SU879821A1 - Device fr measuring scanning non-linearity of cathode -ray tube - Google Patents

Description

(.54) DEVICE FOR MEASURING NONLINEARITY

Claims (1)

The invention relates to radio engineering and can be used when measuring the parameters of the beam sweep in cathode-ray tubes / CRT). A device for measuring the non-linearity of a CRT scanner containing a bar on which is installed an equal distance from each other is known. photoconverters and oscilloscope, sig. The input of which is connected to the outputs of the photovoltaic converters, the bar being located in front of the screen of the electronic transducer. However, the known device has a low measurement accuracy. The purpose of the invention is to increase the measurement accuracy. To do this, a device for measuring the nonlinearity of a CRT scanner, containing a bar on which a series of photovoltaic devices are installed at an equal distance from each other, and an oscilloscope whose signal input is connected to the outputs of photoconverters, the bar is located in front of the CRT screen, the first trigger and a differentiating unit, the output of which is connected to the synchronization input of the oscilloscope, as well as a series-connected pulse frequency divider and a second trigger, whose output is under The key is connected to the second key input and the pulse frequency divider is connected to the first trigger input and converter outputs, the second trigger output is connected to the third key input. The block diagram of the proposed device. The device for measuring non-linearity of the CRT scanner contains a bar 1 located in front of the screen 2, on which photoconverters 3 are installed, differentiating unit 4, d-pulse 5 pulse frequency, first trigger 6, key 7 second trigger 8, signal-count 9 3 The device works as follows. The pulses with the output of the photovoltaic cells 3 are fed to the input of the first trigger 6, as a result of which symmetric signals are formed at its outputs. Let the initial state of the second trigger 8 provide the control voltage to the Key 7, in which the differentiating block 4 of the output voltage of the first trigger 6 passes. After the differentiation, we obtain pulses at the synchronization input of the oscilloscope 9. corresponding to the first, third, and fifth volume. (ie, odd) input pulses. The duration of the oscilloscope sweep selects with such a way that on its screen the second, fourth and sixth (i.e., even-numbered pulses are reproduced on each screen). They will be located at certain distances from the beginning of the sweep. the pulses from the outputs of the photovoltaic converter are input to the input of the first trigger by a divider 5 pulse frequency with a division ratio equal to the number of working photoconverters. With the arrival of the pulse, the second trigger 8 transfers a new state than both Switching key 7 is sintered, and pulses from the second arm of the first trigger start to enter the differentiating unit.After differentiation, we get oscilloscope trigger pulses corresponding to even input pulses. As a result, the third and fifth will reproduce on the oscilloscope screen (i.e. a) pulses. They will be spaced from the start of the sweep to a certain distance. Thus, over the two periods of the controlled sweep on. All time intervals between pulses from neighboring photoconverters will be reproduced on the oscilloscope screen. The largest and smallest interval is characterized by the non-linearity of the sweep which can be calculated by direct measurement results for 14 times the largest and smallest distances on the oscilloscope screen or by using the time marks of the horizontal axis of the oscilloscope. reproduced over the entire working length of the horizontal scan of the oscilloscope (then, as in the prototype, it is equal to this length, divided This makes it possible to significantly improve the accuracy of non-linearity measurement, both due to the fact that large distances can be measured with greater accuracy, and due to the fact that the error due to the nonlinearity of the oscilloscope sweep is reduced. A CRT tube containing a bar, on which an equal distance from each other is placed, is a series of transducers and an oscilloscope, the signal: the input of which is connected to the outputs of a photoconverter In this case, the bar is located in front of the CRT screen, characterized in that, in order to increase the measurement accuracy, the first trigger, a key and a differentiation unit, the output of which is connected to the oscilloscope synchronization input, as well as the successively connected pulse frequency divider and the second trigger, are introduced , the output of which is connected to the second key input, and the input of the pulse frequency divider is connected to the input of the first trigger and the outputs of the photovoltaic converters, and the second output of the first trigger is connected to the third input key. Sources of information taken into account during the examination 1. Japan patent No. 53-11165, cl. H 04 M 7/02, published, 1978 (prototype