SU932653A1 - Similator of chrominance signals of cameras with light filters - Google Patents

Description

I

The invention relates to television technology and can be used to control and adjust cameras with raster filters.

A simulator of chrominance signals of cameras with raster filters is known, comprising a lower subcarrier generator and an upper subcarrier generator, a blue signal modulator and a red color-separated image modulator and an adder, the first and second inputs of which are connected to the red and modulator signal blue color separations, and the output of the adder is the output of the simulator O 3

However, the known simulator of chrominance signals of cameras with raster filters has a small range of simulated chrominance signals, which limits its scope.

The purpose of the invention is to increase the range of simulated chroma signals.

To achieve this goal, the chrominance signal simulator of cameras with raster filters contains a lower subcarrier generator and a generator of upper subcarrier frequency, a blue signal modulator and a red color-separated image modulator and an adder, the first and second inputs of which are connected to the outputs respectively of the modulator the red signal and the modulator of the signal of the blue color-separated images, and the output of the adder is the output of the simulator, the modulator of the signal of the green color-separated image is entered razor, subcarrier switch, matrix generator, phase switch and three sawtooth voltage generators, each input is connected to the corresponding matrix input and is the input of the corresponding color stripe image, and the output of each sawtooth voltage generator is connected to a low frequency input of the corresponding modulator of the color separation signal, while the output of the subcarrier switch is connected to the high-frequency input of the modulator the green color separated image signal, the output of which is connected to the third input of the adder, the first and second inputs of the subcarrier switch of the frequencies are connected respectively to the first and second inputs of the phase switch, and the first and second generators of the lower and subcarrier respectively, and the second outputs of the phase switch are connected to the high-frequency inputs of the modulator of the red signal and the modulator of the blue color-separated image signal, respectively; the sync input the phase switch is the input of horizontal sync pulses, and the output of the matrix unit is connected to the fourth input of the adder.

The drawing shows a structural diagram of a simulator of chrominance signals of cameras with raster filters

The chrominance signal simulator of cameras with raster filters contains the upper subcarrier frequency generator 1, the lower subcarrier generator 2, the modulator 3 si | - red color-separated image, the adder} modulator 5 SI1-blue color-separated image, the modulator 6 of the green color-separated image signal , switch 7 subcarrier frequencies, block 8 matrixing, switch 9, the first 10, second 11 and third 12 generators sawtooth voltage.

Simulator signals chrominance cameras with raster filters works as follows.

The upper subcarrier generator generates a square wave with the frequency of the subcarrier frequency. This generator is tuned according to an autogenous circuit with capacitive feedback, the generator circuit being formed by a tunable inductance and an equivalent capacitance determined by three capacitances connected in series. The signal of the generator 1 is used to generate the signal of the upper subcarrier frequency in the modulator 5 of the signal of the blue color separation image in the frequency information color coding method.

Generator 2 constructed similarly to generator 1 is used to generate a signal of a lower subcarrier frequency fg in modulator 3 of a red color-separated image signal. For this, a square wave with a frequency of 3.5 MHz is generated by the generator. The low-frequency inputs of the modulators 3 and 5 receive signals of color-separated images of RGB color bands. In modulators 3 and 5 assembled in a balanced scheme, the signals fQ and fg are formed, which are added up in the adder t ,, whose output signal is used to simulate si (- camera frequency-coded information on the frequency method. However, this signal cannot be used to configure and verify the correctness of the setting of the decoders of all other cameras with raster filters.

To increase the range of simulated chrominance signals of cameras with raster filters of the RG and B signal, the color bands are applied to the inputs of the sawtooth voltage generators, respectively, 10.11 and 12 8 each generator, when a chrominance signal arrives on it, a sawtooth voltage is formed.

The use of a sawtooth low frequency signal eliminates the occurrence of amplitude-frequency distortions in the decoding path of the camera signal. At the high frequency, the modulator input of the green color separation image signal 6 is connected by the subcarrier switch 7, either the upper subcarrier frequency signal from generator 1, or the lower subcarrier signal from generator 2.

Claims (1)

Depending on the camera used, the following signals can be connected to the high-frequency input of the modulator with a 9-phase switch, a frequency method simulation signal, a three-signal vidicon and a trinicone, a signal simulating phase coding of red and blue color-separated images, and frequency-phase coding of red and green and blue color separation5. In the case of simulating the two-tube version of the camera, the signal to the high-frequency input of the modulator 3 is not supplied. The signal simulating the phase coding of the red, green, and blue color separation images. Depending on the camera used, the following signals of the 9-phase switch can be connected to the high-frequency input of the modulator 5, the simulation signal of the frequency encoding method and two-tube antenna, the simulation signal of the phase method with the coding of red and blue information and in the case of frequency-phase coding of the red , green and blue color components: signal of imitation of the phase method with coding of red, green and blue color information and signal of imitation of the signal of a three-signal vidicon and trinicone. The subcarrier signal, modulated in the modulator 5 by the signal from the output of the generator 12, is fed to the input of the adder k. In addition, the signals R, G and B are fed to the corresponding inputs of the block 8 of matrixing of the video signals, where they are added to the exact frames. Depending on the type of camera being simulated, such signals are sent to the low-frequency input of the adder k; the signal, in the case of imitation of the frequency method of coding the red and blue information, as well as in the case of the phase method of coding the red and blue color information, matched in accordance with the expression -B signal 1 1 in the case of the two-way variant, matched in accordance with the expression Q + R4 -lg) -. a signal, in the case of frequency-phase coding of red, green and blue information, and in the case of phase coding of red, green and blue information and a signal, in the case of simulating a signal of a three-signal vidicon and trinicone. At the output of the adder 4, a signal is generated simulating the chroma signal of any camera with raster filters. 3 The range of simulated chroma signals in the proposed simulator is much larger than that of the known. which expands the area of its application and improves the quality of control and adjustment of television cameras with raster filters. BACKGROUND OF THE INVENTION A chrominance signal simulator of cameras with raster filters, comprising a lower subcarrier generator and an upper subcarrier generator, a blue signal modulator and a red color-separated image modulator, and an adder, the first and second inputs of which are connected to the red and modulator signals respectively the color separated image signal torus, and the adder output is a simulator output, characterized in that, in order to increase the range of simulated color signals For example, a green color separated image modulator, a subcarrier frequency switch, a matrix unit, a phase switch and three sawtooth voltage generators, each input of which is connected to the corresponding matrix unit input and input of the corresponding color bars image of the color bars, are entered into and the output of each of the sawtooth voltage generators is connected to the low-frequency input of the corresponding modulator of the color-separation image signal, while the output of the switch Frequency subcarriers are connected to the high-frequency input of the modulator of the green color-separated image signal, the output of which is connected to the third input of the adder, the first and second inputs of the subcarrier switch are connected to the first and second inputs of the phase switch, as well as to the output of the lower subcarrier frequency generator and the generator output the upper subcarrier frequency, respectively, the first and second outputs of the phase switch are connected to high frequency ones. inputs, respectively, of the modulator of the red signal and the modulator of the blue color-separated image signal, the synchronization input