RU2342737C2 - Secondary switched power supply for image converter - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is attributed to the field of electric engineering. Essence of invention: secondary switched power supply comprises: voltage converter, microcontroller, two digital-analog converters, analog-digital converter, automatic brightness adjustment amplifier, key unit, voltage multipliers, interface. The device performs automatic adjustment of amplifiers output voltages depending on ambient temperature with simultaneous control of automatic brightness adjustment current and alteration of photocathode voltage generation mode depending on brightness level on the photocathode.

EFFECT: extension of electron-optical converter illumination dynamic range, control signals generation without using external circuits, decrease in device overall dimensions.

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Description

The proposed device relates to the field of electrical engineering and can be used in combination with other devices to obtain the necessary high-voltage voltages, ensuring the operability of the electron-optical converter (EOC) in a wide range of illumination.

AHV power supply devices NV-2 and NV-3 are known from the company "AHV", containing a sinusoidal signal generator, voltage multipliers, an automatic brightness control circuit (Advertising information about the NV series devices, listed on the website www.ahv.com., By "AHV" , 2005. Appendix 1). The disadvantages of these devices - the need to use an external signal to control the power supply, as well as the large size - do not allow their use in portable portable equipment.

Closest to the claimed technical solution is a secondary power source for an electron-optical converter, comprising a voltage converter, a microcontroller, an analog-to-digital converter, first and second digital-to-analog converters, an automatic brightness control amplifier, a microchannel plate voltage multiplier, a screen voltage multiplier, while the input the voltage converter is connected to the input bus, the first output of the voltage converter is connected to the first input of the micro the controller, with the first input of the analog-to-digital converter, with the first input of the amplifier for automatic brightness control, with the first input of the first digital-to-analog converter, with the first input of the second digital-to-analog converter, the second output of the microcontroller is connected to the second input of the first digital-to-analog converter, the third output of the microcontroller is connected to the second input the second digital-to-analog converter, the output of the first digital-to-analog converter is connected to the second input of the second digital-to-analog of the second converter, the output of the analog-to-digital converter is connected to the second input of the microcontroller, the second input of the analog-to-digital converter is connected to the output of the automatic brightness control amplifier, the output of the screen voltage multiplier is connected to the second input of the automatic brightness control amplifier (RF patent for utility model No. 45362 dated 19.01 .2005).

The disadvantages of the closest technical solution are the low level of adjustment of the dynamic range of illumination of the electron-optical converter, the need to use external circuits to expand the dynamic range and generate control signals, which leads to an increase in the dimensions of the device.

The objective of the invention is to increase the dynamic range of illumination of the electron-optical converter, the formation of control signals without the use of external circuits, reducing the size of the device.

The problem is solved in that in a device containing a voltage converter, a microcontroller, an analog-to-digital converter, first and second digital-to-analog converters, an automatic brightness adjustment amplifier, a microchannel plate voltage multiplier, a screen voltage multiplier, while the input of the voltage converter is connected to the input bus, the first output of the voltage converter is connected to the first input of the microcontroller, with the first input of the analog-to-digital converter, with the first input of the amplifier an amplifier for automatic brightness control, with the first input of the first digital-to-analog converter, with the first input of the second digital-to-analog converter, the second output of the microcontroller is connected to the second input of the first digital-to-analog converter, the third output of the microcontroller is connected to the second input of the second digital-to-analog converter, the third input of the microcontroller is connected to the serial data bus, the output of the first digital-to-analog converter is connected to the second input of the second digital-to-analog converter The output of the analog-to-digital converter is connected to the second input of the microcontroller, the second input of the analog-to-digital converter is connected to the output of the automatic brightness control amplifier, the output of the screen voltage multiplier is connected to the second input of the automatic brightness control amplifier, a microchannel plate voltage amplifier, a screen voltage amplifier, photocathode voltage amplifier, key unit, interface, while the first output of the voltage converter is connected to the first inputs of the int of the interface, voltage amplifier of the microchannel plate, voltage amplifier of the photocathode, voltage amplifier of the screen, the second output of the voltage converter is connected to the second input of the interface, the third output of the voltage converter is connected to the first input of the key unit, the first output of the microcontroller is connected to the third input of the interface, the first output of the interface is connected to the second input of the key block, the second output of the photocathode voltage amplifier is connected to the third input of the key block, the second output of the voltage amplifier m the crochannel plate is connected to the input of the voltage multiplier of the microchannel plate, the second output of the voltage amplifier of the screen is connected to the input of the voltage multiplier of the screen, the first outputs of the voltage amplifier of the microchannel, the voltage amplifier of the voltage amplifier of the photocathode are connected respectively to the third, fourth and fifth inputs of the analog-to-digital converter, the second inputs of the microchannel plate voltage amplifier, screen voltage amplifier, photocathode voltage amplifier are connected respectively With the first, second, and third outputs of the second digital-to-analog converter, the second output of the microchannel plate voltage amplifier is connected to the first input of the microchannel plate voltage multiplier, the second output of the screen voltage amplifier is connected to the first input of the screen voltage multiplier, and the output of the microchannel plate voltage multiplier, the second output of the multiplier voltage of the screen, the output of the key block are the outputs of the secondary switching power supply.

When the luminous flux changes at the photocathode of the electron-optical converter according to the linear law, the microblock stabilizes the screen current, and a signal proportional to the screen current goes to the automatic brightness control amplifier, and from the automatic brightness control amplifier to the analog-to-digital converter of the microcontroller. The code of the analog-to-digital converter is used by the microcontroller to change the voltage on the microchannel plate in order to stabilize the brightness of the screen of the electron-optical converter - this is the so-called passive mode of operation of the electron-optical converter. When a certain illumination is reached at the photocathode, the microcontroller begins to generate pulses of various durations using the feedback voltage of the microchannel plate. These pulses then enter the key unit, which changes the duration of the high voltage voltage pulses at the photocathode of the electron-optical converter, stabilizing the screen current. This is how the photocathode is protected at increased light flux, as well as the expansion of the dynamic range of the electron-optical converter without the use of external circuits. Device control, parameter change, programming is carried out through a serial data bus.

The applicants have not identified technical solutions having features that match the distinctive features of the invention. A secondary switching power supply with the claimed combination of essential features is also not found in known sources of information.

Figure 1 presents the structural block diagram of the proposed secondary switching power supply, figure 2 - algorithm of the device.

The secondary switching power supply contains: voltage converter 1, microcontroller (MK) 2, analog-to-digital converter (ADC) 3, first and second digital-to-analog converters (DAC) 4 and 5, voltage amplifier microchannel plate (MKP) 6, voltage amplifier screen 7, the voltage amplifier block of the key 8, the amplifier automatic brightness control (ARA) 9, the interface 10, the voltage multipliers of the microchannel plate 11 and the screen 12, the block of the key 13 (figure 1).

Voltage converter 1 generates a constant voltage U ₁ for powering the microcontroller 2, ADC 3, DACs 4 and 5, voltage amplifiers 6, 7 and 8, as well as voltage 5 V for powering the interface 10 and voltage U ₃ for powering the key 13. The microcontroller is designed to control the operating conditions of the secondary switching power supply and adjust output voltages depending on external factors. DACs 4 and 5 set the operation mode for voltage amplifiers 6, 7, and 8. The key unit 13 serves to form pulses on the photocathode. The voltage amplifiers 6, 7 and 8 are designed to generate sinusoidal voltages, which are then fed to the voltage multipliers 11 and 12 and to the key block 13.

Voltage multipliers, in turn, form high constant voltage Umkp and Uekr. The key block 13 generates a pulse voltage on the photocathode, depending on the algorithms of operation of the microcontroller 2.

The secondary power source for the image intensifier tube is as follows. The supply voltage U _pit is supplied to the voltage converter 1, where voltages U ₁ , U ₂ , U ₃ are generated. Voltage U _{1 is} supplied to microcontroller 2, ADC 3, DAC 4 and 5, voltage amplifiers 6, 7 and 8, amplifier ARYA 9, interface 10. Microcontroller 2, depending on the ambient temperature and the set initial values, issues a control to DAC 4 the code. DAC 4 generates a sinusoidal control signal, which, in turn, is fed to DAC 5. DAC 5, depending on the code received from the microcontroller, generates three sinusoidal signals, the amplitude of which depends on air temperature, feedback signals and required voltages at the output of a secondary switching power supply. Further, these signals are fed to voltage amplifiers 6, 7 and 8, voltages U _c are formed on them, depending on what parameters are set by the microcontroller. The feedback signals from the voltage amplifiers are fed to the ADC 3, and then to the microcontroller 2, which in this way can monitor the output voltage of the secondary switching power supply. The output voltages from the voltage amplifiers are supplied to the voltage multipliers 11 and 12, the key unit 13. The output voltages Uekr, Umkp, Ufk are regulated in accordance with the feedback signals that come from the voltage amplifiers to the input of the ADC 3, and depending on the ambient temperature and current ARYA, which comes from the amplifier ARYA. When the screen current increases to the threshold, the microcontroller transfers the operation mode of the key unit from constant to pulsed, and a pulse voltage is generated at the output of Ufk.

Explanatory diagrams of the output voltages of the microblock are shown in Fig.2. The abscissa axes of the graphs indicate the time. On the first graph, the ordinate axis shows the illumination in lux. The second graph shows the screen current along the ordinate axis. On the third graph, the ordinate indicates the voltage on the MCP. The fourth graph shows the voltage on the photocathode along the ordinate axis. When the luminous flux at the photocathode of the image intensifier tube is changed from 10 ^-4 to 10 ⁴ lux according to the linear law, the microblock stabilizes the screen current (20 ÷ 70 nA), while a signal proportional to the screen current is fed to the ARYA amplifier 9, and from the ARYA amplifier 9 to the ADC 3 microcontrollers 2. The ADC 3 code is used by microcontroller 2 to change the voltage on the MCP in order to stabilize the brightness of the screen of the image intensifier tube - this is the so-called passive mode of operation of the image intensifier tube. When a certain illumination is reached at the photocathode (usually 0.5 ÷ 0.8 lux), the microcontroller begins to generate pulses of different durations using the feedback voltage of the MCP. These pulses are then fed to a key device that changes the duration of the high voltage voltage pulses on the photocathode of the image intensifier tube, stabilizing the screen current. This is how the photocathode is protected at an increased intensity of the light flux, as well as the expansion of the dynamic range of the image intensifier tube.

The positive effect of the proposed technical solution lies in the fact that the device, which has small dimensions and weight, allows you to automatically adjust the output voltages of the multipliers depending on the ambient temperature, perform digital adjustment of the voltage levels of the MCP, the screen and current of the ARIA via the data bus and reduce the response time ARIA. With the introduction of the pulse mode of operation, the range of illumination increases, at which the performance of the image intensifier tube is maintained.

Claims (1)

A secondary switching power supply comprising a voltage converter, a microcontroller, an analog-to-digital converter, a first and second digital-to-analog converters, an automatic brightness control amplifier, a microchannel plate voltage multiplier, a screen voltage multiplier, wherein the voltage converter input is connected to the input bus, the first output of the voltage converter connected to the first input of the microcontroller, with the first input of the analog-to-digital converter, with the first input of the amplifier dimming control, with the first input of the first digital-to-analog converter, with the first input of the second digital-to-analog converter, the second output of the microcontroller is connected to the second input of the first digital-to-analog converter, the third output of the microcontroller is connected to the second input of the second digital-to-analog converter, the output of the first digital-to-analog converter is connected to the second input of the second digital-to-analog converter, the output of the analog-to-digital converter is connected to the second microc input on the controller, the third input of the microcontroller is connected to the serial data bus, the second input of the analog-to-digital converter is connected to the output of the automatic brightness control amplifier, the output of the screen voltage multiplier is connected to the second input of the automatic brightness control amplifier, characterized in that the voltage amplifier of the microchannel plate is inserted into it, screen voltage amplifier, photocathode voltage amplifier, key unit, interface, while the first output of the voltage converter is connected to inputs of the interface, microchannel plate voltage amplifier, photocathode voltage amplifier, screen voltage amplifier, the second output of the voltage converter is connected to the second input of the interface, the third output of the voltage converter is connected to the first input of the key unit, the first output of the microcontroller is connected to the third input of the interface, the first output of the interface connected to the second input of the key block, the second output of the photocathode voltage amplifier connected to the third input of the key block, the second output will amplify For microchannel plate voltages, it is connected to the input of the microchannel plate voltage multiplier, the second output of the screen voltage amplifier is connected to the input of the screen voltage multiplier, the first outputs of the microchannel plate voltage amplifier, screen voltage amplifier, photocathode voltage amplifier are connected to the third, fourth, and fifth analog-to-digital inputs respectively converter, the second inputs of the microchannel plate voltage amplifier, screen voltage amplifier, photocathode voltage amplifier with are connected with the first, second, and third outputs of the second digital-to-analog converter, the second output of the microchannel plate voltage amplifier is connected to the first input of the microchannel plate voltage multiplier, the second output of the screen voltage amplifier is connected to the first input of the screen voltage multiplier, and the output of the microchannel plate multiplier, second output voltage screen multiplier, the output of the key block are the outputs of the secondary switching power supply.

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