SU403111A1 - DEVICE FOR MEASURING THE MODULATION CHARACTERISTICS OF A KINESCOPE - Google Patents

Description

I

The invention relates to the field of radio measurements, namely television measurements.

A device for measuring the modulation characteristic of a kinescope is known, comprising a non-detecting television camera with a coordinate device, a gamma corrector, a video amplifier, an oscilloscope, a synchronous generator, a window signal generator, an electronic switch, a reference pulse generator.

A disadvantage of the known device is the impossibility of measurements in the presence of interference.

In order to measure the modulation characteristics when there are background, bright and temporal noise from an asynchronous network in the proposed device, an oscilloscope is connected to the output of the video amplifier through the control unit and the emitter follower through the electronic switch. threshold device, to the output of which a smooth delay multivibrator connected in series is simultaneously connected, D | differentiated 1.a circuit and - OUTPUT cascade connected to the input synchronization of the oscilloscope and successively connected fixed-delay multivibrator, forming a multivibrator and an amplifier-limiter, the output of which is connected to the input of the controlled anchor unit.

The drawing is a block diagram of the proposed device.

The device contains a transmitting television camera 1, a coordinate device 2, a gamma corrector 3, a video block 4, a video monitoring device (VCC) 5, a control unit 6, an oscillator 7 of reference pulses, an emitter follower 8, an oscilloscope 9, an electronic switch 10, a generator 11 window signals, threshold device 12, smooth delay multivibrator 13, differentiating circuit 14, output stage 15, fixed-delay multivibrator 16, forming multivibrator 17, limiter amplifier 18 and chip generator 19.

The structure works as follows. The transmitting camera is installed with the help of a coordinate device installed on the screen of a kinescope of the device under investigation in such a way that a portion of the image from the linear dimensions of the device under study is projected onto the photocathode of the transmission tube. In this case, the time intervals in the video signal of the transmitting tube are transformed with respect to the clock signal in the video signal of the device under study in the direction of increasing the first M times, where is the scaling factor, which allows reducing the frequency band of the measuring device and, consequently, increasing the measurement accuracy due to increasing the signal-to-noise ratio at its output.

The accuracy of the scale setting is monitored by comparing the video signal durations, corresponding to the transmission of the part available in the table with known dimensions and calibrated by the pulse width produced by the reference pulse generator. The transmitting camera is then oriented in such a way that a black and white differential is projected onto the photocathode. At the same time, a signal is formed at the output of the camera, the amplitude of which corresponds to the luminance distribution of the image under study, and the temporal ratios correspond to the time ratios increased 10 times in the video signal of the device under investigation.

The video signal from the camera output is amplified and fed to a gamma corrector, which linearizes the characteristics of the light-to-signal converter, which is necessary for undistorted conversion of the ratios (outliers). From the output of the gammacorrector, the video signal enters the video block, where a mixture of damping and synchronizing pulses is kneaded into it, after which it enters the ICU, which serves to tune the camera and monitor its operation. The video block also generates a signal containing only damping pulses (without a sync mixture), which is fed to the control loop block. An additive background noise causes the image to increase or decrease, which in turn causes a change in the constant component in the video signal of the meter, i.e., a change in the video signal level relative to damping pulses, which results in an amplitude vertical instability of the oscillogram of this video signal.

If the level fixation in the video signal is not performed in the blanking interval, but at some point in the active part of the line immediately before the interval observed on the oscilloscope screen, then the vertical instability of the oscillogram is eliminated. This operation is carried out by the controllable anchor block, and then the video signal through the emitter noirtor enters the oscilloscope. The oscillogram on its screen with the help of measuring and compensating pulses produced by the generator 7, measures the parameters of the transient characteristic (emissions, rise time).

Geometric background noise appears in the form of periodic image movement and causes temporary periodic fluctuations in the video signal corresponding to this image. On the oscilloscope screen, horizontal oscillations of the oscillogram are observed, which make it difficult and often impossible to measure the parameters of a video signal. To eliminate this effect, the oscilloscope is triggered by a pulse whose temporal position is associated with a differential front in a video signal, and a trigger pulse is generated by an analog circuit that monitors the temporal position of the video signal containing the switch 10, generator 11, device 12, multivibrator 13, which differentiates circuit 14, output stage 15.

The analog circuit works as follows.

The video signal from the output of the controllable anchor block is fed to an electronic switch that transmits a signal only in the signal interval of the window. From the switch output, the video signal goes to a threshold device that generates pulses, the temporal positie of which is rigidly connected with the front of the signal under study. Then, these pulses trigger a smooth delay multivibrator, performing a delay within

0.2-3.0 I, where I is the length of the string, which allows viewing any part of the video signal on the oscilloscope screen. Then the pulse from the output of the multivibrator 13 is differentiated by the circuit 14 and through the output

a cascade that forms a triangular pulse of negative polarity is applied to trigger a pending sweep of the oscilloscope.

Subject invention

A device for measuring the modulation characteristic of a kinescope containing a transmitting television camera with a coordinate device installed in front of the screen of the kinescope and connected in series to the output of the transmitting television camera with a gamma corrector, video amplifier and

oscilloscope; a synchronous generator, the output of which is simultaneously connected via a signal generator close to the control input of the electronic switch, to the inputs of a transmitting television camera, gamma equalizer, video amplifier and reference pulse generator, in order to measure the modulation characteristic of the kinescope when on the screen of a kinescope of background, luminous and temporal noise from an asynchronous network, an oscilloscope is connected to the output of the video amplifier through the control locking unit and the emitter follower, while ode unit controlled by affixing the electronic switch is connected via a threshold device to the output of which simultaneously connected serially connected delay multivibrator smooth, differentiating circuit and an output stage coupled to the input of the oscilloscope synchronization and series connected multi