KR20160043599A - Circuit for controlling luminance of a multi channel led - Google Patents

Abstract

The present invention relates to a lamp brightness control circuit which can minimize the required circuit size and component cost when controlling two LED lamps to have different brightness. The lamp brightness control circuit includes: a driving unit which includes a switch, an energy storage unit and a control unit; and a lamp unit which is coupled to the energy storage unit and includes a first lamp and a second lamp. The energy storage unit receives energy from a power supply unit by using opening and closing operations of the switch. The control unit is configured to control the opening and closing operations of the switch in response to a control signal to transmit the energy supplied from the power supply unit to the energy storage unit to save the energy in the energy storage unit and transmit the stored energy to the first and second lamps.

Description

[0001] Description [0002] CIRCUIT FOR CONTROLLING LUMINANCE OF A MULTI CHANNEL LED [0003]

The present invention relates to LED brightness control, and more particularly to a multi-channel LED lamp brightness control circuit.

LED (Light Emitting Diode) is an eco-friendly light source that has advantages such as small size, light weight, low voltage driving and long life, and is attracting attention as a next generation light source to replace fluorescent lamp. In accordance with this trend, the backlight used in display devices such as televisions and monitors is being replaced by CCFL backlights (fluorescent lamps) and LED backlights, and household and industrial lighting is being replaced by LED lighting from fluorescent lamps.

In the case of LED lighting, it is common to adjust the brightness using Pulse Width Modulation (PWM) method. By adjusting the duty ratio between the high level and the low level of the PWM control signal of the square wave, do. If the PWM control signal is at a high level, the LED is turned on. If the PWM control signal is at a low level, the LED is turned off, and the brightness of the LED light is controlled by adjusting the ratio of the time the LED is on and the time the LED is off .

When two or more LEDs need to be controlled at different brightness, a control circuit is connected to each LED, and brightness is adjusted in accordance with each PWM control signal from the control circuit. However, this method requires a separate control circuit for each LED, which causes damage in terms of circuit area and component cost.

It is an object of the present invention to provide a multi-channel LED lamp brightness control circuit capable of minimizing the circuit area and component cost required for controlling two LED lamps at different brightnesses.

In order to achieve the above object, a lamp brightness control circuit of the present invention includes a driver including a switch, an energy storage unit and a control unit, and a lamp unit coupled to the energy storage unit and including a first lamp and a second lamp. Here, the energy storage unit receives energy from the power supply unit by the opening and closing operation of the switch, and the control unit controls the energy supplied from the power supply unit to be transferred to and stored in the energy storage unit in response to the control signal, Closing operation of the switch to be transmitted to the first lamp and the second lamp.

In one embodiment, the second lamp enables transfer of energy from the power supply unit to the energy storage unit, and is mounted in a separate module from the drive unit.

In one embodiment, the control signal is a square wave comprising a series of first voltage level signals and a series of second voltage level signals alternating with the series of first voltage level signals, Is determined by the time ratio of the first voltage level signal and the second voltage level signal of the signal.

In one embodiment, the energy storage includes an inductor and a capacitor connected in series, one end of the inductor is coupled to the switch and the second lamp, and the other end of the inductor is coupled to the capacitor and the first lamp . Here, the relative brightness of the second ramp with respect to the first ramp is determined by the ratio of the inductor value or the voltage across the power supply to the voltage across the capacitor.

Another lamp brightness control circuit of the present invention includes a driving unit including an energy storage unit and a control unit coupled to a power supply unit, and a lamp unit coupled to the energy storage unit and including a first lamp and a second lamp. Here, the second lamp is coupled to the power source unit, and the control unit controls the operation of storing the energy supplied from the power source unit in the energy storage unit in response to the control signal and the operation of storing the stored energy in the first lamp and the second lamp So that the operation to be performed is alternately performed.

In one embodiment, the second lamp enables transfer of energy from the power supply unit to the energy storage unit, and is mounted in a separate module from the drive unit.

In one embodiment, the control signal is a square wave comprising a series of first voltage level signals and a series of second voltage level signals alternating with the series of first voltage level signals, Is determined by the time ratio of the first voltage level signal and the second voltage level signal of the signal.

In one embodiment, the energy storage includes an inductor and a capacitor, the inductor and the capacitor are coupled in series and coupled in parallel with the second lamp, and the first lamp is coupled in parallel with the capacitor. Here, the relative brightness of the second ramp with respect to the first ramp is determined by the ratio of the inductor value or the voltage across the power supply to the voltage across the capacitor.

According to the present invention, two LED lamps can be controlled to have different brightness by using one driving circuit.

FIG. 1 is a view for explaining the operation principle of the multi-channel LED lamp brightness control circuit according to the first embodiment of the present invention.
2A is a diagram showing an operation of opening / closing a switch according to a control signal in a multi-channel LED lamp brightness control circuit.
FIG. 2B is a view showing a waveform of a current flowing in an inductor during a time period in which the control signal is a high level signal after the current flowing through the first ramp in the multi-channel LED lamp brightness control circuit reaches a steady state.
2C is a diagram showing a waveform when the current flowing through the first lamp reaches a steady state.
2 (d) is a graph showing a waveform of a current flowing through the second ramp when the current flowing through the inductor is the same as the waveform of FIG. 2a.
3 is a diagram illustrating a multi-channel LED lamp brightness control circuit according to a second embodiment of the present invention.
4 is an exemplary diagram for explaining the brightness change of the first and second lamps according to the change of the control signal in the multi-channel LED lamp brightness control circuit.
5 is a diagram illustrating a multi-channel LED lamp brightness control circuit according to a third embodiment of the present invention.
6 is a diagram illustrating a multi-channel LED lamp brightness control circuit according to a fourth embodiment of the present invention.
7 is a circuit diagram for simulating the multi-channel LED lamp brightness control circuit of the present invention shown in Fig.
8 is a diagram showing a simulation result of the circuit shown in Fig.

Hereinafter, the present invention will be described in detail with reference to Figs. 1 to 8. Fig.

1 is a diagram illustrating a multi-channel LED lamp brightness control circuit 100 according to a first embodiment of the present invention. The multi-channel LED lamp brightness control circuit 100 includes an energy storage unit 130 coupled to the power supply unit 110 through the switch 120 and a second lamp (not shown) coupled in parallel to the front end of the energy storage unit 130. [ 132 < / RTI > The energy storing unit 130 can receive energy from the power source unit by the opening and closing operation of the switch 120. In one embodiment, the switch 120 may be implemented using transistors.

The second lamp 132 enables transfer of energy from the power source unit 110 to the energy storage unit 130 and the energy storage unit 130 and the second lamp 132 can transfer energy from the power source unit 110 to the first To the lamp (140). In this process, the energy storing unit 130 may repeat the operation of charging the energy from the power source unit 110 and discharging the charged energy, and the second lamp 132 may emit light energy. The second lamp 132 may include at least one LED.

In one embodiment, the energy storage 130 may include a capacitor 136 and an inductor 134 coupled in series. In this case, one end of the inductor 134 may be coupled to the switch 120 and the second lamp 132, and the other end of the inductor 134 may be coupled to the capacitor 136. In this configuration, energy transferred from the power supply unit 110 to the energy storage unit 130 may be stored in the inductor 134 and the capacitor 136.

The multi-channel LED lamp brightness control circuit 100 may further include a first lamp 140 coupled to the energy storage unit 130. The first lamp 140 may receive energy stored in the energy storage unit 130 and emit light energy. One end of the inductor 134 is coupled to the switch 120 and the second lamp 132 and the inductor 134 is coupled to the inductor 134. The energy storage unit 130 includes an inductor 134 and a capacitor 136 connected in series, The capacitor 136 and the first lamp 140 may be coupled to each other. In one embodiment, the first lamp 140 may include at least one LED, and may be the same as or different from the second lamp 132.

The multi-channel LED lamp brightness control circuit 100 may further include a controller 150 coupled to the first lamp 140 and the switch 120. The control unit 150 controls the opening and closing operation of the switch 120 in response to the control signal so that energy transfer from the power source unit 110 to the energy storage unit 130 and storage of the energy stored in the energy storage unit 130 The first lamp 140 and the second lamp 132 may be controlled to control the driving of the first lamp 140 and the second lamp 132. [

In one embodiment, the control signal may be a spherical file having a constant period. In this case, the square wave may comprise a series of high level signals and a series of low level signals alternating with the series of high level signals. Here, the brightness of the first lamp 140 can be adjusted by adjusting the time ratio (duty ratio) of the high level signal and the low level signal in the control signal. The brightness of the second lamp 132 is lower than the brightness of the first lamp 140 and the brightness of the second lamp 132 relative to the first lamp 140 is lower than the brightness of the inductor 134 Or the ratio of the voltage across the power supply 110 to the voltage across the capacitor 136 in the energy storage 130.

As the ratio of the high level signal in the control signal increases, the brightness of the first lamp 140 increases. Conversely, as the ratio of the high level signal decreases, the brightness of the first lamp 140 decreases. Therefore, when the voltage of the power source unit 110, the inductor 134 and the capacitor 136 in the energy storage unit 130 are fixed, the time ratio (duty ratio) of the high level signal and the low level signal in the control signal is adjusted The brightness of the first lamp 140 and the brightness of the second lamp 132 can be adjusted together.

2A is a diagram showing the opening and closing operations of the switch 120 according to a control signal in the multi-channel LED lamp brightness control circuit 100. As shown in FIG. As shown in the figure, during a time interval t1 during which the control signal is a high level signal H, the switch 120 can be controlled to be in the on (closed) / off (open) state at regular intervals. Energy is transferred from the power supply unit 110 to the energy storage unit 130 and energy is stored in the inductor 134 and the capacitor 136 of the energy storage unit 130 when the switch 120 is on.

The supply of energy from the power supply unit 110 to the energy storage unit 130 is cut off and the energy stored in the energy storage unit 130 is supplied to the first lamp 140 and the second lamp 132, So that the first lamp 140 and the second lamp 132 are driven to emit light energy. The energy stored in the inductor 134 in the energy storage unit 130 is transferred to the second lamp 132 to drive the second lamp 132 and stored in the capacitor 136 in the energy storage unit 130 The energy is transferred to the first lamp 140 and the first lamp 140 is driven. The control signal is held at the high level signal H for a predetermined time or more and the opening / closing operation (on / off operation) of the switch is repeated so that the current flowing through the first lamp 140 reaches the normal state. The first lamp 140 is driven.

During the time interval t2 when the control signal is the low level signal L, the switch 120 can be controlled to maintain the OFF state. As described above, when the voltage of the power supply unit 110, the inductor 134 and the capacitor 136 in the energy storage unit 130 are fixed, the high level signal H and the low level signal L in the control signal, The brightness of the first lamp 140 and the brightness of the second lamp 132 can be adjusted together by adjusting the time ratio t1: t2 of the first lamp 140 and the second lamp 132, respectively.

2B shows a state in which the current I ₁ flowing through the first lamp 140 reaches a steady state during a time period in which the control signal is a high level signal in the multi-channel LED lamp brightness control circuit 100, 1 shows a waveform 220 of a current I _L flowing. As shown, the current I _L flowing in the inductor 134 changes as the switch 120 is turned on / off at a constant cycle. The current I _L flowing in the inductor 134 increases with a constant slope during the time interval I during which the switch 120 is on and decreases with a constant slope during the time interval II during which the switch 120 is off . The slope may be determined by the value of the inductor 132 in the energy storage unit 130 or the ratio of the voltage of the power supply unit 110 and the voltage across the capacitor 136 in the energy storage unit 130. [

Here, the ratio of the brightness of the first lamp 140 to the brightness of the second lamp 132 is set such that the area (I + II) during the time interval in which the switch 120 is on and the interval during which the switch 120 is off, Is determined by the ratio of the area (II) over the time interval. This is because the direct current of the average value of the inductor current I _L flows to the first lamp 140 by the rectifying action of the capacitor 136 and the second lamp 132 is supplied with the inductor (I _L ) flowing through the resistor 134 flows. Thus, according to FIG. 2A, the ratio of the brightness of the first lamp 140 to the brightness of the second lamp 132 is about 2: 1. The brightness of the first lamp 140 is determined by the duty ratio of the high level signal and the low level signal in the control signal so that the brightness of the second lamp 132 is controlled by the brightness of the first lamp 140, The brightness corresponding to half of the brightness.

2C is a diagram showing a waveform 230 when the current I ₁ flowing through the first lamp 140 reaches a steady state. As described above, the current I ₁ flowing through the first lamp 140 is a direct current having an average value of the inductor current I _{L due} to the rectifying action of the capacitor 136.

2D shows a waveform 240 of the current I ₂ flowing through the second lamp 132 when the inductor current I _L is the same as the waveform 210 of FIG. 2A. As described above, only the current I _L flowing in the inductor 134 flows during the time interval during which the switch 120 is off, and no current flows during the time period during which the switch 120 is on, in the second ramp 132. Thus, the ratio of the brightness of the first lamp 140 to the brightness of the second lamp 132 is determined by the ratio of the area of the waveform 230 shown in FIG. 2C to the area of the waveform 240 shown in FIG. 2D, The brightness of the second lamp is weaker than the brightness of the first lamp.

FIG. 3 is a diagram illustrating a multi-channel LED lamp brightness control circuit 300 according to a second embodiment of the present invention. In the case of this embodiment, the configuration except for the connector 310 is the same as the multi-channel LED lamp brightness control circuit 100 shown in FIG. The driving unit 320 including the power supply unit 110, the switch 120, the energy storage unit 130 and the control unit 150 drives the first lamp 140 and the second lamp 140 through the connector 310, And a lamp unit 330 including a lamp unit 132. The first lamp 140 of the lamp unit 330 is coupled to the energy storage unit 130 and the control unit 150 of the driving unit 320 through the connector 310 and the second lamp 132 is coupled to the connector 310, And is coupled between the switch 120 of the driving unit 320 and the energy storage unit 130 through the switch unit 120. [ Here, the second lamp 132 may transmit energy from the power supply unit 110 to the energy storage unit 130, and may be mounted in a separate module from the driving unit 330.

The first lamp 140 is coupled to the inductor 134 and the capacitor 136 via the connector 310 when the energy storage unit 130 includes the inductor 134 and the capacitor 136 connected in series, A second ramp may be coupled to one end of the inductor 134 and the switch 120. Channel LED lamp brightness control circuit 300 and the first lamp 140 and the second lamp 132 that emit light energy by separating the driving unit 320 and the lamp unit 330 using the connector 310, It is possible to arrange them separately from the rest of the components. The operation of the multi-channel LED lamp brightness control circuit 300 is the same as that of the multi-channel LED lamp brightness control circuit 100 described with reference to FIGS. 1 to 2D.

4 is an exemplary diagram for explaining a change in brightness of the first and second lamps 140 and 132 according to a change in a control signal in the multi-channel LED lamp brightness control circuits 100 and 300. Referring to FIG. The relative brightness of the second lamp 132 with respect to the first lamp 140 is determined by the value of the inductor 132 in the energy storage unit 130 or the voltage of the power supply unit 110, Can be determined by the ratio of the voltage across the capacitor 136. 4 is a graph illustrating the relationship between the voltage of the power supply unit 110 and the value of the inductor 132 and the value of the capacitor 136 of the energy storage unit 130 so that the brightness of the first lamp 140 is twice the brightness of the second lamp 132 Is an example of a fixed case.

In this case, the brightness of the first lamp 140 and the second lamp 132 is controlled according to the time ratio (duty ratio) of the high level signal and the low level signal in the control signal. The brightness of the first lamp 140 is 60% of the maximum brightness when the time ratio of the high level signal H and the low level signal L in the control signal is 6 to 4 as shown in FIG. 4 (a) 2 lamp 132 becomes half of the first lamp 140 and becomes 30% of the maximum brightness. 4 (b), the brightness of the first lamp 140 becomes the maximum brightness (100%), and the brightness of the second lamp 132 becomes the brightness of the first lamp 140 140), which is 50% of the maximum brightness.

As described above, the multi-channel LED lamp brightness control circuits 100 and 300 according to the present invention use two LED lamps, i.e., the first lamp 140 and the second lamp 132, You can control with different brightness. The multi-channel LED lamp brightness control circuits 100 and 300 may be used to control two LED lamps having different brightnesses of an automobile tail lamp, for example, using one driving circuit. In this case, FIG. 4 (a) shows a control signal for controlling the brightness of two different LED lamps in the tail lamp when the vehicle is running, and FIG. 4 (b) And a control signal for controlling the brightness of the other two LED lamps.

5 is a diagram illustrating a multi-channel LED lamp brightness control circuit 500 according to a third embodiment of the present invention. The multi-channel LED lamp brightness control circuit 500 may include an energy storage unit 520 coupled to the power supply unit 510 and a second lamp 522 coupled to the front end of the energy storage unit 520 in parallel. have. The second lamp 522 enables transfer of energy from the power source unit 510 to the energy storage unit 520 while the energy storage unit 520 and the second lamp 522 can transfer energy from the power source unit 510 to the first To the lamp (530). In this process, the energy storing unit 520 may repeat the operation of charging the energy from the power source unit 510 and discharging the charged energy, and the second lamp 522 may emit light energy. The second lamp 522 may include at least one LED.

In one embodiment, the energy storage 520 may include a capacitor 524 and an inductor 526. [ In this case, the second ramp 522 may be coupled in parallel with the capacitor 524 and the inductor 526 connected in series. In this configuration, the energy transferred from the power source unit 510 to the energy storage unit 520 may be stored in the capacitor 524 and the inductor 526.

The illustrated multi-channel LED lamp brightness control circuit 500 may further include a first lamp 530 coupled to the energy storage unit 520. When the energy storage unit 520 includes the capacitor 524 and the inductor 526, the first lamp 530 may be coupled in parallel with the capacitor 524 and the energy stored in the energy storage unit 520 And can emit light energy. In one embodiment, the first lamp 530 may include at least one LED, and may be the same or different from the second lamp 522.

The multi-channel LED lamp brightness control circuit 500 may further include a control unit 540 coupled to the energy storage unit 520 and the second lamp 522. The control unit 540 controls the operation of transferring energy from the power source unit 510 to the energy storage unit 520 in response to the control signal and the operation of transferring energy stored in the energy storage unit 520 between the first lamp 530 and the second lamp 530. [ 522 of the first lamp 530 and the second lamp 522. In this way, the operation of the first lamp 530 and the second lamp 522 can be controlled.

In one embodiment, the control signal may be a spherical file having a constant period. In this case, the square wave may comprise a series of high level signals and a series of low level signals alternating with the series of high level signals. Here, the brightness of the first lamp 530 can be adjusted by adjusting the time ratio (duty ratio) of the high level signal and the low level signal in the control signal. The brightness of the second ramp 522 is less than the brightness of the first ramp 530 and the brightness of the second ramp 522 relative to the first ramp 530 is less than the brightness of the inductor 526 value in the energy store 520 Or the ratio of the voltage across the power supply 510 to the voltage across the capacitor 524 in the energy storage 520.

As the ratio of the high level signal increases, the brightness of the first ramp 530 increases. Conversely, as the ratio of the high level signal decreases, the brightness of the first ramp 530 decreases. Accordingly, when the voltage of the power source unit 510, the capacitor 524 and the inductor 526 in the energy storage unit 520 are fixed, the time ratio (duty ratio) of the high level signal and the low level signal in the control signal is adjusted The brightness of the first lamp 530 and the brightness of the second lamp 522 can be adjusted together.

In one embodiment, the controller 540 may include a transistor. In this case, although not shown, the controller 540 may include a square wave voltage generator for generating a square wave voltage to be applied to the gate of the transistor in response to the high level signal of the control signal. The square wave voltage may include alternating low and high voltages at regular intervals. When the control signal is a low level signal, a low voltage may be applied to the gate of the transistor.

Transferring energy from the power source unit 510 to the energy storage unit 520 in response to the gate voltage of the transistor and transferring the energy stored in the energy storage unit 520 to the first ramp 530 and the second ramp 522 Is controlled. When the voltage applied to the gate of the transistor is a high voltage, energy is supplied from the power supply unit 510 to the energy storage unit 520 and energy is stored in the energy storage unit 520. When the voltage applied to the gate of the transistor is low voltage The supply of energy from the power source unit 510 to the energy storage unit 520 is interrupted so that the energy stored in the energy storage unit 520 is transferred to the first lamp 530 and the second lamp 522, And the second ramp 522 are driven.

The energy stored in the inductor 526 in the energy storage unit 520 is transferred to the second lamp 522 to drive the second lamp 522 and stored in the capacitor 526 in the energy storage unit 520 The energy is transferred to the first lamp 530 and the first lamp 530 is driven. The control signal is maintained as a high level signal for a predetermined time and the high voltage and low voltage are repeatedly applied to the gate of the transistor so that the current flowing through the first lamp 530 reaches a steady state. In this case, the first ramp 530 is driven even when the voltage applied to the gate of the transistor is a high voltage. The current I _L flowing in the inductor 526 after the current flowing through the first lamp 530 reaches the steady state during the time period in which the control signal is the high level signal in the multi-channel LED lamp brightness control circuit 500, The current I ₁ flowing through the first ramp 530 and the current I ₂ flowing through the second ramp 522 are the same as those shown in FIGS. 2B through 2C.

6 is a diagram illustrating a multi-channel LED lamp brightness control circuit 600 according to a fourth embodiment of the present invention. In the case of this embodiment, the configuration excluding the connector 610 is the same as the multi-channel LED lamp brightness control circuit 500 shown in Fig. The driving unit 620 including the power unit 510, the energy storage unit 520 and the control unit 540 includes the first lamp 530 and the second lamp 522 through the connector 610 And the lamp unit 630 is connected to the lamp unit 630. The first lamp 530 of the lamp unit 630 is coupled to the energy storage unit 520 of the driving unit 620 through the connector 610 and the second lamp 522 is coupled to the driving unit 320 And the energy storage unit 520. The energy storage unit 520 is connected to the power supply unit 510 of FIG. Here, the second lamp 522 may transfer energy from the power source unit 510 to the energy storage unit 520, and may be mounted in a separate module from the driving unit 620.

When the energy storage unit 520 includes a capacitor 524 and an inductor 526 connected in series, the first lamp 530 is coupled in parallel with the capacitor 524 via the connector 610, May be coupled in parallel to capacitor 524 and inductor 526, which are connected in series via connector 610. The first lamp 530 and the second lamp 522 that emit light energy are separated from the multi-channel LED lamp brightness control circuit 500 by separating the driving unit 620 and the lamp unit 630 using the connector 610. [ It is possible to arrange them separately from the rest of the components. The operation of the multi-channel LED lamp brightness control circuit 600 is the same as that of the multi-channel LED lamp brightness control circuit 500 described with reference to FIG.

FIG. 7 is a diagram illustrating a circuit 700 for simulating the multi-channel LED lamp brightness control circuit 500 of the present invention shown in FIG. As shown in the figure, the power supply unit 510 is a DC voltage source of 200 V, and the capacitor 524 and the inductor 526 of the energy storage unit 520 are 10 V and 470 μH, respectively. Also, the first lamp 530 includes 24 LEDs connected in series, and the second lamp 522 is configured similarly to the first lamp 530. In this simulation, a PWM control signal is used as a signal for controlling the control unit 540, and the control signal is set to include only a high level signal.

8 is a diagram showing a simulation result of the circuit 700 shown in Fig. As shown in Fig. 8 (a), the control signal includes only a high level signal of about 5 V. 8 (b) shows the voltage applied to the transistor gate in the control unit 540. FIG. Since the control signal includes only a high-level signal, a square wave including a high voltage (9 V) and a low voltage (0 V) alternating with a certain period is applied to the transistor gate.

FIG. 8 (c) shows the current I _L flowing in the inductor 526 in the energy storage unit 520. As shown, the current I _L flowing in the inductor 526 changes as the high and low voltages are applied to the gate at regular intervals. Specifically, the current I _L flowing in the inductor 526 increases with a constant slope during a time period in which the gate voltage is high, and decreases with a constant slope during a time period during which the gate voltage is low.

8 (d) shows the current I ₁ flowing through the first ramp 530 and FIG. 8 (e) shows the current I ₂ flowing through the second ramp 522. As shown in the figure, a direct current (about 800 mA) of the average value of the current I _L flowing in the inductor 526 flows through the first lamp 530 due to the rectifying action of the capacitor 524, 522, only the current I _L flowing in the inductor 522 flows during a time period in which the gate voltage is low. Therefore, the ratio of the brightness of the first lamp 530 to that of the second lamp 522 is determined by the ratio of the areas of the waveforms shown in Figs. 8D and 8E. As a result of the above-described simulation, it can be seen that the multi-channel LED lamp brightness control circuit according to the present invention can drive two LED lamps with different brightness even if only one driving circuit is used. With this configuration, it is possible to reduce the circuit area required for driving the two LED lamps at different brightnesses, and reduce the component cost.

100: Multi-channel LED lamp brightness control circuit
110:
120: Switch
130: Energy storage unit
132: second lamp
134: inductor
136: Capacitor
140: first lamp
150:
310: connector
320:
330:

Claims (22)

A lamp brightness control circuit comprising:
A driving unit including a switch, an energy storage unit, and a control unit;
And a lamp unit coupled to the energy storage unit and including a first lamp and a second lamp,
The energy storage unit receives energy from a power source unit by an opening and closing operation of the switch,
Wherein the control unit controls the open / close operation of the switch so that the energy supplied from the power supply unit is transferred to and stored in the energy storage unit and the stored energy is transferred to the first lamp and the second lamp in response to the control signal The lamp brightness control circuit. The method according to claim 1,
Wherein the second lamp is capable of transferring energy from the power source unit to the energy storage unit and is mounted on a separate module from the driving unit. The method according to claim 1,
Wherein the control signal is a square wave comprising a series of first voltage level signals and a series of second voltage level signals alternating with the series of first voltage level signals. 4. The lamp brightness control circuit according to claim 3, wherein the brightness of the first lamp is determined by a time ratio of the first voltage level signal and the second voltage level signal of the control signal. The method according to claim 1,
Wherein the energy storage unit includes an inductor and a capacitor connected in series,
One end of the inductor is coupled to the switch and the second lamp,
And the other end of the inductor is coupled to the capacitor and the first lamp,
Lamp brightness control circuit. 6. The lamp brightness control circuit of claim 5, wherein the relative brightness of the second ramp to the first ramp is determined by the inductor value. 6. The lamp brightness control circuit according to claim 5, wherein a relative brightness of the second lamp with respect to the first lamp is determined by a ratio of a voltage of the power supply unit and a voltage applied to the capacitor. 2. The lamp brightness control circuit according to claim 1, wherein the brightness of the second lamp is weaker than the brightness of the first lamp. The lamp brightness control circuit according to claim 1, wherein the driving unit and the lamp unit are connected through a connector. 10. The lamp brightness control circuit of claim 9, wherein the first lamp is coupled to the energy storage via the connector. 10. The lamp brightness control circuit of claim 9, wherein the second lamp is coupled between the switch and the energy storage via the connector. A lamp brightness control circuit comprising:
A driving unit including an energy storage unit and a control unit coupled to the power supply unit;
And a lamp unit coupled to the energy storage unit and including a first lamp and a second lamp,
The second lamp is coupled to the power supply,
Wherein the control unit is configured to alternately control an operation in which energy supplied from the power source unit is stored in the energy storage unit and an operation in which the stored energy is transferred to the first lamp and the second lamp, Lamp brightness control circuit. 13. The method of claim 12,
Wherein the second lamp is capable of transferring energy from the power source unit to the energy storage unit and is mounted on a separate module from the driving unit. 13. The method of claim 12,
Wherein the control signal is a square wave comprising a series of first voltage level signals and a series of second voltage level signals alternating with the series of first voltage level signals. 15. The lamp brightness control circuit of claim 14, wherein the brightness of the first ramp is determined by a time ratio of the first voltage level signal and the second voltage level signal of the control signal. 13. The method of claim 12,
Wherein the energy storage unit includes an inductor and a capacitor,
Wherein the inductor and the capacitor are connected in series and coupled in parallel with the second lamp,
Wherein the first ramp is coupled in parallel with the capacitor,
Lamp brightness control circuit. 17. The lamp brightness control circuit of claim 16, wherein the relative brightness of the second ramp to the first ramp is determined by the inductor value. 17. The lamp brightness control circuit according to claim 16, wherein a relative brightness of the second lamp with respect to the first lamp is determined by a ratio of a voltage of the power supply unit to a voltage applied to the capacitor. 13. The lamp brightness control circuit according to claim 12, wherein the brightness of the second lamp is weaker than the brightness of the first lamp. 13. The lamp brightness control circuit according to claim 12, wherein the driving unit and the lamp unit are connected through a connector. 21. The lamp brightness control circuit of claim 20, wherein the first lamp is coupled to the energy storage via the connector. 21. The lamp brightness control circuit of claim 20, wherein the second lamp is coupled between the power supply and the energy storage via the connector.

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