SU907447A1 - Electron beam oscilloscope with automaic vertical dimension and position setting - Google Patents

Description

The invention relates to electrical engineering and can be used in the development of automatic oscillographic equipment.

Closest to the invention. · By technical essence is an electron beam oscilloscope with automatic installation of the vertical size and position of the image, containing an attenuator, the signal input of which is connected to the studied signal bus, controlling the input with the second output of the control unit, and the output with the first differential input of the vertical deviation amplifier the output of which is connected to vertically deflecting plates of the cathode ray tube, and the control input is to the first output of the control unit, the first second input of which is connected to the output of the decoder, and the second input - to the second output-voltage converter kodi first output.

² which is connected to the inputs of the decoder and digital indicator [11.

A disadvantage of the known device is the low accuracy of setting the vertical size and position of the image when studying pulsed signals with a large duty cycle>, as well as the complexity of its design.

The purpose of the invention is to increase the accuracy of the installation.

This goal is achieved in that an electron beam oscilloscope with automatic installation of the vertical size and position of the image, containing an attenuator, the signal input of which is connected to the bus of the signal under study, the control input with the second output of the control unit, and the output with the first differential input of the vertical deviation amplifier, output which is connected to vertically deflecting plates of the cathode ray tube, and the control input is connected to the first output of the control unit, the first input of which is connected to the output of the decoder, and the second input with the second output of the voltage-code converter, the first output of which is connected to the inputs of the decoder and digital indicator, equipped with detectors of maximum and minimum signals and a voltage divider, the output of which is connected to the second differential input of the vertical deviation amplifier, the first input to the first input of the voltage-code converter and to the output of the signal maximum detector, and the second input to the second input of the voltage-code converter and the output of the signal minimum detector, input to The latter is connected with the input of the signal maximum detector and the attenuator output.

The drawing shows a structural electrical diagram of the device.

The device consists of an attenuator 1, a vertical deviation amplifier 2, an electron beam tube 3, a signal maximum detector 4, a signal minimum detector 5, a voltage divider 6, a voltage-code converter 7, a digital indicator 8, a decoder 9, and a control unit 10.

The device operates as follows.

The studied signal is fed to the input of the attenuator 1, the transmission coefficient of which in the initial state is equal to unity. With a large amplitude of the signal, this causes a restriction mode in the maximum detector 4 or in the minimum detector 5, or in both detectors simultaneously.

The dynamic range of the input signals of the voltage-converter 7 is selected so that the limiting signals from the outputs of the detectors 4 and 5 lie outside it, as a result of which an overload signal appears on the second output of the voltage-code converter 7, which increases the attenuation coefficient by one step through the control unit 10 attenuator 1.

For convenience, when indicating the measured value of the signal amplitude, the attenuator attenuation coefficient 1 for two adjacent steps differs by a factor of 10. Also overlapping over the range of input signals

907447 4

They have detectors 4 and 5 and a voltage-to-code converter 7.

The adjustment cycles are repeated until the signal amplitude at the 5th output of the attenuator 1 is less than the limiting voltages of the detectors 4 and 5. In this case, a constant voltage is formed at the output of the detector 4, which coincides with the maximum, and 10 at the output of the detector 5 is a constant voltage, coinciding with the minimum signal.

The difference of the indicated constant voltages, equal to the amplitude of the variable 15 of the signal component, is converted in the converter 7 into a digital code, which is displayed by the digital indicator 8 taking into account the attenuation coefficient of attenuator 1 and determines the true value of the signal amplitude at the input of the oscilloscope.

At the same time, the digital code is decrypted by the decoder 9, which, through the control unit 10, sets the gain of the vertical deviation amplifier 2, which provides the optimal image size for viewing the signal on the screen of the cathode ray tube 3. 30 When controlling from block 10, the gain of the vertical deviation amplifier 2 can change 10 times smoothly or with a given discrete value.

The voltage divider 6, connected between the outputs of the detectors 4 and 5 of the maximum and minimum, has a division coefficient equal to two and ensures the formation of a constant voltage at its output equal to the sum of the minimum signal value and half of its variable component. The constant voltage generated in this way always coincides with the middle of the variable component of the signal, regardless of its shape and duty cycle, and arriving at the second differential input of the vertical deviation amplifier 2, it shifts the image to the center of the cathode ray tube screen, arranging the signal maximum and minimum points symmetrically with respect to the midline screen and provisioning the most optimal condition ⁵⁵ Wii for observation.

If the signal at the input of the oscilloscope decreases, a code corresponding to the reduced value of the variable component of the signal appears at the output of converter 7, as a result of which the decoder 9 through the control unit 10 will increase the gain of the vertical deviation amplifier 2, restoring the image size on the electron beam screen tube 3.

With a further reduction of the amplitude of the signal at the output of the attenuator to a predetermined control in block 10 the value at which the voltage converter 7 and a code vertical deflection amplifier 2 can no longer provide the desired experimental ^error, measurement NOSTA ⁵ and set the vertical picture size, the control unit 10 reduces attenuator 1 attenuation coefficient by one step, providing adjustment in the opposite direction, or establishes a unit attenuator gain of 1, starting a new cycle of direct p adjustments.

The device allows you to eliminate 25 image shift to the edge of the screen when studying signals with high duty cycle, which improves the accuracy of the installation of the vertical image size. thirty

Compensation of the DC component of the signal using the elements used in measuring the amplitude of the signal simplifies the device.

Claims (1)

The first output of the control unit, the first input of which is connected to the output of the decoder, and the second input to the second output of the voltage-code converter, the first output of which is connected to the inputs of the decoder and digital indicator, is equipped with a maximum and minimum signal detectors and a voltage divider output which is connected to the second differential input of the vertical deflection amplifier, the first input to the first input of the voltage-code converter and to the output of the maximum signal detector, and the second input to the second input of the transducer Atel voltage code output and the minimum signal detector having an input coupled to the input of maximum signal detector and the output attenuator. The drawing shows a structural electrical circuit of the device. The device consists of an attenuator 1, a vertical deflection amplifier 2, a cathode ray tube 3, a signal maximum detector 4, a signal minimum detector 5, a voltage divider 6, a voltage-code converter 7, a digital indicator 8, a decoder 9, and a control unit 10. The device works as follows. The signal under study is fed to the input of the attenuator 1, the transmission coefficient of which in the initial state is equal to one. With a large signal amplitude, this causes a mode of restrictions in the maximum detector k or in the detector 5 of the signal minimum, or in both detectors simultaneously. The dynamic range of the input voltage of the converter 7 voltage code is selected so that the limit signals from the outputs of the detectors 4 and 5 lie outside of it, with the result that at the second output of the voltage converter 7, an overload signal appears that The control increases by one step the attenuation coefficient of attenuator 1. For convenience, when displaying the measured value of the signal amplitude, the attenuation coefficient of attenuator 1 for two adjacent steps is 10 times different. Also, the overlap in the input signal range is provided by the detectors 4 and 5 and the voltage-code converter 7. The adjustment cycles are repeated until the signal amplitude at the output of attenuator 1 becomes less than the limiting voltages of the detectors 4 and 5. In this case, a constant voltage coincides with the maximum at the output of the detector k, and the constant at the output of the detector 5 This voltage is the same as the minimum signal. The difference of the indicated constant voltages, equal to the amplitude of the variable component of the signal, is converted in the converter 7 into a digital code, which is displayed by the digital indicator 8 taking into account the attenuation coefficient of the attenuator 1 and determines the true value of the amplitude of the signal at the oscilloscope. Simultaneously, the digital code is decrypted by the decoder 9, which, through the control unit 10, sets the gain factor of the vertical deviation amplifier 2, which provides the optimum for observation image size of the signal on the screen of the cathode ray tube 3. With the control from the unit 10, the gain of the vertical deviation amplifier 2 10 times smoothly or with a given discrete value. The voltage divider 6 connected between the outputs of the detectors k and S of the maximum and minimum has a division factor of two and ensures the formation of a constant voltage at its output equal to the sum of the minimum signal value and half of its variable component. The constant voltage generated in this way always coincides with the middle of the variable component of the signal regardless of its shape and duty cycle, and entering the second differential input of the vertical deflection amplifier 2, shifts the image to the center of the screen of the cathode ray tube symmetrically relative to center line of the screen and thus providing optimal conditions for observation. If the signal at the input of the oscilloscope is reduced, the output of the converter 7 is a code corresponding to the reduced variable component of the signal, with the result that the decoder 9 through the control unit 10 will increase the gain of the amplifier 2 vertical deflection, restoring the image size on the screen of the cathode ray tube 3 With a further decrease in the amplitude of the signal at the output of the attenuator to a certain value specified in the control unit 10, at which the converter 7 voltage-code and amplifier 2 vertical deflections can no longer provide a predetermined measurement error and set the vertical image size, control unit 10 reduces attenuation coefficient of attenuator 1 by one step, providing adjustment in the opposite direction, or sets the unit transfer ratio of attenuator 1, starting a new direct adjustment cycle. The device eliminates the displacement of the image to the edge of the screen when examining signals with a high duty cycle, which improves the accuracy of setting the vertical size of the image. Compensating the constant component of the signal with the elements used in measuring the amplitude of the signal simplifies the device. The invention of an electron-beam oscilloscope with automatic installation of a vertical E 6 size and position of the image, containing an attenuator, the signal input of which is connected to the bus of the studied signal, the control input of the second output of the control unit, and the output of the first differential input of the vertical deviation amplifier whose output is connected to the vertically deflecting plates of the electron-beam tube, and the control input to the first output of the control unit, the first input of which is connected to the output of the decipher torus, and the second input with the second output of the voltage-code converter, the first output of which is connected to the inputs of the decoder and the digital indicator, characterized in that; In order to improve the accuracy of the installation, it is equipped with maximum and minimum signal detectors and a voltage divider whose output is connected to the second differential input of the vertical deflection amplifier, the first input to the first input of the voltage-code converter and to the output detector of the signal maximum, and the second the input to the second voltage converter and the output of the minimum signal detector, whose input is connected to the input of the maximum signal detector and the output of the attenuator. Sources of information taken into account during the examination 1. USSR Author's Certificate tf i 36285, class C. 01 R 13/20, 1973 (prototype). / k k t t