RU2613529C2 - Device for controlling light-emitting crystals in led - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to devices for controlling light-emitting crystals in light-emitting diodes of electronic devices, matrix screens and other visual data display means. Substance of invention consists in that device comprises light-emitting crystals, a comparator module, a counter, pulse generator, register, a decoder, wherein output of register is connected to input of a memory module, output of pulse generator is connected to input of memory module, output of memory module is connected to input of decoder, output of which is connected to input of memory module. Invention provides branching of part of current flowing through light-emitting crystal, proportional to coefficient in memory cell, which provides adjustment of brightness of light-emitting crystal.

EFFECT: simplified circuit for controlling light-emitting crystals in a two-component LED, which leads to unloading of control electronics.

1 cl, 1 dwg

Description

The invention relates to the field of information technology and can be used in any consumer electronic devices, as well as in the construction of large-sized matrix screens and other means of displaying visual data.

A device is known for controlling the radiation of crystals in an LED (CN 103052211 A from 11.29.2012) containing light-emitting crystals, an I2C bus controller, and LED drivers.

A device is known as described in patent CN 103702494 from 01/09/2014. It comprises: a transmit signal voltage detecting unit, a serial data conversion module, a latch, and an address comparing device connected in series. Three latch control lines control three MOS transistors, each of which is connected to a respective light emitting crystal. The transmit signal voltage detection unit consists of two operational amplifiers that are simultaneously connected to a power source, the reference voltage of the first amplifier being 2 V and the reference voltage of the second 5 V. The result of the comparison from the output of two operational amplifiers is fed to the input of the serial data conversion module, where the serial data is converted to parallel. Parallel data is stored in the latch register and compared by the address comparison device, MOS transistors are controlled in accordance with the result of the comparison, thereby controlling each LED.

Known technical solutions have the following disadvantages: The device described in the patent (CN 103052211 A dated 11.29.2012) requires the use of a separate power supply for the digital circuit of the device, the implementation of control via the I2C bus requires a relatively high performance control computer with a low data transfer speed on the bus, has a large number of contact pads of the case.

The device described in the patent (CN 103702494 from 01/09/2014) has the following disadvantages: due to the fact that for the operation of the data receiving circuit it is necessary to use a code sequence generator with 2 voltages: 2 and 5 volts, the scope of the diode is very limited due to lack of voltages above 4 volts in all modern mobile devices powered by batteries. Using a voltage shaper of 5 volts negates the effect of using the specified diode. The construction of information display systems on these diodes is impossible due to the fact that the data loading mode is possible only when the supply voltage goes beyond the operating range, which will lead to the destruction of image integrity during data loading in any of the diodes included together, and at the specified time downloads, the amount of data transferred and the period of their updating, the time for displaying information is commensurate with the data loading time, which makes the use of this diode impossible in this area. Also, the use of an internal generator with a stability of 5% and the inability to programmatically take into account the frequency drift will give a 10% different brightness of adjacent diodes, which is acceptable only for garlands and lighting effect systems. A significant drawback of all the described solutions is that in order to obtain the same brightness of the glow of several crystals, a constant correction of the level of the output signal from the control controller is required, which significantly increases the complexity of the control electronics and affects its cost.

The objective of the invention is to create a new device for controlling light-emitting crystals in a two-contact LED, eliminating the above disadvantages of known technical solutions.

The technical result is the lack of calculations associated with the correction of the brightness level of individual LEDs, which leads to the unloading of the control electronics, as well as a significant simplification of the complexity of printed circuit boards by reducing the number of connections by 2 or more times and simplifying the control circuit.

The task with the specified technical result is achieved by a new set of essential features necessary and sufficient to achieve the specified technical result. The essence of the invention lies in the fact that the device for controlling light-emitting crystals in the LED contains a comparator module, a counter, a register, a decoder, a pulse shaper, a memory module, a voltage generation module, a digital-to-analog converter, a comparison and amplification module, two amplifiers, two resistors , transistors, light-emitting crystals, while the input of the comparator module is connected to the terminal of the anode, and the output is connected to the input of the counter and the input of the pulse shaper, the output of the counter is connected to the input of the register, the output of the register is connected to the input of the decoder, the output of the decoder is connected to the bases of transistors, the collectors of which are connected to the cathodes of light-emitting crystals, the anodes of which are connected to each other and connected to the terminal of the anode, and the emitters of the transistors are connected to each other and connected to the input of the first amplifier and to one the resistor contact, another resistor contact is connected to the cathode terminal, the output of the first amplifier is connected to the input of the comparison and gain module, the output of the comparison and gain module is connected to the base of the transistor, whose lecturer is connected to the terminal of the anode, and the emitter is connected to the input of the second amplifier, the output of the second amplifier is connected to the input of the comparison and amplification module, the input of the second amplifier is connected to one contact of the resistor, the second contact of the resistor is connected to the cathode terminal, the decoder output is connected to the digital input -analog converter, the output of the digital-to-analog converter is connected to the comparison and amplification module, and the output of the register is connected to the input of the memory module, the output of the pulse shaper is connected to the input of m After the memory module, the output of the memory module is connected to the input of the decoder, the output of which is connected to the input of the memory module, the input of the supply voltage generating module is connected to the anode terminal and the cathode terminal, and its outputs are connected to a digital-to-analog converter, comparison and amplification module, decoder, module memory, pulse shaper, comparator module, counter, register, while the output of the pulse shaper is connected to the input of the register, the other output of the pulse shaper is connected to the input of the decoder.

The invention is illustrated in FIG. 1, which shows a general block diagram of a device for controlling light-emitting crystals in an LED. The device comprises a comparator module 6, a counter 10, a register 7, a decoder 11, a pulse shaper 8, a memory module 12, a supply voltage generating module 9, a digital-to-analog converter 13, a comparison and amplification module 16, two amplifiers 14, 15, two resistors 17 , 18, transistors 5, 3, light-emitting crystals 4, while the input of the comparator module 6 is connected to the terminal 1 of the anode, and the output is connected to the input of the counter 10 and the input of the pulse shaper 8, the output of the counter 10 is connected to the input of the register 7, the output of the register 7 is connected with decoder 11 input, deco output Era 11 is connected to the bases of transistors 5, the collectors of which are connected to the cathodes of light-emitting crystals 4, the anodes of which are interconnected and connected to terminal 1 of the anode, and the emitters of transistors 5 are interconnected and connected to the input of the first amplifier 14 and to one contact of the resistor 17, another contact of the resistor 17 is connected to the cathode terminal 2, the output of the first amplifier 14 is connected to the input of the comparison and amplification module 16, the output of the comparison and amplification module 16 is connected to the base of the transistor 3, the collector of which is connected to the terminal 1 of the anode, and the mitter of transistor 3 is connected to the input of the second amplifier 15, the output of the second amplifier 15 is connected to the input of the comparison and amplification module 16, and the input of the second amplifier 15 is connected to one contact of the resistor 18, the second contact of the resistor 18 is connected to terminal 2 of the cathode, the output of decoder 11 is connected to the input of the digital-to-analog converter 13, the output of the digital-to-analog converter 13 is connected to the comparison and amplification module 16, and the output of the register 7 is connected to the input of the memory module 12, the output of the pulse shaper 8 is connected to the input of the module 12 pa That is, the output of the memory module 12 is connected to the input of the decoder 11, the output of which is connected to the input of the memory module 12, the input of the supply voltage generating module 9 is connected to the terminal 1 of the anode and terminal 2 of the cathode, and its outputs are connected to the digital-to-analog converter 13, module 16 comparison and amplification, the decoder 11, the memory module 12, the pulse shaper 8, the comparator module 6, the counter 10, the register 7, while the output of the pulse shaper 8 is connected to the input of the register 7, the other output of the pulse shaper 8 is connected to the input of the decoder 11.

The proposed device operates as follows: the terminals anode 1 - cathode 2 from the external circuit into which the device is connected, voltage is applied. The power supply voltage generating module 9 provides short-term energy storage to maintain the circuit for a period not exceeding the reset time, and distributes the voltage to the DAC (Digital-to-Analog Converter) 13, comparison and amplification module 16, decoder 11, memory module 12, register 7, counter 10, pulse shaper 8, comparator module 6. The incoming voltage from the terminal anode 1 to the input of the comparator module 6 is digitized at the level of 0.7 Volts and applied to the input of the counter 10 and the pulse shaper 8. Counter 10 counts the incoming pulses. When the receipt of pulses stops for a period of more than 2 periods (1 μs.), The pulse shaper 8 generates a load pulse of register 7, which writes the contents of the counter 10 to register 7, in turn, transmitting data to decoder 11 and the same data, which is the address, to memory module 12. Decoder 11 decodes the received command and, if it does not exceed N (the number of light-emitting crystals), generates a control voltage based on transistor 5 (1 ... N), opening it and igniting the light-emitting crystal 4 (1 ... included in its collector circuit) N). At the same time, the decoder 11 transmits the data received from the memory module 12 to the DAC 13, which generates a voltage for the comparison and amplification module 16. The module 16 comparison and amplification from the outputs of the amplifiers 14 and 15 are supplied voltage proportional to the currents flowing through the resistors 17 and 18, respectively. Comparison and amplification module 16 controls the voltage potential at the base of transistor 3 so that the ratio

I (rl7) = I (r18) * K, where K is the coefficient value in the memory cell,

thus, branching off part of the current flowing through the light-emitting crystal, which is proportional to the coefficient in the memory cell, through the transistor 3, providing adjustment of the brightness of the glow of the light-emitting crystal.

If, when decoding an instruction by decoder 11, its value exceeded the value of N (the number of light-emitting crystals), decoder 11 compares the instruction with the write command in memory, and if it matches, transfers data that is part of the instruction to memory module 12. If there are no pulses for a period of more than 8 periods (4 μs.), The pulse shaper 8 generates a write pulse of the memory module 12, by which the received correction coefficient for the selected light-emitting crystal is recorded in the corresponding memory cell.

If, when decoding a command by decoder 11, its value was 0 or did not match the write command to memory, then the decoder stops further receiving and analyzing commands until the circuit is reset.

When the external circuit removes the supply voltage from the terminal 1 of the anode for a time longer than the reset time — 16 periods (8 μs), the supply voltage generating unit 9 stops supplying the supply voltage to the circuit components, performing a reset operation and thus transferring the circuit to the initial state.

The technical and economic effect is achieved by using the described device in the apparatus due to a substantial reduction in the number of connections by 2 or more times due to a decrease in the required number of control channels for indicators and the number of power control keys, as well as through simplification of the hardware implementation of control circuits with large matrixes of LEDs. At the same time, the installation time is reduced due to the elimination of the LED arrangement model, associated with the heterogeneity of their brightness sorting.

Claims (1)

A device for controlling light-emitting crystals in an LED, characterized in that it comprises a comparator module, a counter, a register, a decoder, a pulse shaper, a memory module, a power voltage generation module, a digital-to-analog converter, a comparison and amplification module, two amplifiers, two resistors, transistors, light-emitting crystals, while the input of the comparator module is connected to the terminal of the anode, and the output is connected to the input of the counter and the input of the pulse shaper, the output of the counter is connected to the input of the register , the register output is connected to the decoder input, the decoder output is connected to transistor bases, the collectors of which are connected to the cathodes of light-emitting crystals, the anodes of which are interconnected and connected to the anode terminal, and the transistor emitters are interconnected and connected to the input of the first amplifier and to one contact resistor, another contact of the resistor is connected to the cathode terminal, the output of the first amplifier is connected to the input of the comparison and amplification module, the output of the comparison and amplification module is connected to the base of the transistor, the collector is connected to the anode terminal and the emitter of the transistor is connected to the input of the second amplifier, the output of the second amplifier is connected to the input of the comparison and amplification module, the input of the second amplifier is connected to one contact of the resistor, the second contact of the resistor is connected to the cathode terminal, the decoder output is connected to the digital input -analog converter, the output of the digital-to-analog converter is connected to the comparison and amplification module, and the output of the register is connected to the input of the memory module, the output of the pulse shaper is connected to to the memory module, the output of the memory module is connected to the input of the decoder, the output of which is connected to the input of the memory module, the input of the supply voltage generating module is connected to the anode terminal and the cathode terminal, and its outputs are connected to a digital-to-analog converter, comparison and amplification module, decoder, memory module, pulse shaper, comparator module, counter, register, while the output of the pulse shaper is connected to the input of the register, the other output of the pulse shaper is connected to the input of the decoder.

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