RU209707U1 - Computing interface device - Google Patents

Abstract

The utility model relates to computer technology. The technical result is to expand the functionality that allows the use of the claimed solution in lighting control modules. The computing interface device contains a microprocessor, the first and second power supplies, the first and second input-output interfaces, the communication module connection unit, the first and second terminals of which are connected, respectively, with the first and second terminals of the first input-output interface, the power supply with support Ethernet, interference and surge protection unit, bus for interaction with functional modules and external memory connection unit with appropriate connections. 1 ill.

Description

The utility model relates to specialized computing devices and can be used in automated control systems as a computing device embedded in technological equipment, for example, in base stations for controlling lighting in large areas of cities for local primary data processing from connected external devices - image processing and recognition from video cameras, processing of acoustic signals from built-in microphones, etc.

Known processor [RU 76757, U1, H03G 5/14, 09/27/2008], containing a high-pass filter, a low-pass filter, a buffer stage, the first, second and third attenuators, as well as an adder, the output of which is associated with the output of the sound processor, when In this case, the first input of the adder is connected to the output of the first attenuator, the second input of the adder is connected to the output of the second attenuator, the input of which is connected to the output of the low-pass filter, the third input of the adder is connected to the output of the third attenuator, the input of which is connected to the output of the high-pass filter, the inputs of the first attenuator , the low-pass filter and the high-pass filter are connected to the output of the buffer stage, the input of which is the input of the sound processor, the buffer stage, filters, moreover, the attenuators and the adder are analog, the frequency settings of the low-pass filter, the high-pass filter, as well as the values of the transmission coefficients of the first , the second and third attenuators are chosen such that the amplitude-frequency characteristic of the sound cessor, reduced to 0 dB at a frequency of 1 kHz, in the frequency range of 80 Hz-25 kHz fits into the corridor, the upper boundary of which is a broken line connecting points with coordinates (80 Hz; +9 dB), (170 Hz; +9 dB), (600 Hz; +2 dB), (3.5 kHz; +2 dB), (25 kHz; +7 dB), and the lower boundary of the corridor is a broken line, connecting points with coordinates (80 Hz; +2 dB), (170 Hz; -3 dB), (6 kHz; -3 dB), (25 kHz; +0.5 dB), while the specified frequency response has a sustained rise of 1-6 dB/octave towards low frequencies up to 80 Hz with the beginning of said steady rise in the frequency range from 1 kHz to 100 Hz, as well as a steady rise of 1.5-2 dB/octave towards high frequencies up to frequency of 25 kHz with the beginning of the specified steady rise in the frequency range from 2.5 kHz to 6 kHz. This result is also achieved by the fact that the adder is made on an operational amplifier according to the inverting adder circuit, and frequency-independent resistors installed in series in each of the input circuits of the adder and a resistor installed in the negative feedback circuit of the operational amplifier are used as attenuators. This result is also achieved by the fact that the adder and the buffer stage are made inverting.

The disadvantage of this device is a relatively limited scope, which does not allow its use in lighting control systems.

It is also known a device [RU 2645750, C1, H02N 7/00, 03/27/2017], containing a housing in which a processor module united by a common data bus is installed, containing one or more processors that perform the main computational processing, and a real-time clock module, a block memory containing ROM and RAM, communication interfaces configured to communicate with external computing devices, relay protective automation (RPA) modules connected to the processor module and including measuring modules, consisting of an analog input module and a discrete input module, a relay module , which was a discrete output module, and a combined discrete input/output module, a power supply unit designed to maintain the device’s operability in the event of a loss of operational power, and the analog input module contains an ADC designed to convert incoming analog signals, contains galvanically isolated input channels and serves as for out measuring currents and voltages in three phases and zero sequence; possibility of remote control of the MPD.

The disadvantage of the devices is relatively high complexity and relatively narrow functionality.

Closest to the proposed one is a computing interface device [RU 101225, U1, G06F 15/00, 01/10/2011], containing a microprocessor, two synchronous dynamic RAM, two switches, boot ROM, user program and data ROM, two PCI Express bridges - PCI, Ethernet transceivers, two USB bus controllers, removable storage controller, multi-protocol transceivers, real time clock, temperature sensor, serial EEPROMs, microcontroller, power voltage supervisor, operating hours timer, secondary power supply sources, first and second PMC/ XMS, clock series generators, control unit, moreover, the microprocessor is connected via the PCI Express interface to the first switch and the second PCI Express - PCI bridge, via the Local BUS interface - to the control unit, boot ROM, user program and data ROM, the first USB bus controller , via DDR2bus interfaces - with the first and second RAM, via GMI interfaces I - with Ethernet transceivers, the inputs-outputs of which are connected to the first inputs-outputs of an additionally introduced system-wide connector, the second inputs-outputs of which are connected through the first I2C interface to the inputs-outputs of the microcontroller, temperature sensor, supply voltage supervisor, with serial EPROMs, with microprocessor, the inputs-outputs of which are connected through the second I2C interface to the inputs-outputs of the operating timer and the real time clock, and the group of inputs-outputs from the third to the sixth system-wide connector is connected respectively to the group of inputs-outputs from the first to the fourth of the second switch, the fifth inputs - the outputs of which are connected via the Serial RapidIO interface to a microprocessor that has additional inputs/outputs for the JTAG interface, inputs/outputs UART0, UART1 for connecting to multiprotocol transceivers and an input for connecting to the first output of clock series generators, the outputs of which from the second to the thirteenth are connected Responsibly with the inputs of the second switch, the first PCI Express - PCI bridge, RMC / XMC modules, the second PCI Express - PCI bridge, the first switch, I / O device, microcontroller, Ethernet transceivers, USB bus controllers and a removable storage controller, inputs - the outputs of which are connected through the second PCI 2 interface to the inputs and outputs of the second USB bus controller, the second PCI Express - PCI bridge and to the third inputs and outputs of the second PMC / XMC module, the first, second and fourth inputs and outputs of which are connected respectively to the second inputs - outputs of the first switch, with the ninth and seventh inputs-outputs of the system-wide connector, the eighth and tenth inputs-outputs of which are connected respectively to the fourth and second inputs-outputs of the first PMC/XMS module, the first and third inputs-outputs of which are connected respectively to the first inputs-outputs the first switch and through the first PCI 1 interface - with the first I/Os of the first PCI Express bridge - PCI, the second inputs-outputs of which are connected to the third inputs-outputs of the first switch, and the input of the control unit is the first input of the system-wide connector, the input of secondary voltage sources is the second input of the system-wide connector, the first and second outputs of the control unit are, respectively, the output of the system-wide connector and the output control unit through the interface of one-time commands, the output of the controller of the removable storage device forms an output through the IDE/CompactFlash interface, and Ethernet transceivers and multiprotocol transceivers have additional inputs and outputs via two Ethernet and RS-232/422/485 interfaces, respectively, the first bus controller USB has additional inputs/outputs via interfaces, two USB host channels and one USB OTG channel.

The disadvantage of the devices is the relatively high complexity and relatively narrow functionality, due to the fact that it does not allow using it in lighting control base stations without additional modifications. This narrows the arsenal of technical means that can be used to control lighting, in particular, to perform specific computing functions.

The objective of the utility model is to create a computing interface device with functionality that allows it to be used in lighting control modules.

The required technical result consists in expanding the functionality and expanding on this basis the arsenal of technical means that can be used for lighting control devices, in particular, to perform specific computing functions.

The task is solved, and the required technical result is achieved by the fact that, according to the utility model, the device containing the microprocessor, the first and second power supplies, as well as the first and second input-output interfaces, has a communication module connection unit, the first and second terminals of which connected, respectively, to the first and second terminals of the first input-output interface, the third and fourth terminals of which are connected, respectively, to the first and second terminals of the microprocessor, the third terminal of which is connected to the connection terminal of the second input-output interface, an Ethernet-enabled power supply, the first terminal of which is connected to the fourth terminal of the microprocessor, the noise and surge protection unit, the bus for interaction with functional modules, the first and second terminals of which are connected to the fifth and sixth terminals of the microprocessor, respectively, the external memory connection unit, the first and second terminals of which are connected, respectively, with the seventh and eighth terminals microprocessor, moreover, the first terminal of the noise and surge protection unit is connected to the third terminal of the bus for interaction with functional modules, the second terminal is connected to the first terminals of the first and second power supplies and to the second terminal of the Ethernet-enabled power supply, and the third terminal is connected to the second terminals of the first and second power supplies and with the third terminal of the power supply with Ethernet support, while the ninth, tenth, eleventh, twelfth and thirteenth terminals of the microprocessor are connected, respectively, to the fourth, fifth, sixth and seventh terminals of the communication module connection unit.

The drawing shows a functional diagram of the computing interface device.

The computing-interface device contains a microprocessor 1 made on a 1892VM14Ya chip with the ability to install and use the Linux operating system and includes a DDR SDRAM and eMMC memory subsystem, as well as the first 2 and second 3 power supplies and the first 4 and second 5 input-output interfaces.

The device also contains a block 6 for connecting a communication module, the first and second terminals of which are connected, respectively, with the first and second terminals of the first input-output interface 4, the third and fourth terminals of which are connected, respectively, with the first and second terminals of the microprocessor 1, the third terminal of which connected to the connection terminal of the second I/O interface 5.

In addition, the device contains a power supply 7 with Ethernet support, the first terminal of which is connected to the fourth terminal of the microprocessor 1, block 8 protection against interference and overvoltage, bus 9 interaction with functional modules, the first and second terminals of which are connected, respectively, to the fifth and sixth microprocessor terminals 1.

In addition to the above, the device contains an external memory connection block 10, the first and second terminals of which are connected, respectively, to the seventh and eighth terminals of the microprocessor 1, and the first terminal of the block 8 of protection against interference and overvoltage is connected to the third terminal of the bus 9 for interaction with functional modules, the second terminal is connected to the first terminals of the first 2 and second 3 power supplies and to the second terminal of the power supply 7 with Ethernet support, and the third terminal is connected to the second terminals of the first 2 and second 3 power supplies and to the third terminal of the power supply 7 with Ethernet support, with In this case, the ninth, tenth, eleventh, twelfth and thirteenth terminals of the microprocessor 1 are connected, respectively, to the fourth, fifth, sixth and seventh terminals of the block 6 for connecting communication modules.

Works computing-interface device as follows.

The device is designed to control technological equipment, automation and data transmission facilities, mainly in base lighting control stations in large areas of cities, and processes information about the status of controlled devices, sensors, transceiver equipment, including local primary data processing from connected external devices (processing and recognition images from video cameras, processing of acoustic signals from built-in microphones, etc.).

Based on the requirements for the functions performed by the device, the device provides algorithmic support for the functions of a modular controller, the ability, if necessary, to switch between different channels for transmitting commands / data, the ability to store and archive data, ensure the functioning of information protection tools from unauthorized access, transfer diagnostic and other information status of subsystems and connected equipment.

The device is made on the domestic element base and has a modular design.

Thus, the device achieves the required technical result, which consists in expanding the functionality and expanding on this basis the arsenal of technical means that can be used for lighting control devices in large areas of cities, in particular, to perform specific computing and control functions.

Claims (1)

Computing-interface device containing a microprocessor, the first and second power supplies, as well as the first and second input-output interfaces, characterized in that a communication module connection unit is introduced, the first and second terminals of which are connected, respectively, to the first and second terminals of the first interface I/O, the third and fourth terminals of which are connected to the first and second terminals of the microprocessor, respectively, the third terminal of which is connected to the connection terminal of the second I/O interface, an Ethernet-enabled power supply, the first terminal of which is connected to the fourth terminal of the microprocessor, the protection unit from interference and overvoltage, a bus for interaction with functional modules, the first and second terminals of which are connected, respectively, to the fifth and sixth terminals of the microprocessor, an external memory connection unit, the first and second terminals of which are connected, respectively, to the seventh and eighth terminals of the microprocessor, and the first anti-jamming block terminal overvoltage is connected to the third terminal of the communication bus with functional modules, the second terminal is connected to the first terminals of the first and second power supplies and to the second terminal of the power supply with Ethernet support, and the third terminal is connected to the second terminals of the first and second power supplies and to the third terminal of the power supply with Ethernet support, while the ninth, tenth, eleventh, twelfth and thirteenth terminals of the microprocessor are connected, respectively, to the fourth, fifth, sixth and seventh terminals of the communication module connection block.

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