CS232430B1 - Amplifier with automatic regulation fo gain - Google Patents

Abstract

The wiring according to the invention realizes an amplifier which, at its output, maintains a television signal with a measuring line at a specified unit size. Its merit over the hitherto known words is the ease of engagement. In the amplifier channel there is only a control circuit and a low-pass amplifier at the output. There are two sampling circuits in the control loop, a correction amplifier and an integrator. The wiring can also be used in automatic TV signal level correctors in studios and TV transmitters.

Description

(54) Amplifier with automatic gain control

The circuit according to the invention implements an amplifier which at its output keeps the television signal with the measurement line at a specified unit size. Its advantage over the previously known language is its simplicity of involvement. The amplifier channel contains only the control circuit and the low-pass amplifier at the output. There are two sampling circuits in the control loop, a correction amplifier and an integrator. The wiring can also be used in automatic TV signal level correctors in studios and TV transmitters.

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232430 2

The invention dilutes an amplifier with automatic gain control, particularly suitable for television measuring technology.

A variety of amplifier connections are known which maintain a unit size television signal at their output. The regulation is derived from a white pulse of 10 µm in the measurement line No. 17 and this pulse is maintained at the specified magnitude by the amplifier control loop. At the same time, the actual amplifier of the signal is subject to high requirements in terms of linear and non-linear distortions, which must be maintained at the order of 0.1%.

The disadvantages of the hitherto known circuitry are the high circuit complexity required to fulfill the desired function, which also results in lower circuit reliability and higher power requirements.

These drawbacks are overcome by the connection of an automatic gain control amplifier according to the invention.

It consists in that the input of the divider is connected to the source of the controlled signal and the output of the divider is connected to the signal input of the control circuit, the output of the control circuit is connected to the input of the first amplifier and the output of the first amplifier is connected to the signal output a first sample circuit input and a second sample circuit signal input, wherein a first sample circuit control input is connected to a first sample pulse source and a second sample circuit control input is connected to a second sample pulse source, and a first sample circuit output is coupled to a first second amplifier input; the output of the second sampling circuit is coupled to the second input of the second amplifier, wherein the third input of the second amplifier is connected to a reference voltage source, and the output of the second amplifier is coupled to the passive correction input Circuitry, wherein the passive output correction circuit is connected to the input of the integrator and the integrator output is connected to the control input of the control circuit.

This circuitry considerably simplifies the amplifier circuit solutions in both the signal and control loop circuits.

The invention will be further explained in the circuit according to FIG. 1.

In the circuit according to the invention, the input of the divider D is connected to the source U of the controlled signal and the output of the divider D is connected to the signal input 2 of the control circuit RO. The output of the control circuit RO is connected to the input of the first amplifier Z1. The low pass filter input DP is connected to the output of the first amplifier Z1. The low pass filter output DP is connected to the signal output U 'and further to the signal input £ of the first sampling circuit V1 and to the signal input druhého of the second sampling circuit V2.

A first pulse source V1 1 is connected to the control input 5 of the first sampling circuit V1, and a second pulse source V1 2 is connected to the control input 60 of the second sampling circuit V2. The output of the first sampling circuit V1 is connected to the first input 2 of the second amplifier Z2 and the output of the second sampling circuit V2 is connected to the second input 8 of the second amplifier Z2.

A reference voltage source U is connected to the third input 2 of the second amplifier Z2.

The output of the second amplifier Z2 is connected to the input of the passive correction circuit PK. The output of the passive correction circuit PK is connected to the IN integrator input and the IN integrator output is connected to the control input 2 of the control circuit RO.

Sample pulse sources VI1 and VI2 supply pulses of time corresponding to both the center of the white pulse in the 17th measurement line and the blanking level in the 17th measurement line. The difference in the DC output levels of the first sampling circuit V1 and the second sampling circuit V2 corresponds to the amplitude of the white pulse in the low pass filter output DP.

Lowpass DP restricts the band of the signal in the high frequency e separates the capacitive load output U _g signal from the output of the amplifier Z1.

The second amplifier Z2 compares the difference of the output levels of the first sampling circuit V1 and the second sampling circuit V2 with the voltage of the reference voltage source U and gives the output a correction voltage which controls the gain in the control circuit RO through the passive correction circuit PK. This closes the control loop. The passage correction circuit PK adjusts the transmission of the control loop in the frequency domain to achieve an aperiodic response to the signal jump.

At the low pass filter output, the control loop maintains a constant voltage across the entire operating range.

The entire signal amplifier can be implemented with two integrated circuits and two transistors. The control loop includes four additional integrated circuits and four transistors. Compared to the wiring used so far, this means savings of around 30 transistors and 6 integrated circuits. This significantly reduces the possibility of non-linear signal distortion due to active elements. Overall circuit simplicity contributes to high wiring reliability and low power consumption.

SUBJECT OF THE INVENTION

Claims (1)

1. An amplifier with automatic gain control, characterized in that the input of the divider (D) is connected to the source (U _g) of a controlled signal and the output of the divider (D) is connected to the signal input (1) of the control circuit (RO), the output control circuit ( Is connected to the input of the first amplifier (Z1) and the output of the first amplifier (Z1) is connected via the low pass filter (DP) to the signal output (U _g ) and the signal input (3) of the first sampling circuit (VI) and signal the input (5) of the second sampling circuit (V2), the control input (4) of the first sampling circuit (VI) being connected to the first sampling pulse source (VI1) and the control input (6) of the second sampling circuit (VI 2) connected to the second sampling pulse source (V1 2) and the output of the first sampling circuit (V1) is connected to the first input (7) of the second amplifier (Z2) and the output of the second sampling circuit (V2) is connected to the second input (8) of the second the third input (9) of the second amplifier (Z2) is connected to a reference voltage source (U _r ) and the output of the second amplifier (, Z2) is connected to the input of the passive correction circuit (PK), the output of the passive correction circuit (PK) is connected to the integrator input (IN) and the integrator (IN) output is connected to the control input (2) of the control circuit (RO).