-symbol adder 221 of the coherent AGC signal generator 220 is the HDTV signal output from the match filter 108 of FIG. 1. With respect to this signal, symbol timing restoration and carrier wave restoration are performed in the symbol timing restorer 110 and the DFPLL 106.
Therefore, the 4-symbol adder 221 obtains the average of the added vaIue obtained in the 4-symbol unit by adding the input signals in the 4-symbol unit and dividing the outputs of the 4-symbol adder 221 by 4 in the divider 222.
The second latch 223 performs a timing hold with respect to the outputs of the divider 222 by the segment synchronizing signal output from the synchronizing signal detector 112 of FIG. 1. Namely, only the average value of the 4-symbols which are segment synchronizing signal portions shown in FIG. 2 are output through the second latch 223 since the second latch 223 outputs the latched signal only when the segment synchronizing signal is generated.
The second subtractor 224 subtracts the output signal of the second latch 223 from a second reference value. When the output signal of the second latch 223 iS larger than the second reference value, the output of the second subtractor 224 has a negative value. When the output signal of the second latch 223 is less than the second reference value, the output of the second subtractor 224 has a positive value.
The second gain controller 225 applies the AGC signal in which the amplitude of the signal output from the second subtractor 224 is controlled to the second input terminal of the selector 230.
Therefore, the AGC signal for decreasing the amplitude of the IF signal of the tuner/IF demodulator 102 is output when the output of the second subtractor 224 has a negative value and the AGC signal for increasing the amplitude of the IF
signal of the tuner/IF demodulator 102 is output when the output of the first subtractor 224 has a positive value. As mentioned above, the AGC signal is generated using the average amplitude value of the segment synchronizing signal in the coherent AGC signal generator.
The selector 230 selects an output signal of the non-coherent AGC signal generator 210 or the output signal of the coherent AGC signal generator 220 according to the segment synchronizing signal. When the segment synchronizing signal is correctly detected in the synchronizing signal detector 112 of FIG. 1, the selector 230 selects the output signal of the coherent AGC signal generator 220.
The digital accumulator 240 continuously accumulates signals selected in the selector 230. The D/A converter 250 converts the values accumulated in the accumulator 240 into analog signals. The low-pass filter 260 filters (accumulates) the output signal of the D/A converter 250 in an analog manner. The amplifier 270 amplifies the amplitude of the filtered signal and applies the signal to the tuner/IF
demodulator 102 shown in FIG. 1. The tuner/IF demodulator 102 controls the amplitude of the IF signal according to the AGC
signal output from the amplifier 270.
It is possible to maintain a uniform amplitude though the amplitude of the signal of the tuner/IF demodulator 102 changes since the outputs of the first and second subtractors 213 and 214 become negative and reduce the amplitude of the input signal when the HDTV signal input to the tuner/IF
demodulator 102 and the segment synchronizing signal loaded on the HDTV signal are larger than the first reference value set in the non-coherent AGC signal generator 210 and the second reference value set in the coherent AGC signal generator 220 and the outputs of the first and second subtractors 213 and 214 become positive and increase the amplitude of the input signal when the HDTV signal input to the tuner/IF demodulator 102 and the segment synchronizing signal loaded on the HDTV
signal are less than the first reference value set in the non-coherent AGC signal generator 210 and the second reference value set in the coherent AGC signal generator 220.
In the present invention, the amplitude of the received signal is controlled within a short time using the non-coherent AGC method having a fast response time before a system is stabilized and the amplitude of the received signal is controlled more accurately using the coherent AGC method after the segment synchronizing signal is detected. Thus, it is possible to correctly control the amplitude using the coherent AGC method since the method operates only in the portion in which the segment synchronizing signal is generated.
Also, the present invention can be applied to a digital video recording apparatus as well as a digital TV including a digital GA-HDTV system.
It is possible to uniformly maintain the level of the received signal even if severely fluctuating amplitude of the signal is input to the receiver due to various channel circumstances during the transmission and to correctly demodulate the received signal in the receiver using the present invention in the HDTV receiver.

Claims (14)

1. An automatic gain control (AGC) circuit for a receiver including a tuner/IF demodulator for receiving a high definition signal comprised of a plurality of segments each formed of a segment synchronizing signal and a predetermined number of symbols and outputting an intermediate frequency (IF) signal of a predetermined level according to an automatic gain control (AGC) signal and a synchronizing signal detector for detecting the segment synchronizing signal from the IF
signal, the AGC circuit comprising:
a non-coherent AGC signal generator for generating a first AGC signal according to the magnitude of said IF signal;
a coherent AGC signal generator for generating a second AGC signal according to the magnitude of said segment synchronizing signal; and a selector for selecting said second AGC signal when said segment synchronizing signal is detected and said first AGC
signal when said segment synchronizing signal is not detected and providing the selected signal to said tuner/IF demodulator as said AGC signal.

2. An AGC circuit as claimed in claim 1, wherein said non-coherent AGC generator comprises:
a first latch for latching said IF signal and outputting the first latched signal;
an absolute value circuit for obtaining the absolute value of said first latched signal;
a first subtractor for subtracting the output of the absolute value circuit from a first reference value; and a first gain controller for controlling a gain according to the output of said first subtractor and outputting the first AGC signal.

3. An AGC circuit as claimed in claim 2, wherein the output of the first subtractor has a negative value when the output signal of said absolute value circuit is larger than the first reference value and the output of the first subtractor has a positive value when the output signal of said absolute value circuit is less than the first reference value.

4. An AGC circuit as claimed in claim 1, wherein said coherent AGC signal generator generates the second AGC signal using the average magnitude of said segment synchronizing signal.

5. An AGC circuit as claimed in claim 1, wherein said coherent AGC signal generator comprises:
a 4-symbol adder for adding said demodulated signals in a 4-symbol unit;
a divider for obtaining the average of the outputs of said 4-symbol adder;
a second latch for latching the outputs of said divider and outputting a second latched signal according to said segment synchronizing signal;
a second subtractor for subtracting the second latched signal from a second reference value; and a second gain controller for controlling a gain according to the output of said second subtractor and outputting the second AGC signal.

6. An AGC circuit as claimed in claim 5, wherein the output of the second subtractor has a negative value when the output signal of said second latch is larger than the second reference value and the output of the second subtractor has a positive value when the output signal of said second latch is less than the second reference value.

7. An AGC circuit as claimed in claim 1, further comprising an accumulator for accumulating the output signal of said selector.

8. An AGC circuit as claimed in claim 7, further comprising an amplifier for amplifying the output of said accumulator.

9. An AGC circuit as claimed in claim 8, further comprising a digital-to-analog (D/A) converter for converting the output signal of said accumulator into an analog signal and a low-pass filter for filtering the output signal of said D/A converter.

10. An automatic gain control (AGC) method of a receiver for receiving an HDTV signal comprised of a plurality of segments each formed of a segment synchronizing signal and a predetermined number of symbols, outputting an intermediate frequency (IF) signal having a uniform amplitude according to an AGC signal, and detecting the segment synchronizing signal from said IF signal, the AGC method comprising the steps of:
(a) detecting the difference between the amplitude of an input IF signal and a previously set first reference value and generating a first AGC signal;
(b) detecting the difference between the amplitude of said segment synchronizing signal and a previously set second reference value and generating a second AGC signal; and (c) selecting said second AGC signal when said segment synchronizing signal is detected, selecting said first AGC
signal when said segment synchronizing signal is not detected, and applying said AGC signals.

11. An AGC method as claimed in claim 10, wherein the first AGC signal has a negative value when the magnitude of said transferred IF signal is larger than the first reference value and the first AGC signal has a positive value when the magnitude of said IF signal is less than the first reference value in said step (a).

12. An AGC method as claimed in claim 10, wherein the second AGC signal is generated by obtaining the average value of the amplitude of said segment synchronizing signal and detecting an error between the average value and said second reference value.

13. An AGC method as claimed in claim 10, wherein the output of the second AGC signal has a negative value when said segment synchronizing signal is larger than the second reference value and the output of the second AGC signal has a positive value when said segment synchronizing signal is less than the second reference value in said step (b).

14. An AGC method as claimed in claim 10, wherein said first reference value is a predetermined constant and the second reference value is the average amplitude of the segment synchronizing signal.