RU2693844C1 - Method to control light output level of light-emitting diodes and device for its implementation - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: invention relates to LED lighting devices, mainly, to car headlights. Result is achieved by a device for controlling the light output of light-emitting diodes, comprising positive and negative inputs supplying supply voltage to the device, light-emitting diodes, pulse current stabilizer, control unit and electronic switch with control input. Positive input of supply of supply voltage to the device is connected to the "ground" by two electric circuits, the first of which contains a resistive voltage divider, and the second one – a resistor and an electronic switch. Method of controlling light output of light-emitting diodes is that voltage across resistor R1, which is lower arm of resistive voltage divider, are measured at two different versions of current supply, namely: at the first version current is supplied along the first electric circuit, and by the second electric circuit current is not supplied, at the second version current is supplied both along the first and the second electric circuits. At the same time values of voltages measured at resistor R1 are compared at first and second versions of current supply, and depending on results of this comparison level of light output of LEDs is changed by changing value of current supplied to light-emitting diodes.

EFFECT: independence from jumps of input voltage, exclusion of effect of flicker of light in "low light" mode and provision of possibility of smooth change of level of luminous efficiency of light-emitting diodes.

14 cl, 8 dwg

Description

The invention relates to LED lighting devices, designed primarily for vehicles having electrical DC voltage circuits.

A known method of controlling the light output level of LEDs connected to a constant voltage source using a device controls the light output level of LEDs containing positive and negative inputs of the supply voltage to the device and an electrical circuit with a resistive voltage divider connecting the positive input supply voltage to the device with the "ground" consisting in the fact that periodically measure the voltage on the connected to the "ground" resistor R1, which is the lower arm of the above utogo resistive voltage divider, and depending on the results of these measurements alter light output of LEDs [Patent №2619601, Russian Federation, IPC N05V 33/00, process level control of light output of LEDs and device for its implementation / KI BUKHARIN and others, publ. 05/17/2017] - a prototype.

The known method is used in devices in which an abrupt change in the resistance of the electrical circuit connects the positive input supply voltage to the device with the positive pole of the DC voltage source by connecting or disconnecting a load resistor installed in the break of this electrical circuit using an operator-switched switch . In one position of the switch corresponding to the “high light” mode, the positive input of supplying power to the device is connected to the positive pole of the dc source directly, and in another position, corresponding to the “low light” mode, via the load resistor R _H. Therefore, the voltage measured on the resistor R1 in the "big light" mode has one value, and in the "small light" mode - another, smaller value. Setting in advance the threshold value U of the _{pores of the} measured voltage, switching the LEDs to the "low light" mode when the voltage on the resistor R1 drops below this threshold and switching to the "big light" mode - if the measured voltage exceeds this threshold.

The disadvantage of this method is that the voltage value measured at resistor R1 depends not only on whether the load resistor R _{n is} connected or disconnected, but also on the value of the input voltage U _in . As a result, the LEDs can be mistakenly switched from the “high light” mode to the “low light” mode if the input voltage drops below a certain value _Uxmin , at which the voltage across the resistor R1 is below the threshold U _then (see Fig. 1) . On the other hand, when in the “small light” mode and the input voltage _jumps above a certain value _Uxmax , the voltage across the resistor R1 will be higher than the threshold value U _then and an erroneous switch will occur from the “low light” mode to the “big light” mode. Therefore, the known method is undesirable to use in lighting devices, in the power supply circuits of which significant voltage fluctuations are possible. This narrows the scope of application of the known method.

In the known method, the light output of the LEDs is controlled by changing the duty ratio of the current pulses supplied to the LEDs. In the “low light” mode, current is supplied to the LEDs by pulses with a predetermined duty cycle. With a low level of “small light,” the duration of a single pulse can be half or even less than half the clocking period. Therefore, at a low pulse frequency, the effect of light flickering that is harmful to the human eye may appear. As a consequence, the known method is undesirable to use in lighting devices designed for lighting rooms. This also limits the scope of application of the known method.

In the known method, the required light output level of the LEDs is set by connecting or disconnecting a load resistor R _n installed in an open circuit connecting the positive input supply voltage to the device with the positive pole of the constant voltage source. Therefore, in a known manner, it is possible to realize only two levels of light output of the LEDs: “high light” and “low light”. This method does not allow to realize other values of the light output of the LEDs, which reduces consumer properties of the method.

In addition, this method cannot be used in devices in which a smooth change in the level of light output of LEDs occurs due to a smooth change in the resistance of the load resistor R _n installed in an open circuit connecting the positive input supply voltage to the device with the positive pole of the dc source . When using the known method in such lighting devices, it is impossible to ensure that the light output of LEDs matches the resistance of the load resistor R _n , because the change in voltage across the resistor R1 will also occur with a constant value of the load resistor R _n in case of a change in the input voltage. Therefore, the known method is undesirable to use in such lighting devices. This narrows the scope of application of the known method.

The problem to which the proposed method is aimed to control the level of light emitting diodes is to increase consumer properties and expand the scope of application of the method.

To solve this problem in the method of controlling the light output level of LEDs connected to a DC voltage source using a LED light output level control device containing positive and negative inputs for supplying power to the device and an electrical circuit with a resistive voltage divider connecting the positive input supply voltage to the device with the "ground", which consists in the fact that periodically measure the voltage across the connected to the "ground" resistor R1, which is the lower the shoulder of the above resistive voltage divider, and depending on the results of these measurements change the light output of the LEDs, according to the invention, the light output control device of the LEDs is equipped with a second electrical circuit connecting the positive input of the power supply to the device with the "ground" and containing the resistor R3, and the voltage on the resistor R1 measure with two different ways of applying current, namely: in the first embodiment, the current is supplied through the above-mentioned first electrical circuit, containing a resistive voltage divider, and the second electric circuit does not supply current, in the second embodiment, the current is supplied both in the first and second electrical circuits, while comparing the voltage values measured on the resistor R1, respectively, in the first and second variants supply current, and depending on the results of this comparison change the level of light output of LEDs by changing the amount of current supplied to the LEDs.

) и втором (

) вариантах подачи тока:In this case, the first and second variants of current supply are carried out alternately, alternating them one after another, and the values of the voltages on the resistor R1 are compared to each other by calculating the difference ΔU _n between adjacent values of the voltage on the resistor R1, measured, respectively, at the first (

) and second (

a) options for supplying current:

When implementing the method in devices in which an abrupt change in the resistance of the electrical circuit connecting the positive input supply voltage to the device with the positive pole of the constant voltage source, the current to the LEDs is served, following the rule: if the voltage difference ΔU _{n is} less than a predetermined threshold value ΔU _then , the rated current is supplied to the LEDs, and if the voltage difference ΔU _{n is} greater than the threshold value ΔU _then , the current is supplied to the LEDs oh less than the rated current by a predetermined amount.

And when implementing the method in devices in which a smooth change in the resistance of the electrical circuit connecting the positive input supply voltage to the device with the positive pole of the constant voltage source, the current is supplied to the LEDs, following the rule: if the voltage difference ΔU _n is zero, the LEDs a rated current is supplied, and if the voltage difference ΔU _{n is} not zero, a current is supplied to the LEDs, the value of which is less than the rated current by an amount proportional to the difference voltage ΔU _n .

The technical result provided by the invention, is to ensure the independence of the method from the input voltage jumps, the elimination of the effect of light flickering in the "small light" and the possibility of a smooth change in the level of light output of LEDs.

A device for controlling the light output level of LEDs is known, which contains positive and negative inputs for supplying power to the device, LEDs connected in series with the anode and cathode ends, a switching current regulator, a control unit and an electronic switch with a control input, while the supply voltage is positive on the device is connected to the "ground" by an electrical circuit containing a resistive voltage divider, a pulsed current regulator has a control input, and t Also, the positive and negative current supply outputs, the control unit contains an analog-digital converter, a digital signal processing and analysis unit connected to it, as well as a unit for generating periodic voltage pulses and has a control input and two control outputs, with the control input of the control unit from one end connected to the analog-digital converter, and at the other end connected to the above-mentioned electrical circuit between the resistors R1 and R2, forming a resistive voltage divider, the first the control output of the control unit is connected to the control input of a pulse current regulator, the second control output of the control unit is connected from one end to a unit for generating periodic voltage pulses, and from the other end to the control input of the aforementioned electronic switch, and the anode and cathode ends of the LED circuit are connected, respectively , with positive and negative current supply outputs of a pulsed current regulator [Patent # 2619601, Russian Federation, IPC H05B 33/00, Method of controlling the level of light output giving LEDs and a device for its implementation / Bukharinov KI and others, publ. 05/17/2017] - a prototype.

In the known device, an electronic switch is connected in series with resistors R1 and R2, forming a resistive voltage divider and forming part of an electrical circuit connecting the positive input of supplying power to the device with a “ground”. Due to this wiring diagram, the control unit can measure the voltage on the resistor R1, which is the lower shoulder of the resistive voltage divider, only when the electronic key is open. The voltage measured by the control unit is directly proportional to the voltage at the positive input of the supply voltage to the device. In the “big light” mode, when the positive input voltage supply to the device is connected to the positive pole of the constant voltage source, the voltage measured by the control unit on the resistor R1 will have one greater value, and in the “small light” mode, when positive the input supply voltage to the device is connected to the positive pole of the DC voltage source through the load resistor R _n , - another, smaller value. After setting the threshold value U _{then the} measured voltage, the LEDs switch to the “low light” mode when the voltage across the resistor R1 drops below this threshold and switches to the “big light” mode - when the measured voltage exceeds this threshold.

A disadvantage of the known device is that the voltage value measured by the control unit on the resistor R1 depends not only on whether the positive input supply voltage to the device is connected to the positive pole of the constant voltage source directly or through the load resistor R _n , but also on input voltage at a source of DC voltage (see Fig. 1). So, for example, when the LEDs are in the “high light” mode and the input voltage drops below a certain value _Uxmin , the voltage across the resistor R1, measured by the control unit, will be below the predetermined threshold value U _then. As a consequence, there will be an erroneous switch from the “big light” to the “small”. Conversely, when in the “small light” mode and the input voltage _jumps above a certain value _Uvxmax , the voltage across the resistor R1 will be higher than the threshold value U _then and an erroneous switching from “small light” to “large” will occur. Therefore, the known device is undesirable to use in such conditions where significant fluctuations in the input voltage are possible. This narrows the scope of the known device.

Another disadvantage of the known device is that it does not allow to determine for what reason there is a smooth change in the voltage measured on the resistor R1: either due to a change in the resistance of the load resistor R _n , or due to a change in the input voltage. Therefore, the known device cannot be used in lighting devices, in which a smooth change in the level of light output of LEDs takes place due to a smooth change in the resistance of the load resistor Rн installed in an open circuit connecting the positive input supply voltage to the device with a positive pole of a DC voltage source. This also limits the scope of application of the known device.

In the known device, the light output level of the LEDs is determined by the voltage value at the control input of the pulse current regulator. A disadvantage of the known device is that the voltage at the control input of the current regulator is set by the voltage value at the first control output of the control unit. In the “big light” mode, the control unit sends a continuous signal to its first control output. In the “low light” mode, the control unit sends to its first control output a control signal with pulses with a predetermined duty cycle. The duty cycle of the pulses is set so that the ratio of the average value of the voltage of the pulse signal to the voltage of the continuous signal is equal to the ratio of the light output of the LEDs in the “low light” mode to their light output in the “high light” mode. Due to the fact that the first control output of the control unit is connected to the control input of a pulsed current regulator via an electric circuit containing a resistive voltage divider, the voltage at the control input of the pulsed current regulator in the “high light” mode is: Uor = Uns URnp / (Rnp + Rвп), where Uns - voltage of the continuous signal at the first control output of the control unit, Rнп and Rвп - resistance, respectively, of the lower and upper arms of the resistive voltage divider.

In order for the pulse current regulator to issue a rated current to the LEDs, the voltage Uout at the control input of the pulse current regulator must be equal to the nominal voltage Unom. When the control unit is running, this voltage is maintained by the current supplied from the first control output of the control unit to the control input of the pulse current regulator. However, in the event that the control unit fails, the current supply from the first control output of the control unit to the control input of the current regulator will stop. In this case, the voltage at the control input of the pulse current regulator will be maintained only by the internal source of the reference voltage of the pulse current regulator. In this case, the lower arm of the resistive voltage divider Rnp and the internal resistance between the control input of the pulse current regulator and the voltage source also form a resistive voltage divider. Therefore, the voltage at the control input of the pulse current regulator will be: Uout = Uion =Rnp / (Rnp + Rion), where Uion is the value of the reference voltage, Rion is the internal resistance between the control input of the pulse current regulator and the source of the reference voltage. Since the value of the reference voltage Unom is equal to the value of the nominal voltage Unom, then when the resistance values Rnp are comparable to the resistance values Rion, the voltage values Uup at the control input of the pulsed current regulator are two times less than the nominal voltage Unom. Accordingly, the values of the current delivered by the pulse stabilizer to the LEDs will be two times less than the nominal value. Thus, in the event that the control unit fails, the light output of the LEDs will be two times lower than the nominal one. This reduces the consumer properties of the device.

A disadvantage of the known device is that the first control output of the control unit is connected to the control input of a pulse current regulator by means of an electrical circuit containing a resistive voltage divider. This resistive voltage divider makes it possible to reduce the amplitude of current pulses supplied from the first control output of the control unit to the control input of a pulsed current regulator in the “small light” mode, which does not allow smoothing these pulses. In the “low light” mode, the current to the LEDs is supplied by pulses with a high duty cycle, therefore, at a low pulse frequency, the effect of light flickering that is harmful to the human eye can manifest itself. As a consequence, the known device is undesirable to use in lighting devices intended for lighting rooms. This narrows the scope of the known device.

The task to be solved by the invention is to expand the field of application of the device and increase its consumer properties.

To solve this problem, in the device for controlling the light output level of LEDs, containing positive and negative inputs for supplying power to the device, LEDs connected in series with the anode and cathode ends, a switching current regulator, a control unit and an electronic switch with a control input, while the input supply voltage to the device is connected to the "ground" by an electric circuit containing a resistive voltage divider, a pulsed current regulator has control a control input, as well as positive and negative current supply outputs, the control unit contains an analog-digital converter, a digital signal processing and analysis unit connected to it, as well as a unit for generating periodic voltage pulses and has a control input and two control outputs, while the control input of the unit control at one end is connected to an analog-to-digital converter, and at the other end is connected to the above-mentioned electrical circuit between resistors R1 and R2, forming a resistive divider nap The first control output of the control unit is connected to the control input of a pulse current regulator, the second control output of the control unit is connected from one end to the power generation unit of periodic voltage pulses, and from the other end to the control input of the aforementioned electronic switch, and the anode and cathode ends of the LED circuit Connected, respectively, with positive and negative current-supplying outputs of a pulse current regulator, according to the invention, the device is equipped with a second electric epyu connecting the positive input supply voltage to the device with the "ground" and comprising a series-connected resistor R3 and the above-mentioned electronic key.

In addition, a pulse current regulator contains a reference voltage source, the positive terminal of which is connected to the control input of the stabilizer, the first control output of the control unit is connected to the control input of the pulse current stabilizer by means of an electric circuit containing a smoothing filter, and the control unit contains the key and the drive controlling this key , while the key is installed in the gap of the electrical circuit connecting the first control output of the control unit with the "ground", and the drive control key soy Inonii processing unit and digital signal analysis.

The smoothing filter can be implemented, for example, in the form of an active-capacitive filter containing a resistor R4 and a capacitor C1.

The control unit may have a different design. According to one of the possible variants of its execution, the control unit contains a microcontroller into which an analog-to-digital converter (ADC), a digital signal processing and analysis unit, a unit for generating periodic voltage pulses, a key, and a key drive actuator of the control unit are embedded. At the same time, the microcontroller has two general-purpose outputs and an ADC output, and the ADC output is connected to the control input of the control unit, the first and second general-purpose outputs of the microcontroller are connected, respectively, to the first and second control outputs of the control unit, the key is set to an open circuit connecting the first general-purpose output of the microcontroller is with the “ground”, and the unit for generating periodic voltage pulses is connected to the second general-purpose output of the microcontroller.

The pulse current regulator may also have a different design. In one of the possible versions of the device, a pulsed current regulator contains a ZXLD1362 type microcircuit with an integrated reference voltage source, an inductor L1, a Schottky diode VD2, a resistor R5, and a capacitor C2.

To smooth the voltage fluctuations in the power supply circuit of the LEDs, the device is additionally equipped with a capacitor C3 connected to the anode and cathode ends of the LED circuit.

The electronic key can be made in the form of an N-channel field-effect transistor, in the form of an npn type bipolar transistor, in the form of a pnpp type bipolar transistor, and also in the form of an optocoupler.

The technical result provided by the invention, is to smooth the current pulses supplied to the LEDs and ensure the illumination of LEDs with a brightness corresponding to the "big light" in the event of a control unit failure.

The invention is illustrated by drawings. FIG. 1 shows a graph explaining the principle of operation of the device according to the patent of the Russian Federation No. 2619601. FIG. 2 is a graph showing the change in voltage at the control input of a pulsed current regulator in the “low light” mode; in fig. 3, 4, 5, 6, 7 depict electrical circuits of the devices for controlling the light output level of LEDs, in which an abrupt change in the resistance of the electrical circuit connects the positive input of supplying power to the device with the positive pole of a DC source by connecting or disconnecting a load resistor, and the electronic key is made: in FIG. 3, 4 - in the form of an N-channel field-effect transistor; in FIG. 5 - in the form of a bipolar npn transistor of the type, in FIG. 6 - in the form of a bipolar transistor pnp type; in fig. 7 - in the form of an optocoupler, while in FIG. 3 shows the control unit in general, and FIG. 4, 5, 6, 7 - in the specific case when the control unit contains a microcontroller. FIG. 8 shows the electrical circuit of the device, in which a smooth change in the resistance of the load resistor is carried out, the electronic switch is made in the form of an N-channel field effect transistor, and the control unit contains a microcontroller.

The device 1 controls the level of light output of the LEDs contains a positive 2 and negative 3 inputs supplying power to the device, LEDs 4 connected in series with the anode 5 and cathode 6 ends, a switching current regulator 7, a control unit 8 and an electronic switch with a control input.

Positive 2 and negative 3 inputs supply voltage to the device 1 through a diode bridge 9 connected to the poles 10, 11 of the DC voltage source 12.

The negative input 3 of the supply voltage to the device is connected to ground. The positive input 2 of the supply voltage to the device is connected to "ground" by two electrical circuits 13, 14. The first electrical circuit 13 contains series-connected resistors 15 (R1) and 16 (R2), forming a resistive voltage divider and, respectively, its bottom and upper shoulders. The second electrical circuit 14 contains a series-connected resistor 17 (R3) and an electronic switch.

The control unit 8 has a control input 18 and two control outputs 19, 20, as well as positive 21 and negative 22 inputs for supplying power to the control unit. In the General case, the control unit 8 contains serially connected analog-to-digital Converter 23, the unit 24 for processing and analyzing the received digital signal and the key control drive 25, as well as the unit 27 for generating periodic voltage pulses (see FIG. 3).

The control input 18 of the control unit 8 is connected at one end to an analog-to-digital converter 23 and connected at the other end to an electric circuit 13 between resistors 15 (R1) and 16 (R2), forming a resistive voltage divider. The second control output 20 of the control unit 8 is connected from one end to the unit 27 for generating periodic voltage pulses, and from the other end to the control input of the electronic key. The key 26 is installed in the gap of the electric circuit 28 connecting the first control output 19 of the control unit with the "ground". The positive input 21 of the supply voltage to the control unit 8 through the power supply 29 and the Schottky diode 30 (VD1) is connected to the positive input 2 of the supply voltage to the device 1. The negative input 22 of the supply voltage to the control unit 8 is connected to ground.

The pulse current regulator 7 has a control input 31, a positive 32 and a negative 33 inputs for supplying voltage to the stabilizer, as well as positive 34 and negative 35 current-supplying outputs. The positive input 32 of the supply voltage to the switching current regulator through the Schottky diode 30 (VD1) is connected to the positive input 2 of the supply voltage to the device 1. The negative input 33 of the supply voltage to the stabilizer is connected to ground. To the positive 34 and 35 negative current-supply outputs of the pulse current regulator 7 are connected, respectively, the anode 5 and cathode 6 ends of the circuit of the LEDs 4.

The first control output 19 of the control unit 8 by means of an electric circuit 36 containing a smoothing filter is connected to the control input 31 of a pulsed current regulator 7.

The smoothing filter can be implemented, for example, in the form of an active-capacitive (RC) filter containing a resistor 37 (R4) and a capacitor 38 (C1).

In the private version, the control unit 8 may contain a microcontroller 39, which has an analog-to-digital converter (ADC) 23, a digital signal processing and analysis unit 24, a key driver 25, and a unit 27 for generating periodic voltage pulses of the control unit (see FIG. . four). The microcontroller 39 has two outputs of general purpose 40 (GP1), 41 (GP2) and output 42 (GP0) of the ADC. The output 42 (GP0) is connected from one end to the ADC 23, and from the other end is connected to the control input 18 of the control unit 8. The first 40 (GP1) and the second 41 (GP2) outputs of the general-purpose microcontroller are connected, respectively, to the first 19 and second 20 control outputs of the control unit 8. The key 26 is installed in the gap of the electric circuit 43 connecting the first output of the general-purpose 40 (GP1) with the "ground". The unit 27 generating periodic voltage pulses connected to the second output of the General purpose 41 (GP2).

The positive input 44 (Vdd) and the negative input 45 (Vss) of the supply voltage to the microcontroller 39 are connected, respectively, to the positive input 21 and the negative input 22 of the supply voltage to the control unit 8.

Pulse current regulator 7 may have a different design. In one of the possible variants, the pulsed current regulator 7 contains a ZXLD1362 type chip 46 with an integrated voltage source 47, a choke 48 (L1), a Schottky diode 49 (VD2), a resistor 50 (R5), a capacitor 51 (C2).

The positive terminal 52 of the reference voltage source 47 is connected to the output 53 (ADJ) of the microcircuit, which, in turn, is connected to the control input 31 of the pulsed current regulator 7. The output 54 (Vin) of the microcircuit 51 is connected to the positive input 32 of the supply voltage to the switching regulator current 7 and through the capacitor 51 (C2) - with the "ground". Pin 55 (GND) of the microcircuit is connected to the negative input 33 of supplying power to the pulse current regulator 7. Pin 56 (Isense) of the microcircuit is connected to the positive current supply output 34 of the pulsed current regulator and connected to pin 54 (Vin) via a resistor 50 (R5) microcircuits. Pin 57 (LX) of the microcircuit is connected to the negative current supply output 35 of the pulse current regulator through the choke 48 (L1). The anode of the Schottky diode 49 (VD2) is connected to pin 57 (LX) of the microcircuit, and the cathode of the Schottky diode 49 (VD2) is connected to pin 54 (Vin) of the microcircuit.

The electronic key may have a different design. It can be performed, for example, in the form of an N-channel field-effect transistor 58 (see Fig. 3, 4, 8), in the form of a bipolar transistor 59 npn type (see Fig. 5), in the form of a bipolar transistor 60 pn-p type (see Fig. 6), in the form of an optocoupler 61 (see Fig. 7), etc.

In the case when the electronic switch is made in the form of an N-channel field-effect transistor 58, its control input is a gate 62. The drain 63 of the transistor is connected via a resistor 17 (R3) to the positive input 2 of the supply voltage to the device. The source 64 of the transistor is connected to ground and through an additional resistor 65 (R6) to gate 62 (see Figs. 3, 4, 8).

In the case when the electronic switch is made in the form of a bipolar transistor 59 npn type, the control input of which is base 66, the collector 67 is connected to the device via the resistor 17 (R3) positive input 2, and the emitter 68 is connected to ground "(See Fig. 5).

In the case when the electronic key is made in the form of a bipolar transistor 60 pn-p type, the control input of which is base 69, with the positive input 2 of the supply voltage to the device through a resistor 17 (R3) its emitter 70 is connected, and the collector 71 is connected to "Ground" (see Fig. 6).

In the case when the electronic switch is made in the form of an optocoupler 61, the control input of which is the input of the emitter 72, the input 73 of the photodetector is connected to the positive input 2 of the supply voltage to the device and the photodetector output 74 is connected to ground (see Fig. 7).

In the case when the electronic key is made in the form of a bipolar transistor 59 npn type or in the form of a bipolar transistor 60 pn-p type or in the form of an optocoupler 61, the second control output 20 of the control unit 8 is connected to the control input of the electronic key through a resistor 75 (R7) .

The device is equipped with a capacitor 76 (C3) connected to the anode 5 and cathode 6 ends of the LED circuit 4.

The power supply unit 29 of the control unit 8 comprises a resistor 77 (R7), a diode 78 (VD3) and a capacitor 79 (C4).

In addition, the device is equipped with a diode 80 (VD4).

One of the inputs (81) of the diode bridge 9 is connected to the pole 11 of the DC voltage source 12 directly. The connection of another input (82) of the diode bridge 9 to the pole 10 of the DC voltage source 12 depends on the way in which the light output of the LEDs is controlled.

In lighting devices, in which an abrupt change in the resistance of the electrical circuit connecting the positive input 2 of the supply voltage to the device with the positive pole 10 of the constant voltage source, by connecting or disconnecting a load resistor, the input 82 of the diode bridge 9 is connected to the pole 10 of the constant voltage source 12 with an electrical circuit containing a switch 83. In one position of the switch 83, the input 82 of the diode bridge 9 is connected to the pole 10 directly. This position of the switch 83 corresponds to the “high light” mode. In another position of the switch 83, the input 82 of the diode bridge 9 is connected to the pole 10 via a load resistor 84 (R _n ). This position of the switch 83 corresponds to the "small light".

In lighting devices, in which a smooth change in the resistance of the electrical circuit that connects the positive input 2 of the supply voltage to the device with the positive pole 10 of the constant voltage source, is applied, the input 82 of the diode bridge 9 is connected to the pole 10 of the constant voltage source 12 by an electrical circuit containing a load resistor 85 with smoothly variable resistance (see Fig. 8).

The light output level of the LEDs is controlled as follows.

In existing lighting devices using dc incandescent lamps, in particular in car headlights, the driver of the vehicle sets the switch 82 to a position in which the voltage to the positive input is used to realize the "big light" mode (for cars - "dim light" mode). 2 supply voltage to the device 1 is supplied directly from the positive pole 10 of the DC voltage source 12. In this case, incandescent bulbs shine with maximum brightness. To implement the mode of "small light" (for cars - mode "daytime running lights") switch 82 is set in a position in which the voltage to the positive input 2 of the supply voltage to the device 1 is supplied through the load resistor 84 (R _n ). In this case, incandescent bulbs shine with reduced brightness. For a smooth change in the brightness of the lamps, they smoothly change the resistance of the load resistor 85.

In order to control the light output of LEDs of an LED lamp installed in a lighting device, in particular in a car headlight, instead of an incandescent lamp, you need to know the voltage value on the positive input 2 of the supply voltage to device 1. To do this, measure the voltage on the resistor 15 ( R1), which is the lower arm of the resistive voltage divider.

Measurements of the voltage on the resistor 15 (R1) are performed using an analog-to-digital converter (ADC) 23 transferred to the analog input mode 23. Several times per second, the unit 27 generating periodic voltage pulses, supplying the control voltage from the control output 20 to the control input of the electronic key, alternately , then opens, then closes the electronic key. When the electronic key is closed, the current flows through the first electric circuit 13, and through the second electric circuit 14, the current does not flow (the first variant of current supply). When the electronic key is open, the current flows through both the first 13 and the second 14 electrical circuits (the second variant of current supply). The voltage across the resistor 15 (R1) is measured with both current supply options.

At the same time, the values of the voltages measured on the resistor 15 (R1), respectively, are constantly compared with each other in the first and second variants of current supply. Comparison of the voltage values is carried out by calculating the difference ΔU _n between adjacent values of the voltage across the resistor 15 (R1):

и

- значения напряжений на резисторе 15 (R1), замеренные, соответственно, при первом и втором вариантах подачи тока.Where

and

- values of voltages on the resistor 15 (R1), measured, respectively, in the first and second variants of the current supply.

When implementing the method in devices in which there is an abrupt change in the resistance of the electric circuit connecting the positive input 2 of the supply voltage to the device 1 with the positive pole 10 of the DC voltage source 12, by connecting and disconnecting the load resistor 84 (R _n ), the resulting voltage difference ΔU _{n is} compared with a predetermined threshold value ΔU _then . If the difference ΔU _n is less than the threshold value ΔU _then , then this means that the “high light” mode is on. In this case, the drive 25 opens the key, thereby disconnecting the first control output 19 (in the particular case, putting the first general output 40 (GP1) into a high-impedance state). In this case, the reference voltage source 47 of the pulsed current stabilizer becomes the voltage source at the control input 31 of the pulsed current regulator 7 and, accordingly, at the output 53 (ADJ) of the chip 46. Due to the voltage U, the ion source of the reference voltage 47 at the output 53 (ADJ) of the chip 46 will establish the nominal voltage Un, at which the rated current is supplied to the LEDs 4. In this case, the light output of the LEDs 4 corresponds to the “high light” mode.

If the difference ΔU _n is greater than ΔU _then , then this means that the “low light” mode is on. In this case, the drive periodically opens, then closes key 26. When key 26 is open, the voltage of the voltage source 47 charges the capacitor 38 (C1) and the voltage at pin 53 (ADJ) of the chip 46 increases (segment a-b in Fig. 2) . When the key 26 is closed, the capacitor 38 (C1) through the resistor 37 (R4) is discharged to ground and the voltage at the output 53 (ADJ) decreases (segment bc in Fig. 2). The average voltage Ucp at pin 53 (ADJ) will be less than the nominal voltage Unom. The periodicity of opening and closing of the key 26 is set such that the ratio of the average voltage Ucp to the nominal voltage value Unom is equal to the ratio of the light output of the LEDs in the “low light” mode to their light output in the “high light” mode. As a result, a current, the average value of which is less than the nominal value by a predetermined value, is supplied to the LEDs 4 from the current supply outputs 30, 31 of the pulsed current regulator 7, and the LEDs are illuminated with a brightness corresponding to the “low light” mode.

As with the threshold value ΔU _then compared not the absolute value of the voltage, and the voltage difference ΔU _n, the input voltage jumps U _Rin not introduce error in determining whether to enable or disable load resistor 84 (R _n), and thus do not affect the switching LEDs in the modes of "big" or "small" light.

When implementing the method in devices in which there is a smooth change in the resistance of the electrical circuit connecting the positive input 2 of the supply voltage to the device 1 with the positive pole 10 of the DC voltage source 12, due to the smooth change of the resistance of the load resistor 85, the current to the LEDs is guided by the following by the rule. If the voltage difference ΔU _n is equal to zero, the drive 25 opens the key 26, turning off the first control output 19 (transferring the first general-purpose output 40 (GP1) to the high-impedance state). Due to the voltage U, the ion source of the reference voltage 47 at the output 53 (ADJ) of the chip 46 will establish the nominal voltage Un, at which the rated current is supplied to the LEDs 4.

And if the voltage difference ΔU _{n is} not zero, a current is supplied to the LEDs, the value of which is less than the rated current by an amount proportional to the voltage difference ΔU _n . One of the ways to implement the latter can be, for example, increasing the closure duration of key 26 and, accordingly, disconnecting the first control output 19 (transferring the first general-purpose output 40 (GP1) to a high-impedance state) proportional to the difference ΔU _n during each clock period. Due to this, the value of the average voltage Ucp at the output 53 (ADJ) of the chip 46 is reduced relative to the nominal value Uom in proportion to ΔU _n . As a result, a current is supplied to the LEDs 4, the value of which is less than the rated current by an amount proportional to the voltage difference ΔU _n .

Since the light output of LEDs does not depend on the absolute value of the voltage on the resistor 15 (R1), but on the voltage difference ΔU _n , changes in the input voltage U _in do not introduce errors in determining how much the resistance of the load resistor 85 has changed, and, accordingly, to change the level light output of LEDs.

Diode bridge 9 allows you to connect the device 1 to control the level of light output of the LEDs to a constant voltage source 12, regardless of the polarity of the poles 10, 11 of the constant voltage source.

The capacitor 76 (C3) smoothes the voltage fluctuations in the power supply circuit of the LEDs 4. The capacitor 51 (C2) smoothes the voltage fluctuations in the power supply circuit of the pulsed current regulator 7.

The power supply 29 reduces the voltage from the positive input 2 of the supply voltage to the device to the positive input 21 of the supply voltage to the control unit 8, to the desired value and smoothes its fluctuations.

The diode 80 prevents the supply of voltage to the electrical circuit of the device that exceeds the maximum allowable values.

Claims (15)

1. The method of controlling the level of light output of LEDs connected to a constant voltage source using a device controlling the level of light output of LEDs containing positive and negative inputs of supplying voltage to the device and an electrical circuit with a resistive voltage divider connecting the positive input of supplying voltage to the device with ground ", Which periodically measures the voltage across the resistor R1 connected to ground, which is the lower arm of the aforementioned p Resistive voltage divider, and depending on the results of these measurements change the light output of LEDs, characterized in that the device controls the level of light output of LEDs equipped with a second electric circuit connecting the positive input supply voltage to the device with the "ground" and containing a resistor R3, and the voltage on resistor R1 is measured with two different current supply options, namely: in the first embodiment, the current is supplied through the aforementioned first electrical circuit containing a resistive divider voltage, and the second electric circuit does not supply current; in the second embodiment, the current is supplied both through the first and second electrical circuits, while comparing the voltages measured with resistor R1, respectively, with the first and second variants of current supply, and Depending on the results of this comparison, the light output of the LEDs is changed by changing the amount of current supplied to the LEDs. 2. The method according to p. 1, characterized in that the first and second variants of the supply of current is carried out alternately, alternating them one after another, and the values of the voltages on the resistor R1 are compared to each other by calculating the difference ΔU _n between adjacent values of the voltage on the resistor R1, measured respectively at the first

and second

power supply options:

3. The method according to p. 2, characterized in that when implementing the method in devices in which an abrupt change in the resistance of the electrical circuit connecting the positive input supply voltage to the device with the positive pole of the constant voltage source, the current to the LEDs is served, following the rule if the difference voltage ΔU _n smaller than a predetermined threshold value ΔU _then, fed to the LEDs rated current, and if the difference ΔU _n voltages greater than the threshold value ΔU _long on vetodiody supplied current having a value less than the nominal current by a predetermined amount. 4. The method according to p. 2, characterized in that when implementing the method in devices in which there is a smooth change in the resistance of the electrical circuit connecting the positive input supply voltage to the device with the positive pole of the DC voltage source, the current to the LEDs is served according to the following rule : if the voltage difference ΔU _n is zero, a rated current is applied to the LEDs, and if the voltage difference ΔU _{n is} not zero, a current is fed to the LEDs, the value of which is less than the rated current by The value is proportional to the voltage difference ΔU _n . 5. A device for controlling the light output level of LEDs containing positive and negative inputs for supplying power to the device, LEDs connected in series with the anode and cathode ends, a switching current regulator, a control unit and an electronic switch with a control input, with a positive input voltage supply power to the device is connected to the "ground" by an electrical circuit containing a resistive voltage divider, a pulsed current regulator has a control input, and also Auxiliary and negative current supply outputs, the control unit contains an analog-to-digital converter, a digital signal processing and analysis unit connected to it, as well as a unit for generating periodic voltage pulses and has a control input and two control outputs, while the control input of the control unit is connected from one end with an analog-to-digital converter, and at the other end is connected to the above-mentioned electrical circuit between resistors R1 and R2, forming a resistive voltage divider, the first one controls The control output of the control unit is connected to the control input of a pulse current regulator, the second control output of the control unit is connected from one end to a unit for generating periodic voltage pulses, and from the other end to the control input of the aforementioned electronic switch, and the anode and cathode ends of the LED circuit are connected respectively to positive and negative current supply outputs of a pulsed current stabilizer, characterized in that the device is equipped with a second electrical circuit that connects Yelnia input supply voltage to the device from the "ground" and comprising a series-connected resistor R3 and the above-mentioned electronic key. 6. The device according to claim 5, characterized in that the pulsed current regulator contains a reference voltage source, the positive terminal of which is connected to the control input of a pulsed current regulator, the first control output of the control unit is connected to the control input of a pulsed current regulator by means of an electric circuit containing a smoothing filter , and the control unit contains a key and a drive controlling this key, while the key is installed in an open circuit connecting the first control output of the control unit ground, and the drive control key is connected to the processing unit and the analysis of the digital signal. 7. The device according to p. 6, characterized in that the smoothing filter is made in the form of an active-capacitive filter containing a resistor R4 and a capacitor C1. 8. The device according to claim 6, characterized in that the control unit contains a microcontroller that has an analog-to-digital converter (ADC), a digital signal processing and analysis unit, a unit for generating periodic voltage pulses, a key and a control drive for the key of the control unit; This microcontroller has two general-purpose outputs and an ADC output, with the output of the ADC from one end connected to the ADC, and from the other end connected to the control input of the control unit, the first and second general-purpose outputs of the microcontroller There are no corresponding with the first and second control outputs of the control unit, the key is set to an open circuit connecting the first general-purpose pin of the microcontroller to the “ground”, and the unit for generating periodic voltage pulses is connected to the second general-purpose pin of the microcontroller. 9. The device according to claim 6, characterized in that the pulsed current regulator contains a ZXLD1362 type microcircuit with a built-in reference voltage source, an inductor L1, a Schottky diode VD2, a resistor R5 and a capacitor C2; , the Isense pin of the microcircuit is connected to the positive current supply output of a pulsed current regulator and through the resistor R5 is connected to the Vin pin of the microcircuit, the output of the LX chip is connected via a choke L1 to a negative current-supplying output of a pulsed st current amplifier, the Schottky anode VD2 is connected to the LX pin of the chip, and the Schottky cathode of the VD2 pin is connected to the Vin pin of the microcircuit, the GND pin of the microcircuit is connected to ground, the positive output of the voltage source is connected to the ADJ pin of the microcircuit. 10. The device according to claim 5, characterized in that it is additionally equipped with a capacitor C3 connected to the anode and cathode ends of the circuit of LEDs. 11. The device according to claim 5, characterized in that the electronic key is made in the form of an N-channel field-effect transistor, the control input of which is a gate, wherein the drain of the N-channel field-effect transistor is connected to the positive input of supplying power to the device through a resistor R3, and the source of the specified transistor is connected to ground and, via an additional resistor R6, to the gate of this transistor. 12. The device according to p. 5, characterized in that the electronic key is made in the form of a bipolar npn transistor of the type, the control input of which is the base, while the collector of the bipolar transistor is connected to the positive input of the supply voltage to the device, and the emitter of the specified transistor connected to the "land". 13. The device according to claim 5, characterized in that the electronic key is made in the form of a pn-p type bipolar transistor, the control input of which is the base, while the emitter of the bipolar transistor is connected to the positive input of the supply voltage to the device, and the collector the specified transistor is connected to ground. 14. The device according to claim 5, characterized in that the electronic key is made in the form of an optocoupler, the control input of which is the emitter input, while the input of the photodetector is connected to the positive input of the device through a resistor R3 and the photodetector output is connected to ground ".

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