CN104640300A - Light source drive circuit, color temperature controller and method for controlling light source color temperature - Google Patents

Abstract

The invention discloses a light source drive circuit, a color temperature controller and a method for controlling light source color temperature. The light source drive circuit for driving a light source with adjustable color temperature comprises an electric power converter coupled between a power supply and the light source and the color temperature controller coupled to the electric power converter, wherein the electric power converter is used for receiving electric energy from the power supply and providing the adjusted electric energy to the light source; the color temperature controller is used for receiving a switch monitoring signal for instructing the operation of a power switch coupled between the power supply and the electric power converter and adjusting the color temperature of the light source on the basis of the switch monitoring signal. The light source drive circuit has the advantages that light source color temperature adjusting is achieved by operating the power switch, extra special devices are not needed, simpleness and convenience are achieved, and cost is saved.

Description

The method of light source driving circuit, color-temperature controller and control light source color temperature

Technical field

The present invention relates to light source field, particularly relate to a kind of method of light source driving circuit, color-temperature controller and control light source color temperature.

Background technology

In recent years, the new type light source such as light-emitting diode (light-emitting diode, LED) is at material with manufacture and all achieve progress.The features such as LED has high efficiency, the long-life, bright-colored, can be applied to automobile, computer, communication, the fields such as military affairs and commodity.Such as, LED can substitute traditional incandescent lamp as lighting source.

Figure 1 shows that a kind of schematic diagram of traditional LED drive circuit 100.LED drive circuit 100 utilizes LED chain 106 as light source.LED chain 106 comprises the LED of multiple series connection.Electric power converter 102 is used for powering to LED chain 106 for VD Vout DC input voitage Vin being converted to expectation.LED chain 106 can be communicated with input voltage vin or disconnect thus open or close LED by the switch 104 be connected with LED drive circuit 100.Electric power converter 102 receives the feedback signal from current sense resistance Rsen and regulation output voltage Vout produces to make LED chain 106 brightness expected.One of shortcoming of this traditional scheme is, this expectation brightness is pre-set, and in use, user cannot regulate brightness.

Figure 2 shows that the schematic diagram of another kind of traditional LED drive circuit 200.Electric power converter 102 is used for powering to LED chain 106 for VD Vout DC input voitage Vin being converted to expectation.LED chain 106 can be communicated with input voltage vin or disconnect thus open or close LED by the switch 104 be connected with LED drive circuit 100.LED chain 106 is connected with linear current regulators 208.Operational amplifier 210 comparison reference signal REF in linear current regulators 208 and the current monitor signal from current sense resistance Rsen, and produce control signal, regulate the resistance of transistor Q1 in a linear fashion, thus the electric current flowing through LED chain 106 can be regulated accordingly.Apply this traditional scheme, be the light output of control LED chain 106, user needs to utilize certain dedicated devices, and such as one custom-designed has the switch regulating button or the switch that can receive remote signal, regulates reference signal REF.

Summary of the invention

The technical problem to be solved in the present invention is to provide a kind of light source driving circuit, color-temperature controller and controls the method for light source color temperature, the adjustment that can realize light source color temperature in simple and convenient mode.

The invention provides a kind of light source driving circuit, this light source driving circuit has the light source of adjustable color temperature for driving, described light source driving circuit comprises: electric power converter, be coupling between power supply and described light source, for receiving electric energy from described power supply and providing the electric energy after adjustment to described light source; And color-temperature controller, be coupled in described electric power converter, be coupling in the switch monitors signal of the operation of the mains switch between described power supply and described electric power converter for receiving instruction, and adjust the colour temperature of described light source based on described switch monitors signal.

Invention further provides a kind of color-temperature controller, this color-temperature controller comprises: driver element, flows through the current monitor signal of the current value of light source for receiving instruction and produces drive singal according to described current monitor signal and control electric power converter and provide the electric energy after adjustment to light source; And control unit, be coupled in described driver element, for receiving the switch monitors signal of the operation of the mains switch in instruction former limit circuit and based on the colour temperature of the described light source in described switch monitors signal adjustment secondary circuit, wherein said mains switch is coupling between described power supply and described electric power converter.

The present invention also provides a kind of method controlling light source color temperature, and the method comprises: receive electric energy from power supply and provide the electric energy after adjustment by electric power converter to described light source; Receive the switch monitors signal that instruction is coupling in the operation of the mains switch between described power supply and described electric power converter; And the colour temperature of described light source is adjusted based on described switch monitors signal.

Compared with prior art, light source driving circuit of the present invention, color-temperature controller and control the method for light source color temperature can by realizing the adjustment to light source color temperature to the operation of mains switch, without the need to using extra dedicated devices, simple and convenient and provide cost savings.

Accompanying drawing explanation

Below by way of to the description of some embodiments of the present invention in conjunction with its accompanying drawing, object of the present invention, specific structural features and advantage can be understood further.

Figure 1 shows that a kind of circuit diagram of traditional LED drive circuit;

Figure 2 shows that the circuit diagram of another kind of traditional LED drive circuit;

Figure 3 shows that the schematic diagram of the light source driving circuit according to the embodiment of the present invention;

Figure 4 shows that the circuit diagram of the light source driving circuit according to the embodiment of the present invention;

Figure 5 shows that the structural representation of the light adjusting controller in Fig. 4;

Figure 6 shows that the signal waveform schematic diagram under analog dimming mode;

Figure 7 shows that the signal waveform schematic diagram under pulse light modulation pattern;

Figure 8 shows that the function mode schematic diagram of the light source driving circuit according to the embodiment of the present invention, this light source driving circuit includes the light adjusting controller shown in Fig. 5;

Figure 9 shows that method flow diagram light source being carried out to controlling electric energy according to the embodiment of the present invention;

Figure 10 shows that the circuit diagram of the light source driving circuit according to the embodiment of the present invention;

Figure 11 shows that the structural representation of the light adjusting controller in Figure 10;

Figure 12 shows that the function mode schematic diagram of the light source driving circuit according to the embodiment of the present invention, this light source driving circuit includes the light adjusting controller shown in Figure 11;

Figure 13 shows that method flow diagram light source being carried out to controlling electric energy according to the embodiment of the present invention;

Figure 14 A is depicted as the circuit diagram of light source driving circuit according to an embodiment of the invention;

The schematic diagram of an embodiment of the mains switch in Figure 14 A shown in Figure 14 B;

Figure 15 shows that the structural representation of the light adjusting controller in Figure 14 A according to an embodiment of the invention;

Figure 16 shows that the signal schematic representation of the light source driving circuit of the light adjusting controller comprised according to an embodiment of the invention in Figure 15;

Figure 17 shows that another signal schematic representation of the light source driving circuit of the light adjusting controller comprised according to an embodiment of the invention in Figure 15;

Figure 18 shows that the method flow diagram of the light modulation controlling LED light source according to an embodiment of the invention;

Figure 19 shows that the circuit diagram of light source driving circuit according to an embodiment of the invention;

Figure 20 shows that the structural representation of the light adjusting controller in Figure 19 according to an embodiment of the invention;

Figure 21 is depicted as the signal schematic representation of the light source driving circuit of the light adjusting controller comprised according to an embodiment of the invention in Figure 19;

Figure 22 is depicted as the method flow diagram of the light modulation controlling LED light source according to an embodiment of the invention;

Figure 23 A is depicted as the block diagram of the light source driving circuit according to the embodiment of the present invention;

Figure 23 B is depicted as the circuit diagram of the light source driving circuit according to the embodiment of the present invention;

Figure 24 is depicted as the structural representation of the color-temperature controller in Figure 23 B;

Figure 25 is depicted as the signal waveforms comprising the light source driving circuit of the color-temperature controller shown in Figure 24 according to the embodiment of the present invention;

Figure 26 is depicted as the signal waveforms of the light source driving circuit comprising the color-temperature controller shown in Figure 24 according to another embodiment of the present invention; And

Figure 27 is depicted as the method flow diagram of the control light source color temperature according to the embodiment of the present invention.

Embodiment

Detailed reference is provided below by embodiments of the invention.Although the present invention is undertaken setting forth and illustrating by these execution modes, it should be noted that the present invention is not merely confined to these execution modes.On the contrary, all substitutes, variant and the equivalent in invention spirit and invention scope that claims define is contained in the present invention.

In addition, in order to better the present invention is described, in embodiment hereafter, give numerous details.It will be understood by those skilled in the art that do not have these details, the present invention can implement equally.In other example, known method, formality, element and circuit are not described in detail, so that highlight purport of the present invention.

Figure 3 shows that the schematic diagram of light source driving circuit 300 according to an embodiment of the invention.In one embodiment, mains switch 304 is coupled between power supply Vin and light source driving circuit 300, for being selectively connected with power supply Vin by light source driving circuit 300.Light source driving circuit 300 comprises the AC/DC converter 306 for the AC-input voltage Vin from power supply being converted to VD Vout, be connected with AC/DC converter 306 for provide for LED chain 312 regulate after the electric power converter 310 of electric energy, be connected with electric power converter 310 for receiving the switch monitors signal indicating mains switch 304 action and the light adjusting controller 308 exported according to this switch monitors signal controlling electric power converter 310, and for the current monitor 314 of monitoring stream through the electric current of LED chain 312.In one embodiment, mains switch 304 is the mains switches be placed on metope.

In operation, input ac voltage Vin is converted to VD Vout by AC/DC converter 306.Electric power converter 310 receives direct voltage Vout and provides the voltage after adjustment for LED chain 312.Current monitor 314 generation current monitor signal, the instruction of this current monitor signal flows through the size of the electric current of LED chain 312.Light adjusting controller 308 monitors the action of mains switch 304, receives the current monitor signal from current monitor 314, and according to the action control electric power converter 310 of mains switch 304 to regulate the electric energy of LED chain 312.In one embodiment, light adjusting controller 308 works in analog dimming mode, determines that the reference signal of LED current peak value regulates the electric energy of LED chain 312 by regulating one.In another embodiment, light adjusting controller 308 works in pulse light modulation (burst dimming) pattern, by the electric energy regulating the duty ratio of a pulse width modulating signal (pwm signal) to regulate LED chain 312.By regulating the electric energy of LED chain 312, the brightness of LED chain 312 can be regulated accordingly.

Figure 4 shows that the circuit diagram of light source driving circuit 400 according to an embodiment of the invention.Composition graphs 3 is described by Fig. 4.Number identical parts in Fig. 4 with Fig. 3 and there is similar function, do not do repeated description at this for simplicity's sake.

Light source driving circuit 400 comprises the electric power converter 310 be connected between power supply and LED chain 312, for receiving electric energy from power supply and providing the electric energy after adjustment for LED chain 312.In the fig. 4 embodiment, electric power converter 310 comprises inductance L 1, the step-down controller of diode D4 and control switch Q16.In embodiment in Fig. 4, control switch Q16 is positioned at the outside of light adjusting controller 308.In other examples, control switch Q16 also can be integrated in the inside of light adjusting controller 308.

Light adjusting controller 308 receiving key monitor signal the switch Q16 connected with LED chain 312 according to this switch monitors signal controlling, to regulate electric power converter 310(to comprise inductance L 1, diode D4 and control switch Q16) electric energy after the adjustment that exports.The action of this switch monitors signal designation mains switch (as the mains switch 304 be connected between power supply and light source driving circuit).Light source driving circuit 400 comprises AC/DC converter 306 further, for converting AC-input voltage Vin to VD Vout.Light source driving circuit 400 also comprises current monitor 314, for the electric current of monitoring stream through LED chain 312.In the embodiment shown in fig. 4, AC/DC converter 306 comprises diode D1, diode D2, diode D7, diode D8, the bridge rectifier of diode D10 and electric capacity C9.Current monitor 314 comprises current sense resistance R5.

In one embodiment, the port of light adjusting controller 308 comprises: HV_GATE, SEL, CLK, RT, VDD, CTRL, MON and GND.Port HV_GATE is connected with switch Q27 by resistance R3, for controlling the conduction state (state as turned on/off) of the switch Q27 be connected with LED chain 312.Electric capacity C11 is connected between port HV_GATE and ground, for adjusting the grid voltage of switch Q27.

When reality uses, user can select port SEL to be connected to ground by resistance R4, as shown in Figure 4, or port SEL is directly connected to ground, correspondingly can selects analog dimming mode or pulse light modulation pattern.

Port CLK is connected to AC/DC converter 306 by resistance R3, is connected to ground by resistance R6 simultaneously.Port CLK receives a switch monitors signal, the action of this switch monitors signal designation mains switch 304.In one embodiment, the node of switch monitors signal between resistance R3 and resistance R6 produces.Electric capacity C12 is in parallel with resistance R6, for the noise that filtering is unnecessary.Port RT is connected to the ground by resistance R7, for determining the frequency of the pulse signal produced by light adjusting controller 308.

Port VDD is connected with switch Q27, for powering for light adjusting controller 308 by diode D9.In one embodiment, an energy-storage units, as electric capacity C10, is connected between port VDD and ground, is that light adjusting controller 308 is powered when mains switch 304 disconnects.In another embodiment, energy-storage units can also be integrated in light adjusting controller 308 inside.Port GND is connected to the ground.

Port CTRL is connected with switch Q16.Switch Q16 connects with LED chain 312 and switch Q27, and is connected to ground by current monitoring resistance R5.Light adjusting controller 308 conduction state of control signal control switch Q16 by exporting on port CTRL, to adjust the electric energy after adjustment that electric power converter 310 exports.Port MON is connected with current monitoring resistance R5, flows through the current monitor signal of the electric current of LED chain 312 for receiving instruction.When switch Q27 connects, light adjusting controller 308 regulates the electric current flowing through LED chain 312 by control switch Q16.

In operation, when mains switch 304 is connected, the alternating voltage Vin of input is converted to VD Vout by AC/DC converter 306.Voltage port HV_GATE with preset voltage value is put on switch Q27 by resistance R3, thus turn on-switch Q27.

If light adjusting controller 308 turn on-switch Q16, direct voltage Vout can power to LED chain 312 and charge to inductance L 1.Electric current flows through inductance L 1, LED chain 312, switch Q27, switch Q16 and resistance R5 to ground.If light adjusting controller 308 cut-off switch Q16, then electric current flows through inductance L 1, LED chain 312 and diode D4.Inductance L 1 discharges to power to LED chain 312.Therefore, light adjusting controller 308 can pass through control switch Q16, the electric energy after the adjustment that adjustment electric power converter 310 exports.

When mains switch 304 disconnects, electric capacity C10 electric discharge thinks that light adjusting controller 308 is powered.The voltage drop at resistance R6 two ends is to 0, thus light adjusting controller 308 can monitor the switch monitors signal of instruction mains switch 304 opening operation on port CLK.Similar, when mains switch 304 is connected, the voltage at resistance R6 two ends rises to a preset voltage value, thus light adjusting controller 308 can monitor the switch monitors signal of instruction mains switch 304 making operation on port CLK.If monitor opening operation, light adjusting controller 308 can pull down to the voltage on port HV_GATE 0 with cut-off switch Q27, thus after inductance L 1 is thoroughly discharged, LED chain 312 is de-energized.After monitoring the opening operation of mains switch 304, light adjusting controller 308 regulates a reference signal, the expectation brightness of this reference signal indication LED chain 312.When mains switch 304 connection next time, the brightness of LED chain 312 can adjust according to the expectation brightness after adjustment.In other words, the output brightness of LED chain 312 can be adjusted by the opening operation of light adjusting controller 308 according to mains switch 304.

Figure 5 shows that the structural representation of the light adjusting controller 308 in Fig. 4.Composition graphs 4 is described by Fig. 5.Number identical parts in Fig. 5 with Fig. 4 and there is similar function, do not do repeated description at this for simplicity's sake.

Light adjusting controller 308 comprises triggering monitoring means 506, dimmer 502 and pulse signal maker 504.Trigger monitoring means 506 and be connected to ground by Zener diode ZD1.Trigger monitoring means 506 by port CLK receiving key monitor signal, the action of this switch monitors signal designation external power switch 304.When the action of external power switch 304 is monitored to, triggers monitoring means 506 and produce drive singal with actuation counter 526.Trigger the conduction state of monitoring means 506 also further control switch Q27.Dimmer 502 produces reference signal REF, regulates the electric energy of LED chain 312 in the mode simulating light modulation.Dimmer 502 also can produce control signal 538, is adjusted the electric energy of LED chain 312 by the duty ratio of adjusting pulsewidth modulation signal PWM1.Pulse signal maker 504 produces pulse signal for turn on-switch Q16.Light adjusting controller 308 also comprises the startup that is connected with port VDD and low pressure locks (UVL) circuit 508, for optionally starting one or more parts of light adjusting controller 308 inside according to different power levels.

In one embodiment, if the voltage on port VDD is higher than the first predeterminated voltage, then startup and low pressure lock-in circuit 508 will start parts all in light adjusting controller 308.When mains switch 304 disconnects, if the voltage on port VDD is lower than the second predeterminated voltage, start and low pressure lock-in circuit 508 by the miscellaneous part of closing in light adjusting controller 308 except triggering monitoring means 506 and dimmer 502 to save electric energy.If the voltage on port VDD is lower than the 3rd predeterminated voltage, closedown is triggered monitoring means 506 and dimmer 502 by startup and low pressure lock-in circuit 508.In one embodiment, the first predeterminated voltage is higher than the second predeterminated voltage, and the second predeterminated voltage is higher than the 3rd predeterminated voltage.Because light adjusting controller 308 can be powered through port VDD by electric capacity C10, even if so after mains switch 304 disconnection, triggering monitoring means 506 and dimmer 502 can also work a period of time.

In light adjusting controller 308, port SEL is connected with current source 532.User can select light-modulating mode by configured port SEL, such as, be directly connected to the ground by port SEL, or is connected to the ground by a resistance by port SEL.In one embodiment, light-modulating mode is decided by the voltage on measurement port SEL.If port SEL is directly connected to the ground, then the voltage on port SEL is similar to 0.One control circuit (not shown) can turn on-switch 540, cut-off switch 541 and switch 542, thus light adjusting controller 308 can work in analog dimming mode, and adjusts the electric energy of LED chain 312 by adjustment reference signal REF.In one embodiment, if port SEL by resistance R4 be connected to (shown in Fig. 4), and R4 has a default resistance, and the voltage so on port SEL is greater than 0.This control circuit cut-off switch 540, turn on-switch 541 and switch 542.Thus light adjusting controller 308 works in pulse light modulation pattern, and adjusted the electric energy of LED chain 312 by the duty ratio of adjustment pulse-width signal PWM1.In other words, by control switch 540, switch 541, the conduction state of switch 542, can select different light-modulating modes.And switch 540, switch 541, the conduction state of switch 542 is determined by the voltage on port SEL.

Pulse signal maker 504 is connected to ground by port RT and resistance R7, produces the pulse signal 536 being used for turn on-switch Q16.Pulse signal maker 504 can have different structures, is not limited to the structure shown in Fig. 5.

In pulse signal maker 504, the in-phase end of operational amplifier 510 receives predeterminated voltage V1, and therefore the backward end voltage of operational amplifier 510 is also V1.Electric current I _rTflow to ground by port RT and resistance R7.Flow through the electric current I of mos field effect transistor (MOSFET) 514 and mos field effect transistor 515 ₁with electric current I _rTthere is same size.Mos field effect transistor 514 and mos field effect transistor 512 form current mirror, therefore flow through the electric current I of mos field effect transistor 512 ₂also with electric current I _rTthere is identical size.The output of comparator 516 is connected with R input with the S input of set-reset flip-floop 520 respectively with the output of comparator 518.The backward end of comparator 516 receives predeterminated voltage V2.The in-phase end of comparator 518 receives predeterminated voltage V3.In one embodiment, V2 is greater than V3 and V3 is greater than 0.Electric capacity C4 is connected between mos field effect transistor 512 and ground, and one end is connected with the node between comparator 516 in-phase end and comparator 518 backward end.The Q output of set-reset flip-floop 520 is connected with switch Q15, is also connected with the S input of set-reset flip-floop 522 simultaneously.Switch Q15 is in parallel with electric capacity C4.The conduction state of switch Q15 is determined by the Q output of set-reset flip-floop 520.

The initial voltage at electric capacity C4 two ends is approximately 0, is less than V3.Therefore the R input of set-reset flip-floop 520 receives the digital signal 1 that comparator 518 exports.The Q output of set-reset flip-floop 520 is set to digital signaling zero, thus cut-off switch Q15.When switch Q15 disconnects, electric capacity C4 is in electric current I ₂effect under charge, therefore electric capacity C4 two ends voltage raise.When C4 both end voltage is greater than V2, the S input of set-reset flip-floop 520 receives the digital signal 1 of comparator 516 output.The Q output of set-reset flip-floop 520 is set to digital signal 1, thus turn on-switch Q15.When switch Q15 connects, electric capacity C4 is discharged by switch Q15, thus the voltage at two ends reduces.When the voltage drop at electric capacity C4 two ends is to V3, comparator 518 output digit signals 1, the Q output of set-reset flip-floop 520 is set to digital signaling zero, thus cut-off switch Q15.After this electric capacity C4 is in electric current I ₂effect under charge again.As previously mentioned, pulse signal maker 504 produces pulse signal 536 at the Q output of set-reset flip-floop 520, and this pulse signal 536 includes a series of pulse.Pulse signal 536 is transferred into the S input of set-reset flip-floop 522.

Trigger monitoring means 506 monitors mains switch 304 action by port CLK.If the action of mains switch 304 is monitored at port CLK, triggers monitoring means 506 and produce a drive singal with actuation counter 526.In one embodiment, when mains switch 304 is switched on, the voltage rise on port CLK, this voltage equals the voltage at resistance R6 two ends, as shown in Figure 4.When mains switch 304 is disconnected, the voltage drop on port CLK is to 0.Therefore, the switch monitors signal of mains switch 304 action is indicated can be monitored at port CLK.In one embodiment, when a disconnection action is monitored at port CLK, triggers monitoring means 506 and produce drive singal.

Trigger monitoring means 506 also by the conduction state of port HV_GATE control switch Q27.When mains switch 304 is switched on, the puncture voltage at Zener diode ZD1 two ends is applied to switch Q27 by resistance R3, thus turn on-switch Q27.Trigger monitoring means 506 and the voltage of port HV_GATE can be pulled down to 0 thus cut-off switch Q27.In one embodiment, when port CLK monitoring the disconnection action of mains switch 304, trigger monitoring means 506 cut-off switch Q27.When port CLK monitoring the ON Action of mains switch 304, trigger monitoring means 506 turn on-switch Q27.

In one embodiment, dimmer 502 comprises the counter 526 be connected with triggering monitoring means 506, for counting the action of mains switch 304.Dimmer 502 also comprises the digital to analog converter 528 be connected with counter 526, and the pulse width modulating signal generator 530 be connected with digital to analog converter 528.The drive singal that counter 526 is produced by triggering monitoring means 506 driven.Specifically, when mains switch 304 disconnects, trigger monitoring means 506 on port CLK, monitor a trailing edge, thus produce a drive singal.The count value of counter 526 increases progressively (such as adding 1) under the effect of this drive singal.Digital to analog converter 528 reads count value from counter 526, and produces dim signal (this dim signal can be control signal 538 or reference signal REF) according to count value.Dim signal can be used for adjusting the target energy value of electric power converter 310, thus the brightness of adjustment LED chain 312.

Under pulse light modulation pattern, switch 540 disconnects, and switch 541 and switch 542 are connected.The backward end of comparator 534 receives reference signal REF1.REF1 is the direct current signal with preset voltage value.The voltage of REF1 determines the current peak of LED chain 312, thus also determines the high-high brightness of LED chain 312.Under this pulse light modulation pattern, namely dim signal puts on the control signal 538 on pulse width modulating signal generator 530, and this control signal 538 can adjust the duty ratio of pulse-width signal PWM1.By adjusting the duty ratio of PWM1, the brightness of LED chain 312 is made to be equal to or less than the high-high brightness of REF1 decision.Such as, if the duty ratio of PWM1 is 100%, then LED chain 312 has high-high brightness.If the duty ratio of PWM1 is less than 100%, then the brightness of LED chain 312 is lower than high-high brightness.

Under analog dimming mode, switch 540 is connected, and switch 541 and switch 542 disconnect.Under this analog dimming mode, dim signal and reference signal REF.This reference signal REF is an analog signal, has adjustable voltage.Digital to analog converter 528 is according to the voltage of the count value adjustment REF of counter 526.The voltage of REF determines the current peak of LED chain 312, thus also determines the high-high brightness of LED chain 312.Therefore, can correspondingly be adjusted by the brightness of adjustment REF, LED chain 312.

In one embodiment, the count value increase of counter makes digital to analog converter 528 turn down the voltage of REF.Such as, if count value is 0, then digital to analog converter 528 adjusts the voltage of REF is V4.If trigger monitoring means 506 monitor the disconnection action of mains switch 304 at port CLK thus make count value be increased to 1, then digital to analog converter 528 adjusts the voltage of REF is V5, and V5 is less than V4.In another embodiment, the count value increase of counter makes digital to analog converter 528 heighten the voltage of REF.

In one embodiment, when the count value of counter 526 reaches maximum, count value is set to 0 again.If counter 526 is two digit counters, count value will be increased to 1,2,3 successively from 0, then after the 4th opening operation, get back to 0.Correspondingly, the brightness of LED chain 312 is adjusted to the second level from the first order, the third level, the fourth stage successively, then gets back to the first order again.

The backward end of comparator 534 can optionally receive reference signal REF or reference signal REF1.Under analog dimming mode, the backward end of comparator 534 receives reference signal REF by switch 540.Under pulse light modulation pattern, the backward end of comparator 534 receives reference signal REF1 by switch 541.The in-phase end of comparator 534 is connected with current monitoring resistance R5 by port MON, to receive the current monitor signal SEN from current monitoring resistance R5.The voltage representative of current monitor signal SEN flows through the size of current of LED chain 312 when switch Q27 and Q16 opens.

The output of comparator 534 is connected with the R input of set-reset flip-floop 522.The Q output of set-reset flip-floop 522 and being connected with door 524.The pulse width modulating signal PWM1 that pulse width modulating signal generator 530 produces is applied to and door 524.Control signal is exported, by port CTRL control Q16 with door 524.

If have selected analog dimming mode, switch 540 is connected, and switch 541 and 542 disconnects.Switch Q16 is controlled by set-reset flip-floop 522.When mains switch 304 is connected, the puncture voltage at Zener diode ZD1 two ends makes switch Q27 connect.Under the effect of the pulse signal 536 of pulse signal maker 504 generation, set-reset flip-floop 522 produces digital signal 1 at Q output, and switch Q16 is connected.Electric current flows through inductance L 1, LED chain 312, switch Q27, switch Q16, and current monitoring resistance R5 is to ground.Because inductance L 1 stops the saltus step of electric current, therefore this electric current can increase gradually.The voltage (i.e. the voltage of current monitor signal SEN) at current monitoring resistance R5 two ends can increase thereupon.When the voltage of SEN is greater than the voltage of reference signal REF, comparator 534 output digit signals 1 is to the R input of set-reset flip-floop 522, thus set-reset flip-floop 522 output digit signals 0, switch Q16 is disconnected.After switch Q16 disconnects, inductance L 1 discharges to power to LED chain 312.The electric current flowing through inductance L 1, LED chain 312 and diode D4 reduces gradually.When set-reset flip-floop 522 receives a pulse at S input, switch Q16 connects, and the electric current of LED chain 312 flows to ground by current monitoring resistance R5.When the voltage of current monitor signal SEN is greater than the voltage of reference signal REF, switch Q16 is disconnected by set-reset flip-floop 522 again.As mentioned above, reference signal REF determines the peak value flowing through LED chain 312 electric current, also namely determines the brightness of LED chain 312.Correspondingly adjusted by the brightness of adjustment REF, LED chain 312.

Under analog dimming mode, if mains switch 304 is disconnected, as shown in Figure 4, electric capacity C10 discharges to power to light adjusting controller 308.When triggering monitoring means 506 and monitoring the disconnection action of mains switch 304 at port CLK, the count value of counter 526 adds 1.The disconnection action of mains switch 304 makes to trigger monitoring means 506 cut-off switch Q27.The change of count value makes digital to analog converter 528 that the voltage of reference signal REF is adjusted to the second magnitude of voltage from the first magnitude of voltage.Therefore, when mains switch 304 is connected again, the brightness of LED chain 312 is adjusted because of the adjustment of reference signal REF.

If strobe pulse light-modulating mode, switch 540 disconnects, and switch 541 and switch 524 are connected.The backward end of comparator 534 receives the reference signal REF1 with preset voltage value.Switch Q16 by set-reset flip-floop 522 and pulse width modulating signal PWM1 by with door 524 co-controlling.Reference signal REF1 determines the peak current of LED chain 312, also namely determines the high-high brightness of LED chain 312.The duty ratio of pulse width modulating signal PWM1 determines the on/off time of switch Q16.When pulse width modulating signal PWM1 is digital signal 1, the conduction state of switch Q16 is determined by the output of the Q output of set-reset flip-floop 522.When pulse width modulating signal PWM1 is digital signaling zero, switch Q16 disconnects.By the duty ratio of adjustment pulse width modulating signal PWM1, the electric energy of LED chain 312 can be adjusted accordingly.Therefore, reference signal REF1 and pulse width modulating signal PWM1 determines the brightness of LED chain 312 jointly.

Under pulse light modulation pattern, when mains switch 304 disconnects, this opening operation monitors at the port CLK monitoring means 506 that is triggered.Trigger monitoring means 506 disconnect Q27 and produce drive singal.Under the effect of drive singal, the count value of counter 526 increases, such as, increase by 1.Digital to analog converter 528 produces control signal 538, makes the duty ratio of pulse width modulating signal PWM1 become the second level from the first order.Therefore, when mains switch 304 is connected again, the brightness of LED chain 312 will be that target adjusts with target brightness value.And this target brightness value is determined jointly by reference signal REF1 and pulse width modulating signal PWM1.

Figure 6 shows that the signal waveform schematic diagram under analog dimming mode.Comprising the electric current 602 flowing through LED chain 312, pulse signal 536, the output V522 of set-reset flip-floop 522, with the output V524 of door 524, and the ON/OFF state of switch Q16.Composition graphs 4 and Fig. 5 are described by Fig. 6.

Pulse signal maker 504 produces pulse signal 536.Under the effect of each pulse of pulse signal 536, set-reset flip-floop 522 produces digital signal 1 at Q output.And set-reset flip-floop 522 can make switch Q16 connect in Q output generation digital signal 1.When switch Q16 connects, inductance L 1 is charged, and electric current 602 increases.When electric current 602 reaches peak I max, when also namely the voltage of current monitor signal SEN is equal with the voltage of reference signal REF, the R input of comparator 534 output digit signals 1 to set-reset flip-floop 522, makes set-reset flip-floop 522 at Q output output digit signals 0.Set-reset flip-floop 522 can make switch Q16 disconnect at Q output output digit signals 0, and inductance L 1 electric discharge is powered for LED chain 312, and electric current 602 reduces.Under analog dimming mode, by adjustment reference signal REF, the average current value flowing through LED chain 312 is correspondingly adjusted, thus the brightness of LED chain 312 is also adjusted.

Figure 7 shows that the signal waveform schematic diagram under pulse light modulation pattern.Comprising the electric current 602 flowing through LED chain 312, pulse signal 536, the output V522 of set-reset flip-floop 522, with ON/OFF state and the pulse width modulating signal PWM1 of the output V524 of door 524, switch Q16.Composition graphs 4 and Fig. 5 are described by Fig. 7.

When PWM1 is digital signal 1, flow through the electric current 602 of LED chain 312, the correlation between the ON/OFF state of pulse signal 536, V522, V524 and switch Q16 is similar to Fig. 6.When PWM1 is digital signaling zero, become digital signaling zero with the output of door 524.Thus make switch Q16 disconnect and electric current 602 reduces.If PWM1 keeps the state long enough of digital signaling zero, electric current 602 can be reduced to 0.Under pulse light modulation pattern, by adjusting the duty ratio of PWM1, the average current value flowing through LED chain 312 is adjusted accordingly, thus the brightness of LED chain 312 is also adjusted.

Figure 8 shows that the function mode schematic diagram of light source driving circuit according to an embodiment of the invention.Composition graphs 5 is described by Fig. 8.

In the embodiment shown in fig. 8, whenever triggering monitoring means 506 monitors the disconnection action of mains switch 304, the count value of counter 526 will add 1.Counter 526 is two digit counters, and maximum count value is 3.

Under analog dimming mode, digital to analog converter 528 reads count value from counter 526.The increase of count value makes digital to analog converter 528 turn down the voltage of reference signal REF.The voltage of reference signal REF determines the peak I max of LED chain 312 electric current, also namely determines the mean value of LED chain 312 electric current.Under pulse light modulation pattern, digital to analog converter 528 reads count value from counter 526.The increase of count value makes digital to analog converter 528 turn down the duty ratio of pulse width modulating signal PWM1, such as, turn down 25% at every turn.Counter 526 is reaching maximum count value, such as, is reset after 3.

Figure 9 shows that the method flow diagram according to an embodiment of the invention light source being carried out to controlling electric energy.Composition graphs 4 and Fig. 5 are described by Fig. 9.

In step 902, electric power converter, such as electric power converter 310, the electric energy after the adjustment provided, to light source such as LED chain 312, is powered.

In step 904, receiving key monitor signal, such as, by light adjusting controller 308 receiving key monitor signal.The mains switch of this switch monitors signal designation between power supply and electric power converter, such as mains switch 304, action.

In step 906, produce dim signal according to switch monitors signal.

In step 908, control the switch of connecting with light source according to described dim signal, such as switch Q16, to adjust the electric energy after adjustment that electric power converter provides.Adopting in the embodiment of analog dimming mode at one, adjusting electric power converter by comparing dim signal with the current monitor signal representing source current size.Adopt in the embodiment of pulse light modulation pattern at another, adjust electric power converter by the duty ratio controlling a pulse width modulating signal with described dim signal.

As previously mentioned, the present invention discloses a kind of light source driving circuit, this light source driving circuit is according to instruction mains switch such as fixing mains switch on the wall, and the switch monitors signal of action adjusts the electric energy of light source.The electric energy of this light source is provided by electric power converter, and is adjusted by the switch controlling to connect with light source by light adjusting controller.

User by the action to common power switch, such as, can disconnect action, regulates the brightness of light source, and need not use extra device, such as the custom-designed switch with light modulation button, thus saves cost.

Figure 10 shows that the circuit diagram of light source driving circuit 1000 according to an embodiment of the invention.Composition graphs 3 is described by Figure 10.Number identical parts in Figure 10 with Fig. 3 and Fig. 4 and there is similar function

Light source driving circuit 1000 comprises the electric power converter 310 be connected with LED chain 312 with power supply, for receiving electric energy from power supply and providing the electric energy after adjustment for LED chain 312.Light adjusting controller 1008 monitors the action of the mains switch 304 between power supply and light source driving circuit 1000 by the voltage on monitoring port CLK.Light adjusting controller 1008 receives light modulation request signal and light modulation termination signal by port CLK.The set of this light modulation request signal instruction mains switch 304, second group of action of this light modulation termination signal instruction mains switch 304.If receive light modulation request signal, the electric energy after the adjustment that light adjusting controller 1008 continuous setup electric power converter 310 exports.If receive light modulation termination signal, the electric energy after the adjustment that light adjusting controller 1008 stops adjustment electric power converter 310 to export.In other words, if monitor the set of mains switch 304, light adjusting controller 1008 starts the electric energy after the adjustment of continuous setup electric power converter 310 output, until monitor second group of action of mains switch 304.In one embodiment, light adjusting controller 1008 adjusts the electric energy after the adjustment that electric power converter 310 exports by controlling the control switch Q16 that connects with LED chain 312.

Figure 11 shows that the structural representation of light adjusting controller 1008 in Figure 10, Figure 11 will be described in conjunction with Figure 10.Number identical parts in Figure 11 with Fig. 4, Fig. 5 and Figure 10 and there is similar function.

In the embodiment in figure 11, the similar of light adjusting controller 308 in the structure of light adjusting controller 1008 and Fig. 5.Difference is dimmer 1102 and triggers monitoring means 1106.In fig. 11, trigger monitoring means 1106 and receive light modulation request signal and light modulation termination signal by port CLK, and produce signal EN to start or close clock generator 1104.Trigger the conduction state that monitoring means 1106 also controls the switch Q27 be connected with LED chain 312.

Under analog dimming mode, dimmer 1102 produces reference signal REF to adjust the electric energy of LED chain 312.Under pulse light modulation pattern, dimmer 1102 produces control signal 538 to adjust the duty ratio of pulse width modulating signal PWM1, thus the electric energy of adjustment LED chain 312.In the embodiment in figure 11, dimmer 1102 comprises the clock generator 1104 for generation of clock signal be connected with triggering monitoring means 1106, the counter 1126 driven by clock signal, and the digital to analog converter 528 be connected with counter 1126.Dimmer 1102 also comprises the pulse width modulating signal generator 530 be connected with digital to analog converter 528 further.

When mains switch 304 is switched on or switched off, trigger monitoring means 1106 and can monitor voltage rising edge or trailing edge respectively at port CLK.Such as, when mains switch 304 disconnects, electric capacity C10 electric discharge is powered for light adjusting controller 1108.The voltage drop at resistance R6 two ends is to 0, thus triggering monitoring means 1106 can monitor a voltage drop edge on port CLK.Similar, when mains switch 304 is connected, voltage rise to default voltage at resistance R6 two ends, thus triggering monitoring means 1106 can monitor a voltage rising edge on port CLK.As previously mentioned, by the voltage on monitoring port CLK, trigger the action that monitoring means 1106 can monitor mains switch 304, such as ON Action or disconnection action.

In one embodiment, when the set of mains switch 304 is monitored to, namely triggers monitoring means 1106 and receive light modulation request signal by port CLK.When second group of action of mains switch 304 is monitored to, namely triggers monitoring means 1106 and receive light modulation termination signal by port CLK.In one embodiment, the set of mains switch 304 comprises first disconnection action and first ON Action thereafter.In one embodiment, second group of action of mains switch 304 comprises second disconnection action and second ON Action thereafter.

If trigger monitoring means 1106 to receive light modulation request signal, light adjusting controller 1108 starts the electric energy after the adjustment of continuous setup electric power converter 310 output.Under analog dimming mode, light adjusting controller 1108 adjusts the electric energy after the adjustment of electric power converter 310 output by the voltage adjusting reference signal REF.Under pulse light modulation pattern, light adjusting controller 1108 adjusts the electric energy after the adjustment of electric power converter 310 output by the duty ratio of adjustment pulse width modulating signal PWM1.

If trigger monitoring means 1106 to receive light modulation termination signal, the electric energy after the adjustment that light adjusting controller 1108 stops adjustment electric power converter 310 to export.

Figure 12 shows that the function mode schematic diagram of light source driving circuit according to an embodiment of the invention, this light source driving circuit includes the light adjusting controller 1008 shown in Figure 11.Figure 12 will be described in conjunction with Figure 10 and Figure 11.

In one embodiment, suppose that initial time mains switch 304 disconnects.When mains switch 304 is connected by user, electric power converter 310 is powered for LED chain 312, and LED chain 312 has an original intensity.Under analog dimming mode, this original intensity is determined by the initial voltage of reference signal REF.Under pulse light modulation pattern, this original intensity is by the initial duty cycle of pulse width modulating signal PWM1, and the duty ratio of such as 100% determines.Reference signal REF and pulse width modulating signal PWM1 is produced according to the count value of counter 1126 by digital to analog converter 528.Therefore, the initial voltage of REF and the initial duty cycle of PWM1 are by the initial count value of counter 1126, and such as 0 determines.

In order to adjust the brightness of LED chain 312, user can impose set to mains switch 304.Light modulation request signal is produced under the effect of set.In one embodiment, set comprises first disconnection action and first ON Action thereafter.That it produces as a result, trigger monitoring means 1106 to monitor voltage drop along 1204 and voltage rising edge 1206 thereafter at port CLK.In response to light modulation request signal, trigger monitoring means 1106 and produce the EN signal with high level, thus start clock generator 1104 with clocking.The counter 1126 driven by clock signal changes its count value in response to each clock pulse of clock signal.In the fig. 12 embodiment, count value increases progressively under the effect of clock signal.In one embodiment, after counter 1126 reaches its maximum count value preset, it is 0 that count value is reset.In another embodiment, count is until counter 1126 reaches default maximum count value, and then count value is successively decreased until counter 1126 reaches default least count value.

Under analog dimming mode, digital to analog converter 528 reads count value from counter 1126, and increases progressively in response to count value the voltage turning down reference signal REF.Under pulse light modulation pattern, digital to analog converter 528 reads count value from counter 1126, and increases progressively along with count value the duty ratio turning down pulse width modulating signal PWM1 gradually, such as, turn down 10% at every turn.Because by the voltage of reference signal REF, the electric energy after the adjustment that electric power converter 310 exports determines that (under analog dimming mode) or the duty ratio by pulse width modulating signal PWM1 determine (under pulse light modulation pattern), so the brightness of LED chain 312 can be adjusted accordingly.

Once LED chain 312 reaches the brightness of expectation, user stops brightness adjustment by imposing second group of action to mains switch 304.Light modulation termination signal is produced under the effect of second group of action.In one embodiment, second group of action comprises second disconnection action and second ON Action thereafter.That it produces as a result, trigger monitoring means 1106 to monitor voltage drop along 1208 and voltage rising edge 1210 thereafter at port CLK.Under the effect of light modulation termination signal, trigger monitoring means 1106 generation and there is low level EN signal, thus close clock generator 1104.The counter 1126 driven by clock signal keeps its count value constant.Under analog dimming mode, the voltage of reference signal REF will remain unchanged.Under pulse light modulation pattern, the duty ratio of pulse width modulating signal PWM1 will remain unchanged.Therefore, LED chain 312 will keep the brightness of this expectation constant.

Figure 13 shows that the method flow diagram 1300 according to an embodiment of the invention light source being carried out to controlling electric energy.Figure 13 will be described in conjunction with Figure 10 and Figure 11.

In step 1302, with electric power converter, such as electric power converter 310, the electric energy after the adjustment of output is to light source, and such as LED chain 312 is powered.

In step 1304, receive light modulation request signal, such as, receive light modulation request signal by light adjusting controller 1108.This light modulation request signal indicates the mains switch be connected between described power supply and described electric power converter, such as mains switch 304, set.In one embodiment, the set of mains switch comprises first disconnection action and first ON Action thereafter.

In step 1306, the electric energy after the adjustment that continuous setup electric power converter exports, such as, utilize light adjusting controller 1108 to adjust.In one embodiment, start clock generator 1104 and carry out actuation counter 1126.Count value according to counter 1126 produces dim signal, such as control signal 538 or reference signal REF.Under analog dimming mode, the current monitor signal being flowed through light source by comparison reference signal REF and instruction adjusts the electric energy after the adjustment of described electric power converter output.The voltage of REF is determined by count value.Under pulse light modulation pattern, the duty ratio being adjusted pulse width modulating signal PWM1 by control signal 538 carrys out the electric energy after the adjustment of described electric power converter output.The duty ratio of PWM1 is determined by count value.

In step 1308, receive light modulation termination signal, such as, receive light modulation termination signal by light adjusting controller 1108.This light modulation termination signal indicates the mains switch be connected between described power supply and described electric power converter, such as mains switch 304, second group of action.In one embodiment, second group of action of mains switch comprises second disconnection action and second ON Action thereafter.

In step 1310, if receive light modulation termination signal, then the electric energy after the adjustment stopping the described electric power converter of adjustment to export.In one embodiment, closing clock generator 1104 keeps its count value constant to make counter 1126.Its produce as a result, under analog dimming mode, the voltage of reference signal REF remains unchanged; Under pulse light modulation pattern, the duty ratio of pulse width modulating signal PWM1 remains unchanged.Therefore, light source can keep the brightness of expectation.

Figure 14 A is depicted as the circuit diagram of light source driving circuit 1400 according to an embodiment of the invention.Composition graphs 4 is described by Figure 14 A.Number identical parts in Figure 14 A with Fig. 3 and Fig. 4 and there is similar function.Light source driving circuit 1400 is coupled in power supply V by mains switch 304 _iN, such as: 220 volts of alternating currents, 50 hertz, and be coupled in LED light source 312.The structural representation of an embodiment of the mains switch 304 in Figure 14 A shown in Figure 14 B.In one embodiment, mains switch 304 is the ON/OFF switches be placed on metope.By element 1480 being switched to ON end or OFF end, the conduction state of mains switch 304 can be controlled as closing or disconnecting by user.

As shown in Figure 14 A, light source driving circuit 1400 comprises AC/DC converter 306, electric power converter 310 and light adjusting controller 1408.AC/DC converter 306 is by input ac voltage V _iNbe converted to output dc voltage V _oUT.Electric power converter 310 is coupled in AC/DC converter 306, for receiving output dc voltage V _oUT, and provide output electric energy to LED light source 312.Light adjusting controller 1408 is coupled in AC/DC converter 306 and electric power converter 310, for monitoring mains switch 304, and regulates the output electric energy of electric power converter 310 according to the action of mains switch 304, thus controls the brightness of LED light source 312.

In one embodiment, electric power converter 310 comprises inductance L 1, diode D4, control switch Q16, switch Q27 and resistance R5.Light adjusting controller 1408 comprises multiple port, such as: port HV_GATE, and port CLK, port VDD, port CTRL, port MON and port GND.The corresponding ports of the light adjusting controller 308 described in the port of light adjusting controller 1408 and Fig. 4 has similar function.

At work, the port CLK receiving key monitor signal 1450 of light adjusting controller 1408, to monitor mains switch 304.Switch monitors signal 1450 represents the conduction state of mains switch 304, such as: ON/OFF state.Therefore, light adjusting controller 1408 by port HV_GATE control switch Q27, and passes through port CTRL control switch Q16, thus controls the light modulation of LED light source 312.

In particular, in one embodiment, when mains switch 304 closes, light adjusting controller 1408 produces signal on port HV_GATE, such as: logic high, with Closing Switch Q27, and produce switch controlling signal 1452, with closed and disconnected control switch Q16 at port CTRL.In one embodiment, control switch Q16 is operated in switch closed condition and switch off state.When control switch Q16 is in switch closed condition, the closed and disconnected control switch Q16 that switch controlling signal 1452 replaces.In addition, light adjusting controller 1408 receives the electric current I representing and flow through LED light source 312 by port MON _lEDinduced signal 1454.When induced signal 1454 represents electric current I _lEDrise to current threshold I _tHtime, light adjusting controller 1408 disconnects control switch Q16.Therefore, when control switch Q16 closes, electric current I _lEDbecome large gradually; When control switch Q16 disconnects, electric current I _lEDdiminish gradually.By this way, light adjusting controller 1408 determines electric current I _lEDpeak value, and control electric current I thus _lEDmean value I _aVERAGE.When control switch Q16 is in switch off state, switch controlling signal 1452 maintains control switch Q16 and disconnects, to cut off electric current I _lED.In one embodiment, the time ratio between light adjusting controller 1408 determine switch closure state and switch off state, to control electric current I _lEDmean value I _aVERAGE.

In one embodiment, when mains switch 304 disconnects, light adjusting controller 1408 produces signal on port HV_GATE, such as: logic low, with switches Q27.Therefore, the electric current I of LED light source 312 is flowed through _lEDdrop to and be roughly zero ampere, extinguish to make LED light source 312.

In one embodiment, light adjusting controller 1408 receives the switch monitors signal 1450 of the conduction state representing mains switch 304 by port CLK.Accordingly, light adjusting controller 1408 identifies the action of mains switch 304, and provides the light modulation request signal representing this action.In one embodiment, light adjusting controller 1408 provides light modulation request signal when the disconnection action identifying mains switch 304; Or light adjusting controller 1408 provides light modulation request signal when identifying the closed action of mains switch 304.As the response to light modulation request signal, light adjusting controller 1408 is operated in analog dimming mode, burst light-modulating mode (burst dimming mode) or mixing light-modulating mode, with by adjustment control switch Q16 closed/disconnect the light modulation controlling LED light source 312.Such as, in analog dimming mode, light adjusting controller 1408 determines electric current I _lEDpeak value, and the time between maintained switch closure state and switch off state is than constant.In burst light-modulating mode, the time ratio between light adjusting controller 1408 determine switch closure state and switch off state, and maintain electric current I _lEDpeak value constant.In mixing light-modulating mode, the time ratio between light adjusting controller 1408 determine switch closure state and switch off state, and determine electric current I _lEDpeak value.Therefore, (represent that mains switch 304 closes again) when switch Q27 is again closed, light adjusting controller 1408 adjusts electric current I _lEDpeak value and/or duration of switch closed condition and switch off state, and then have adjusted the average current I flowing through LED light source 312 _aVERAGE, to control the brightness of LED light source 312.

The advantage of above-described embodiment is, by adjustment electric current I _lEDand the duration between switch closed condition and switch off state, light adjusting controller 1408 can adjust average current I in relatively wide scope _aVERAGE.Such as, if I _mAXrepresent I _aVERAGEmaximum, then according to embodiments of the invention, I _aVERAGEcan at 4%*I _mAXto 100%*I _mAXscope in change.And in the prior art, I _aVERAGEonly 20%*I _mAXto 100%*I _mAXscope in change.Therefore, the technical scheme provided by the embodiment of the present invention, LED light source 312 can realize light modulation in a wider context, like this, can be applicable in more energy-conservation lamp, such as, mini light night.

Figure 15 shows that the structural representation of the light adjusting controller 1408 in Figure 14 A.Composition graphs 5, Fig. 6, Fig. 7 and Figure 14 A are described by Figure 15.Number identical parts with Fig. 5 and Figure 14 A in Figure 15 and there is similar function.

In the embodiment shown in fig. 15, light adjusting controller 1408 comprise startup and low pressure locking (UVL) circuit 508, pulse signal maker 504, trigger monitoring means 506, dimmer 1502, comparator 534, set-reset flip-floop 522 and with door 524.Dimmer 1502 comprises reference signal generator 1506, for generation of reference signal REF.Dimmer 1502 also comprises PWM maker 1508, for generation of pulse-width signal PWM1.The description of composition graphs 5, comparator 534 compares induced signal 1454 and reference signal REF, to produce comparison signal COMP.Pulse signal maker 504 produces the pulse signal 536 with recurrent pulses waveform.In one embodiment, when pulse signal 536 is logical ones, set-reset flip-floop 522 is by pulse signal V ₅₂₂put 1; When comparison signal COMP is logical one (when induced signal 1454 rises to reference signal REF), set-reset flip-floop 522 is by pulse signal V ₅₂₂be reset to 0.With door 524 return pulse signal V ₅₂₂with pulse-width signal PWM1, and produce switch controlling signal 1452 accordingly, to control control switch Q16.

Suppose that switch Q27 closes, light adjusting controller 1408 is to be similar to the work method control electric current I of the light adjusting controller 308 described in Fig. 6 and Fig. 7 _lED.Such as, in one embodiment, when pulse-width signal PWM1 is in the first state: PWM1 is logical one, with door 524 according to pulse signal V ₅₂₂be alternately closed and disconnect control switch Q16.Thus, control switch Q16 is operated in switch closed condition.In switch closed condition, electric current I _lEDrise gradually when control switch Q16 closes, and decline gradually when control switch Q16 disconnects.Because control switch Q16 disconnects when induced signal 1454 rises to reference signal REF, reference signal REF determines electric current I _lEDpeak value.When pulse-width signal PWM1 is in the second state, such as: PWM1 is logical zero, with door 524 according to remaining open control switch Q16.Now, control switch Q16 is operated in switch off state, to cut off electric current I _lED.

Therefore, reference signal REF is for determining electric current I _lEDpeak value, and the duty ratio of pulse-width signal PWM1 is used for time ratio between determine switch closure state and switch off state.That is, the average current I of LED light source 312 is flowed through _aVERAGEduty ratio according to reference signal REF and pulse-width signal PWM1 changes.Such as, as the magnitude of voltage V of reference signal REF _rEFduring rising, I _aVERAGEincrease; Work as V _rEFduring decline, I _aVERAGEreduce.In addition, as the duty ratio D of pulse-width signal PWM1 _pWM1when becoming large, I _aVERAGEincrease; Work as D _pWM1when diminishing, I _aVERAGEreduce.

Dimmer 1502 also comprises counter 1504, for providing count value VALUE_1504.In one embodiment, reference signal generator 1506 is coupled in counter 1504, and determines the magnitude of voltage V of reference signal REF according to count value VALUE_1504 _rEF.PWM maker 1508 is coupled in counter 1504, and determines the duty ratio D of pulse-width signal PWM1 according to count value VALUE_1504 _pWM1.

Table 1

VALUE_1504	0	1	2	3
					V REF	V MAX	50%*V MAX	20%*V MAX	20%*V MAX
D PWM1	100%	100%	100%	20%

Table 2

VALUE_1504	0	1	2	3
					V REF	V MAX	50%*V MAX	30%*V MAX	20%*V MAX
D PWM1	100%	60%	40%	20%

Above-mentioned table 1 and table 2 are depicted as count value VALUE_1504, voltage V _rEFwith duty ratio D _pWM1embodiment.In one embodiment, counter 1504 is 2 bit counter, and therefore, count value VALUE_1504 can be 0,1,2 or 3.V _mAXrepresent the maximum of reference signal REF.Specifically, as shown in table 1, when count value VALUE_1504 is 0,1,2 and 3, reference signal REF has magnitude of voltage V respectively _mAX, 50%*V _mAX, 20%*V _mAXand 20%*V _mAX, and duty ratio D _pWM1be respectively 100%, 100%, 100% and 20%.As shown in table 2, when count value VALUE_1504 is 0,1,2 and 3, reference signal REF has magnitude of voltage V respectively _mAX, 50%*V _mAX, 30%*V _mAXand 20%*V _mAX, and duty ratio D _pWM1be respectively 100%, 60%, 40% and 20%.Count value VALUE_1504, voltage V _rEFwith duty ratio D _pWM1other relations can be had, and be not limited to the embodiment of table 1 and table 2.

In one embodiment, if receive light modulation request signal, such as: represent that mains switch 304 performs opening operation, trigger monitoring means 506 and produce enable signal 1510.Counter 1504 receives enable signal 1510, and increases accordingly or reduce count value VALUE_1504.Therefore, reference signal generator 1506 determines reference signal REF, such as: according to the data relationship of table 1 or table 2.PWM maker 1508 determines the duty ratio of PWM1, such as: according to the data relationship of table 1 or table 2.

Therefore, light adjusting controller 1408 selectively works in analog dimming mode, burst light-modulating mode and mixing light-modulating mode.In analog dimming mode, light adjusting controller 1408 determines the value of reference signal REF, to adjust electric current I according to the count value of counter 1504 _lEDmean value I _aVERAGE; Now, the duty ratio of PWM1 remains unchanged.In burst light-modulating mode, light adjusting controller 1408 determines the duty ratio of PWM1, to adjust electric current I according to the count value of counter 1504 _lEDmean value I _aVERAGE; Now, the value of reference signal REF remains unchanged.In mixing light-modulating mode, light adjusting controller 1408 determines the duty ratio of PWM1 and the value of reference signal REF, to adjust electric current I according to the count value of counter 1504 simultaneously _lEDmean value I _aVERAGE.Thus, have adjusted the brightness of LED light source 312.The operation of light adjusting controller 1408 will further describe at Figure 16 and Figure 17.Light adjusting controller 1408 can have other structures, and is not limited to the embodiment shown in Figure 15.

Figure 16 shows that the signal schematic representation of the light source driving circuit of the light adjusting controller 1408 comprised in Figure 15.Composition graphs 14A and Figure 15 is described by Figure 16.Figure 16 describes the voltage V on port CLK _cLK, the voltage V of counter 1504 count value VALUE_1504, pulse-width signal PWM1 _pWM1, the duty ratio D of pulse-width signal PWM1 _pWM1, the magnitude of voltage V of reference signal REF _rEF, the voltage V of induced signal 1454 _sENSE, electric current I _lEDmean value I _aVERAGE.In embodiment as shown in figure 16, light adjusting controller 1408 arranges magnitude of voltage V according to the embodiment in above-mentioned table 1 _rEFwith duty ratio D _pWM1.

In the t0 moment, mains switch 304 disconnects.Count value VALUE_1504 is 0.According to table 1, duty ratio D _pWM1100%, and magnitude of voltage V _rEFthere is maximum V _mAX.Because mains switch 304 and switch Q27 disconnect, then cut off electric current I _lED, therefore average current I _aVERAGEit is zero ampere.

In the t1 moment, voltage V _cLKrising edge represent the closed action of mains switch 304.Light adjusting controller 1408 Closing Switch Q27.Therefore, electric current I is controlled according to the conduction state of control switch Q16 _lED.In the time interval of t1 to t2, duty ratio D _pWM1100%, and magnitude of voltage V _rEFthere is maximum V _mAX.Control switch Q16 is operated in switch closed condition, to be alternately closed and to disconnect.As shown in figure 16, when control switch Q16 closes, voltage V _sENSErise gradually; When control switch Q16 disconnects, voltage V _sENSEdecline gradually.Due to voltage V _sENSEpeak value equal the maximum V of reference signal REF _mAX, average current I _aVERAGEthere is maximum I _mAX.

In the t2 moment, voltage V _cLKtrailing edge represent the disconnection action of mains switch 304.Switch Q27 disconnects, to cut off electric current I _lED.Therefore, in the time interval of t2 to t3, voltage V _sENSEdrop to roughly zero volt, and average current I _aVERAGEdrop to roughly zero ampere.

In one embodiment, owing to the disconnection action of mains switch 304 being detected in the t2 moment, then produce light modulation request signal.Count value VALUE_1504 increases to 1 from 0.Based on the embodiment of table 1, light adjusting controller 1408 switches to analog dimming mode, with by voltage V _rEFbe adjusted to 50%*V _mAXand keep duty ratio D _pWM1be 100%.

In the t3 moment, switch Q27 closes again.Therefore, in the time interval of t3 to t4, light adjusting controller 1408 controls the closed and disconnected of control switch Q16 according to reference signal REF and pulse-width signal PWM1.Therefore, by average current I _aVERAGEbe adjusted to 50%*I _mAX.

In the t4 moment, voltage V _cLKtrailing edge represent the disconnection action of mains switch 304.Count value VALUE_1504 increases to 2 from 1.According to table 1, light adjusting controller 1408 works in analog dimming mode, with by voltage V _rEFbe adjusted to 20%*V _mAXand keep duty ratio D _pWM1be 100%.Therefore, in the time interval of t5 to t6, average current I _aVERAGEbe adjusted to 20%*I _mAX.

In the t6 moment, voltage V _cLKtrailing edge represent the disconnection action of mains switch 304.Count value VALUE_1504 increases to 3 from 2.According to table 1, light adjusting controller 1408 works in burst light-modulating mode, to keep voltage V _rEFfor 20%*V _mAXand by duty ratio D _pWM1be decreased to 20%.Therefore, in the time interval of t7 to t8, mains switch 304 closes.Now, as voltage V _pWM1there is the first state, such as: logic high, voltage V _sENSEoblique line rises and oblique line declines; As voltage V _pWM1there is the second state, such as: logic low, voltage V _sENSEdrop to zero volt.Therefore, in the time interval of t7 to t8, average current I _aVERAGEbe adjusted to 4%*I _mAX.

Therefore, in embodiment as shown in figure 16, light adjusting controller 1408 is first operated in average current I in analog dimming mode _aVERAGEfrom 100%*I _mAXbe adjusted to 20%*I _mAX, be then operated in average current I in burst light-modulating mode _aVERAGEfrom 20%*I _mAXbe adjusted to 4%* I _mAX.The advantage of the embodiment of the present invention is, by the duty ratio D of adjusting pulsewidth modulation signal PWM1 _pWM1with the magnitude of voltage V of reference signal REF _rEF, achieve average current I _aVERAGEat 100%*I _mAXand 4%*I _mAXscope in adjustment.Therefore, LED light source 312 light modulation in more wide region is achieved.In addition, in the process of light modulation in relatively wide scope, voltage V _rEFkeep being greater than a voltage threshold, such as: 15%*V _mAX, duty ratio D _pWM1keep being greater than a duty cycle threshold, such as: 10%.Thus, the precision of pulse-width signal PWM1 and reference signal REF can not be subject to the impact of the unfavorable factor as noise and so on, thus improves the light modulation precision of light source driving circuit 1400.

Figure 17 shows that the signal schematic representation of the light source driving circuit of the light adjusting controller 1408 comprised in Figure 15.Composition graphs 14A to Figure 16 is described by Figure 17.Figure 17 describes the voltage V on port CLK _cLK, the voltage V of counter 1504 count value VALUE_1504, pulse-width signal PWM1 _pWM1, the duty ratio D of pulse-width signal PWM1 _pWM1, the magnitude of voltage V of reference signal REF _rEF, the voltage V of induced signal 1454 _sENSE, electric current I _lEDmean value I _aVERAGE.In embodiment as shown in figure 17, light adjusting controller 1408 arranges magnitude of voltage V according to the embodiment in table 1 _rEFwith duty ratio D _pWM1.

In the time interval between t0 ' and t2 ', light adjusting controller 1408 has the operation similar between t0 and t2 described in Figure 16.Such as, in the time interval of t0 ' to t2 ', count value VALUE_1504 is 0.According to table 2, duty ratio D _pWM1100%, and magnitude of voltage V _rEFthere is maximum V _mAX.Therefore, between t1 ' and t2 ', voltage V _sENSEpeak value equal the maximum V of reference signal REF _mAX, average current I _aVERAGEthere is maximum I _mAX.

In the t2 ' moment, voltage V _cLKtrailing edge represent the disconnection action of mains switch 304.Switch Q27 disconnects, to cut off electric current I _lED.Therefore, in the time interval of t2 ' to t3 ', voltage V _sENSEdrop to roughly zero volt, and average current I _aVERAGEdrop to roughly zero ampere.

In one embodiment, owing to the disconnection action of mains switch 304 being detected in the t2 ' moment, then produce light modulation request signal.Count value VALUE_1504 increases to 1 from 0.Based on the embodiment of table 2, light adjusting controller 1408 switches to mixing light-modulating mode, with by voltage V _rEFbe adjusted to 50%*V _mAXand by duty ratio D _pWM1be adjusted to 60%.Therefore, in the time interval of t3 ' to t4 ', as voltage V _pWM1have the first state, such as: during logic high, control switch Q16 is operated in switch closed condition, with the closed and disconnected replaced.Voltage V _sENSEpeak value equal the magnitude of voltage V of reference signal REF _rEF, i.e. 50%*V _mAX.In addition, as voltage V _pWM1have the second state, such as: during logic low, control switch Q16 is operated in switch off state, to cut off electric current I _lED.Therefore, electric current I _lEDmean value I _aVERAGEequal 30%*I _mAX.

In the t4 ' moment, voltage V _cLKtrailing edge represent and the disconnection action of mains switch 304 therefore, create light modulation request signal.Count value VALUE_1504 increases to 2 from 1.According to table 2, light adjusting controller 1408 works in mixing light-modulating mode, with by voltage V _rEFbe adjusted to 30%*V _mAXand keep duty ratio D _pWM1be 40%.Therefore, in the time interval of t5 ' to t6 ', average current I _aVERAGEbe adjusted to 12%*I _mAX.

In the t6 ' moment, voltage V _cLKtrailing edge represent and the disconnection action of mains switch 304 therefore, create light modulation request signal.Count value VALUE_1504 increases to 3 from 2.According to table 2, light adjusting controller 1408 works in mixing light-modulating mode, to adjust voltage V _rEFfor 20%*V _mAXand by duty ratio D _pWM1be decreased to 20%.Therefore, in the time interval of t7 ' to t8 ', average current I _aVERAGEbe adjusted to 4%*I _mAX.

Therefore, between t1 ' and t7 ', when count value VALUE_1504 changes, light adjusting controller 1408 is operated in mixing light-modulating mode.Advantage is, by the duty ratio D of adjusting pulsewidth modulation signal PWM1 _pWM1with the magnitude of voltage V of reference signal REF _rEF, achieve average current I _aVERAGEat 100%*I _mAXand 4%*I _mAXscope in adjustment.Therefore, LED light source 312 light modulation in more wide region is achieved.In addition, in the process of light modulation in relatively wide scope, voltage V _rEFkeep being greater than a voltage threshold, such as: 15%*V _mAX, duty ratio D _pWM1keep being greater than a duty cycle threshold, such as: 10%.Thus, the precision of pulse-width signal PWM1 and reference signal REF can not be subject to the impact of the unfavorable factor as noise and so on, thus improves the light modulation precision of light source driving circuit 1400.

Figure 18 shows that the method flow diagram 1800 of the light modulation controlling LED light source according to an embodiment of the invention.Composition graphs 14A to Figure 17 is described by Figure 18.The concrete steps that Figure 18 is contained are as just example.That is, the present invention's step of being applicable to other rational flow processs or Figure 18 being improved.

In step 1802, compare the induced signal representing and flow through the electric current of LED light source, such as: induced signal 1454 and reference signal, such as: reference signal REF, to produce pulse signal, such as: pulse signal V ₅₂₂.

In step 1804, work as pulse-width signal, such as: when PWM1 is in the first state, according to the electric current of pulse signal control flow check through LED light source.

In step 1806, when pulse-width signal is in the second state, cut off the electric current flowing through LED light source.

In step 1808, regulate the value of reference signal and the duty ratio of pulse-width signal, to regulate the average current flowing through described LED light source according to light modulation request signal.

In one embodiment, the count value of counter is regulated according to light modulation request signal.Count value according to counter determines the value of reference signal and the duty ratio of pulse-width signal.If count value becomes second value from the first numerical value, then select first mode (such as: analog dimming mode), the second pattern (burst light-modulating mode) or three-mode (mixing light-modulating mode).In a first mode, regulate the value of reference signal and keep the duty ratio of pulse-width signal constant.In a second mode, adjusting pulsewidth modulation signal duty ratio and keep the value of reference signal constant.In three-mode, regulate the value of reference signal and the duty ratio of adjusting pulsewidth modulation signal.

Figure 19 shows that the circuit diagram of the light source driving circuit 1900 according to the embodiment of the present invention.Number identical parts in Figure 19 with Fig. 3 and Fig. 4 and there is similar function.Composition graphs 3 and Fig. 4 are described by Figure 19.Light source driving circuit 1900 is coupled in power supply V by mains switch 304 _iN(as 110/120 volt, the alternating current of 60 hertz), and provide output electric energy to LED light source 312.In one embodiment of the invention, mains switch 304 can be the ON/OFF switch be placed on metope as shown in Figure 14B.The conduction state of mains switch 304 can be controlled as closed or disconnection by user.

Light source driving circuit 1900 comprises AC/DC transducer 306, electric power converter 310 and light adjusting controller 1908.AC/DC transducer 306 is by input ac voltage V _iNconvert output dc voltage V to _oUT.In the example of Figure 19, AC/DC transducer 306 comprise there is diode D1, D2, D7 and D8 bridge rectifier, also comprise the filter with diode D10 and electric capacity C9.Electric power converter 310 is coupled in AC/DC transducer 306, for receiving output dc voltage V _oUT, and provide the electric energy after adjustment for LED light source 312.In one embodiment, electric power converter 310 comprises inductance L 1, diode D4, switch Q27, control switch Q16 and current inductor R5.Light adjusting controller 1908 is coupled between AC/DC transducer 306 and electric power converter 310.Light adjusting controller 1908 monitors the action of mains switch 304, as closed or disconnect, and corresponding control electric power converter 310 be supplied to the adjustment of LED light source 312 after electric energy, to control the brightness of LED light source 312.Light adjusting controller 1908 comprises multiple port, such as, and port HV_GATE, monitoring port CLK, port VDD, port GND, voltage control port CTRL, port RT, port MON and Current Control port CS.The operation principle of the corresponding port of the light adjusting controller 1408 in its middle port VDD, port GND, port RT and port MON and Figure 14 A is similar.

In one embodiment, light adjusting controller 1908 receives the switch monitors signal 1450 of the action (closed or disconnection) of instruction mains switch 304 at monitoring port CLK.In one embodiment, light adjusting controller 1908 is according to switch monitors signal 1450 control switch Q27.Specifically, when switch monitors signal 1450 indicates mains switch 304 to disconnect, light adjusting controller 1908 produces signal, as logic-low signal, with cut-off switch Q27 at port HV_GATE.Therefore, the electric current I of LED light source 312 is flowed through _lEDdrop to 0 ampere, to disconnect LED light source 312.When switch monitors signal 1450 indicates mains switch 304 to close, light adjusting controller 1908 produces signal, as logic-high signal, with Closing Switch Q27 at port HV_GATE.Light adjusting controller 1908 flows through the electric current I of LED light source 312 according to the signal controlling of voltage control port CTRL and Current Control port CS _lED.

In one embodiment, light adjusting controller 1908 determines the light modulation request signal of the action indicating mains switch 304 according to switch monitors signal 1450.In one embodiment, when switch monitors signal 1450 indicates mains switch 304 to disconnect, light adjusting controller 1908 receives light modulation request signal.When mains switch 304 is again closed, according to light modulation request signal, light adjusting controller 1908 regulates the average current flowing through LED light source 312 to regulate the brightness of LED light source 312.

Light adjusting controller 1908 can be operated in first mode and the second pattern, to regulate the average current of LED light source 312.As described below, electric current I _lEDrepresent the electric current flowing through LED light source 312.Under first mode, electric current I _lEDby I _lED1represent.Under the second mode, electric current I _lEDby I _lED2represent.

When light adjusting controller 1908 is operated in first mode, the voltage control port CTRL of light adjusting controller 1908 provides pulse signal 1952, to control control switch Q16 alternation in the first state (e.g., closure state) and the second state (e.g., off-state).Therefore, the electric current I of LED light source 312 is flowed through _lED1state according to control switch Q16 changes.In one embodiment, at control switch Q16 period of contact, electric current I _lED1flow through LED light source 312, switch Q27, control switch Q16, resistance R5 to ground, so electric current I _lED1increase.At control switch Q16 off period, electric current I _lED1flow through LED light source 312 and diode D4, so electric current I _lED1reduce.According to embodiments of the invention, the average current flowing through LED light source 312 can by controlling control switch Q16 and adjusted under analog dimming mode, under pulse light modulation pattern or under combination light-modulating mode, and concrete light-dimming method will be described in detail in conjunction with Figure 20.

When light adjusting controller 1908 is operated in the second pattern, light adjusting controller 1908 provides control signal 1954 at voltage control port CTRL, as numeral 0, makes control switch Q16 maintain off-state.Therefore, electric current I _lED1cut-off.In addition, light adjusting controller 1908 connects the electric current I flowing through LED light source 312 and Current Control port CS _lED2.

Advantageously, by selecting to be at least functioning in first mode and the second pattern, light adjusting controller 1908 reaches relatively wide dimming scope.Such as, if I _mAXthe average current I of indication LED light source 312 _aVERAGEmaximum, light adjusting controller 1908 can be operated in first mode, to regulate electric current I _lED1average current I _aVERAGEchange in a wider scope, such as 4%*I _mAXto 100%*I _mAXscope in change.In addition, light adjusting controller 1908 also can be operated in the second pattern, with by average current I _aVERAGEbe transferred to a lower value.Such as, light adjusting controller 1908 arranges electric current I _lED2for steady state value 1%*I _mAX.In other words, LED light source 312 is under the second mode than darker under first mode.Therefore in energy-saving application, as night-light, can advantageously.In addition, the electric current I under the second pattern _lED2be the value that an essence is constant, it or can not disconnect and change because of the closed of control switch Q16.So the light that LED light source 312 sends can not be controlled the impact of switch Q16 switching noise, thus enhance the power stability of LED light source 312.

Figure 20 shows that the structural representation according to the light adjusting controller 1908 in Figure 19 of the embodiment of the present invention.Figure 20 will be described in conjunction with Figure 15 and Figure 19.Number identical parts in Figure 20 with Figure 15 and Figure 19 and there is similar function.In the example of Figure 20, light adjusting controller 1908 comprises startup and low pressure lock-in circuit 508, pulse signal maker 504, triggers monitoring means 506, dimmer 2002, driver 2010, switch 2008 and current source 2006.

In one embodiment, monitoring means 506 is triggered by monitoring port CLK receiving key monitor signal 1450.Trigger monitoring means 506 according to switch monitors signal 1450, determine the light modulation request signal indicating mains switch 304 opening operation.If receive light modulation request signal, trigger monitoring means 506 and produce enable signal 1510.

Dimmer 2002 comprises counter 1504, reference signal generator 1506, pulse-width signal maker 1508 and mode selection module 2004.Counter 1504 provides the count value VALUE_1504 changed according to enable signal 1510.In one embodiment, counter 1504 increases count value VALUE_1504 according to enable signal 1510.In another embodiment, counter 1504 reduces count value VALUE_1504 according to enable signal 1510.

Table 3

Table 4

Mode selection module 2004 selects the mode of operation of light adjusting controller 1908 from first mode and the second pattern according to count value VALUE_1504.In one embodiment, the expectation brightness value of count value VALUE_1504 indication LED light source 312.Expect that brightness value corresponds to the average current I of LED light source 312 _aVERAGEtarget current value I _tARGET.Table 3 and table 4 are depicted as count value VALUE_1504, the target current value I of counter 1504 _tARGETand the example of the corresponding relation of the mode of operation of light adjusting controller 1908.In the example of table 3, count value VALUE_1504 can be 0,1 and 2, respectively indicating target current value I _tARGETfor 100%*I _mAX, 30%*I _mAXand 1%*I _mAX, wherein, I _mAXrepresent average current I _aVERAGEmaximum.In the example of table 4, count value VALUE_1504 can be 0,1 and 2, respectively indicating target current value I _tARGETfor 1%*I _mAX, 30%*I _mAXand 100%*I _mAX.

Mode selection module 2004 compares count value VALUE_1504 and threshold value, to select mode of operation.Such as, according to the example of table 3 and table 4, threshold value is set to 1.In the example of table 3, when count value VALUE_1504 is equal to or less than 1, mode selection module 2004 selects first mode, and when count value VALUE_1504 is greater than 1, mode selection module 2004 selects the second pattern.In the example of table 4, when count value VALUE_1504 is equal to or greater than 1, mode selection module 2004 selects first mode, and when count value VALUE_1504 is less than 1, mode selection module 2004 selects the second pattern.Therefore, in the example of table 3 and table 4, as average current I _aVERAGEtarget current value I _tARGET(as 30%*I time relatively high _mAXand 100*I _mAX), select first mode.In addition, as average current I _aVERAGEtarget current value I _tARGET(as 1%*I time relatively low _mAX), select the second pattern.

According to selected mode of operation, mode selection module 2004 control switch 2008, reference signal generator 1506 and pulse-width signal maker 1508, to regulate average current I _aVERAGE.More specifically, in one embodiment, current source 2006 produces the constant electric current I of an essence _lED2.When light adjusting controller 1908 is operated in first mode, mode selection module 2004 cut-off switch 2008 is to cut off electric current I _lED2, and control reference signal generator 1506 and produce reference signal REF, and control pulse-width signal maker 1508 and produce pulse-width signal PWM1.In one embodiment, driver 2010 produces pulse signal 1952, to control control switch Q16 according to reference signal REF and pulse-width signal PWM1.

In one embodiment, driver 2010 comprise comparator 534, set-reset flip-floop 522 and with door 524.When being operated in first mode, the operation principle of driver 2010 is similar to the corresponding assembly in the light adjusting controller 1408 in Figure 15.As the description above for Figure 15, comparator 534 compares induced signal 1454 and reference signal REF, to produce comparison signal COMP.Pulse signal maker 504 produces the pulse signal 536 with recurrent pulse waveform.In one embodiment, when pulse signal 536 is digital 1, set-reset flip-floop 522 is by pulse signal V ₅₂₂be set to numeral 1.When comparison signal COMP is digital 1 (when induced signal 1454 reaches reference signal REF), set-reset flip-floop is by pulse signal V ₅₂₂be set to numeral 0.With door 524 return pulse signal V ₅₂₂with pulse-width signal PWM1, and produce pulse signal 1952 on voltage control port CTRL, to control control switch Q16.Therefore, when pulse-width signal PWM1 the first state (as numeral 1) time, the waveform of pulse signal 1952 and pulse signal V ₅₂₂waveform identical, namely according to comparison signal COMP numeral 1 and numeral 0 between switch.When pulse-width signal PWM1 the second state (as numeral 0) time, pulse signal 1952 remain numeral 0.According to the associated description above for Figure 15, reference signal REF determines electric current I _lED1peak value.The duty ratio of pulse-width signal PWM1 determines the closing time of control switch Q16 and the ratio of opening time.So by regulating the value of reference signal REF and/or the duty ratio of pulse-width signal PWM1, dimmer 2002 can be operated in analog dimming mode, pulse light modulation pattern or combination light-modulating mode, to regulate the average current I of LED light source 312 _aVERAGE.

According to the example in table 3, when count value VALUE_1504 is 0, light adjusting controller 1908 is operated in first mode, and the value of reference signal REF is V _rEF0, the value of the duty ratio of pulse-width signal PWM1 is D _pWM0.When count value VALUE_1504 becomes 1 from 0, light adjusting controller 1908 remains operating in first mode, average current I _aVERAGEtarget current value from 100%*I _mAXbecome 30%*I _mAX.If dimmer 2002 is operated in analog dimming mode, then the value of reference signal REF is adjusted to 30%*V _rEF0, the duty ratio of pulse-width signal PWM1 remains D _pWM0.If dimmer 2002 is operated in pulse light modulation pattern, then the value of reference signal REF remains V _rEF0, the duty cycle adjustment of pulse-width signal PWM1 is 30%*D _pWM0.If dimmer 2002 is operated in combination light-modulating mode, the value of reference signal REF and the duty ratio of pulse-width signal PWM1 all can change, and such as, the value of reference signal REF is adjusted to 50%*V _rEF0, the duty cycle adjustment of pulse-width signal PWM1 is 60%*D _pWM0.Adopt any one light-modulating mode in three kinds of light-modulating modes (i.e. analog dimming mode, pulse light modulation pattern and combination light-modulating mode), average current I _aVERAGEfrom 100%*I _mAXbecome 30%*I _mAX, to complete the brightness adjustment control under first mode.

When light adjusting controller 1908 is operated in the second pattern, as shown according to table 3, when count value VALUE_1504 becomes 2 from 1, light adjusting controller 1908 produces control signal 1954, to disconnect control switch Q16 at CTRL port.More specifically, mode selection module 2004 controls pulse-width signal maker 1508, makes pulse-width signal PWM1 remain on the second state (as numeral 0).With door 524, produce control signal 1954(as digital 0 signal), to keep the voltage of voltage control port CTRL for low level.Therefore, the electric current I of LED light source 312 is flow through _lED1cut-off.

In addition, in one embodiment, current source 2006 produces the constant electric current I of essence _lED2.Mode selection module 2004 produces switch controlling signal 2012 with Closing Switch 2008.If connected switch Q27, then electric current I after mains switch 304 is closed _lED2loop be switched on.Therefore, electric current I _lED2flow through LED light source 312, Current Control port CS, switch 2008 to ground.Wherein, " the electric current I that essence is constant _lED2" refer to electric current I _lED2value change only in certain scope, the nonideal current ripples therefore produced by circuit unit can be left in the basket.Advantageously, due to electric current I _lED2not by the impact of one or more switch (as mains switch 304 and/or control switch Q16), the circuit interference of LED light source 312 can reduce or eliminate.Therefore, the power stability of light source driving circuit 1900 is improved.Light adjusting controller 1908 can have other structure and be not limited to the example of Figure 20.

Figure 21 is depicted as the signal schematic representation comprising the light source driving circuit of the light adjusting controller 1908 in Figure 19 according to the embodiment of the present invention.Figure 21 will be described in conjunction with Figure 19 and Figure 20, and Figure 21 shows voltage VCLK, the count value VALUE_1504 of counter 1504, the voltage V of pulse-width signal PWM1 of monitoring port CLK _pWM1, pulse-width signal PWM1 duty ratio D _pWM1, flow through the electric current I of LED light source 312 _lEDand electric current I _lEDaverage current I _aVERAGE.In the example of Figure 19, light adjusting controller 1908 determines mode of operation according to table 3, and controls the average current I of LED light source 312 _aVERAGE.

In the t0 ' ' moment, mains switch 304 disconnects.Light adjusting controller 1908 roof-cut resistence Q27.Count value VALUE_1504 is 0.According to table 3, mode selection module 2004 selects first mode, average current I _aVERAGEtarget current value be 100%*I _mAX.Therefore, the duty ratio D of pulse-width signal maker 1508 adjusting pulsewidth modulation signal PWM1 _pWM1be 100%, reference signal generator 1506 controls reference signal REF, to regulate electric current I _lEDpeak value be I _pEAK(maximum of peak current).In the t1 ' ' moment, the voltage V of monitoring port CLK _cLKthere is the rising edge of instruction mains switch 304 closed procedure, average current I _aVERAGEbe adjusted to 100%*I _mAX.In t1 ' ' to t2 ' ' period, average current I _aVERAGEremain on 100%*I _mAX.

In the t2 ' ' moment, voltage V _cLKthere is the trailing edge of instruction mains switch 304 opening operation.Switch Q27 is disconnected to cut off electric current I _lED.Therefore, in t2 ' ' to t3 ' ' period, electric current I _lEDdrop to 0 ampere, average current I _aVERAGEdrop to 0 ampere.

In one embodiment, in the t2 ' ' moment, voltage V _cLKthere is the trailing edge of instruction mains switch 304 opening operation, receive light modulation request signal.Count value VALUE_1504 is increased to 1 from 0.According to table 3, average current I _aVERAGEtarget current value be adjusted to 30%*I _mAX.In t2 ' ' to t4 ' ' period, mode selection module 2004 remains on first mode, and in the example of Figure 21, dimmer 2002 is operated in combination light-modulating mode, and pulse-width signal maker 1508 regulates duty ratio D _pWM1be 60%, reference signal generator 1506 controls reference signal REF, to regulate electric current I _lEDpeak value be 50%*I _pEAK.In the t3 ' ' moment, the voltage V of monitoring port CLK _cLKthere is the rising edge of instruction mains switch 304 closed procedure, average current I _aVERAGEbe adjusted to 30%*I _mAX.In t3 ' ' to t4 ' ' period, average current I _aVERAGEremain on 30%*I _mAX.

In the t4 ' ' moment, voltage V _cLKthere is the trailing edge of instruction mains switch 304 opening operation, receive light modulation request signal.Accordingly, count value VALUE_1504 is increased to 2 from 1.According to table 3, average current I _aVERAGEtarget current value be adjusted to 1%*I _mAX, mode selection module 2004 selects the second pattern.Therefore, mode selection module 2004 produces switch controlling signal 2012 with Closing Switch 2008.In t4 ' ' to t5 ' ' period, because mains switch 304 and switch Q27 disconnect, so electric current I _lEDwith average electric current I _aVERAGEbe all 0 ampere.

In the t5 ' ' moment, the voltage V of monitoring port CLK _cLKthere is the rising edge of instruction mains switch 304 closed procedure.Because after mains switch 304 is closed, switch Q27 is switched on, and switch 2008 closed in the t4 ' ' moment, electric current I _lED2path be switched on.In one embodiment, electric current I _lED2equal 1%*I _mAX.Therefore, in t5 ' ' to t6 ' ' period, average current I _aVERAGEremain on 1%*I _mAX.

Therefore, in t1 ' ' to t6 ' ' period, light adjusting controller 1908 selects mode of operation according to count value VALUE_1504 from first mode and the second pattern.Advantageously, light adjusting controller 1908 can obtain a relatively wide dimming scope, as from 100%*I _mAXto 1%*I _mAX.The operation principle of light adjusting controller 1908 and working method are not limited to the example of Figure 21.In another embodiment, during the second pattern, light adjusting controller 1908 can provide another electric current (as a less constant current value 0.01*I _mAX) flow through LED light source 312 and Current Control port CS.Therefore, the brightness of LED light source 312 can be lower, to reach wider dimming scope.In addition, electric current I _lED2be the value that an essence is constant, can not change according to the closed and disconnected action of control switch Q16.Therefore, LED light source 312 can not be controlled the impact of switch Q16 noise, enhances the power stability of LED light source 312.

Figure 22 is depicted as the method flow diagram of the control LED light source light modulation performed by light adjusting controller (as light adjusting controller 1908) according to the embodiment of the present invention.Composition graphs 19-Figure 21 is described by Figure 22.The concrete steps that Figure 22 is contained are as just example.That is, the present invention's step of being applicable to other rational flow processs or Figure 22 being improved.

In step 2202, electric power converter (as electric power converter 310) provides the electric energy after adjustment for light source (as LED light source 312).

In step 2204, receiving key monitor signal.Switch monitors signal designation is connected to the action of the mains switch (as mains switch 304) between power supply and electric power converter.

In step 2206, be first mode or the second pattern according to switch monitors signal behavior mode of operation.In one embodiment, when receiving the switch monitors signal of instruction mains switch opening operation, the count value of counter changes, such as, become second value from the first numerical value.Count value and threshold value (as 1) are compared, and selects mode of operation according to comparative result.

In step 2208, when mode of operation is chosen as first mode, control switch (as control switch Q16) is operated in the first state (as closure state) and the second state (as off-state) according to pulse signal (as pulse signal 1952).In one embodiment, when control switch is in the first state, flow through the first electric current of LED light source (as electric current I _lED1) increase, when control switch is in the second state, the first electric current flowing through LED light source reduces.In one embodiment, when mode of operation is chosen as first mode, produce reference signal (as reference signal REF) and pulse-width signal (as pulse-width signal PWM1).In the flrst mode, the induced signal and the reference signal that instruction are flowed through the first electric current of LED light source compare.When pulse-width signal is in the first state (as numeral 1), according to comparative result closed and disconnected control switch.When pulse-width signal is in the second state (as numeral 0), disconnect control switch, the first electric current reduces.In one embodiment, in the flrst mode, when count value changes, the value of reference signal and/or the duty ratio of pulse-width signal is regulated, to regulate the brightness of LED light source.

In step 2210, when mode of operation is chosen as the second pattern, cut off the first electric current (as electric current I according to control signal (as control signal 1954) _lED1).In one embodiment, under the second mode, pulse-width signal remains on the second state (as numeral 0), cuts off the first electric current to produce control signal (as digital 0 signal).

In step 2212, when mode of operation is chosen as the second pattern, be conducted through the second electric current of LED light source 312.In one embodiment, the second electric current is that electric current that essence is constant is (as electric current I _lED2).In one embodiment, electric current I LED2 is provided by current source (as current source 2006).When selection the second pattern, mode selection module 2004 produces switch controlling signal 2012, with closed switch 2008 of connecting with current source 2006.

Figure 23 A is depicted as the block diagram of the light source driving circuit 2300 according to the embodiment of the present invention.In one embodiment, light source comprises the first light-emitting component (such as, a LED chain 2308) and the second light-emitting component (such as, the 2nd LED chain 2310).2nd LED chain 2310 can have the color temperature value different from a LED chain 2308, and such as, a LED chain 2308 has the first color temperature value, and the 2nd LED chain 2310 has the second color temperature value.Be coupling in power supply V _iNand the mains switch 304 between light source driving circuit 2300 is by power supply V _iNoptionally be coupled in light source driving circuit 2300.In one embodiment, mains switch 304 can be the mains switch be placed on metope.

Light source driving circuit 2300 comprises for by the AC-input voltage V from power supply _iNconvert direct voltage V to _dCaC/DC converter 306, be coupling in AC/DC converter 306 and light source (such as, one LED chain 2308 and the 2nd LED chain 2310) between DC-DC converter 2302, color-temperature controller 2306, light source (such as, a LED chain 2308 and the 2nd LED chain 2310), the first control switch 2312, second control switch 2314 and current monitor 2316.Wherein, AC/DC converter 306 and DC-DC converter 2302 form electric power converter, are coupling between power supply and light source, for receiving electric energy from power supply and providing the electric energy after adjustment to light source.DC-DC converter 2302 is for receiving direct voltage V from AC/DC converter 306 _dCand provide the V of the output voltage after adjustment to light source (such as, a LED chain 2308 and the 2nd LED chain 2310) _oUT.DC-DC converter 2302 comprises the transformer 2304 with former limit winding and vice-side winding.Color-temperature controller 2306 is coupling in the former limit winding of transformer 2304 and light source (such as, one LED chain 2308 and the 2nd LED chain 2310) between, the switch monitors signal TS of (such as opening operation) is operated for receiving instruction mains switch 304, and the colour temperature of light source (such as, a LED chain 2308 and the 2nd LED chain 2310) is adjusted based on switch monitors signal TS.As shown in fig. 23 a, color-temperature controller 2306 produces the first control signal CTR1 and the second control signal CTR2 according to switch monitors signal TS and controls a LED chain 2308 and the 2nd LED chain 2310 respectively.

First control signal CTR1 optionally connects the first control switch 2312 be coupling between color-temperature controller 2306 and a LED chain 2308, is adjusted to the first color temperature value to make the colour temperature of light source.Second control signal CTR2 optionally connects the second control switch 2314 be coupling between color-temperature controller 2306 and the 2nd LED chain 2310, is adjusted to the second color temperature value to make the colour temperature of light source.More particularly, if the first control signal CTR1 connects the first control switch 2312, the then electric current I be coupling between color-temperature controller 2306 and a LED chain 2308 _lED1flow through a LED chain 2308 and the colour temperature of light source is adjusted to the first color temperature value; If the second control signal CTR2 connects the second control switch 2314, the then electric current I be coupling between color-temperature controller 2306 and the 2nd LED chain 2310 _lED2flow through the 2nd LED chain 2310 and the colour temperature of light source is adjusted to the second color temperature value.Color-temperature controller 2306 also receives from current monitor 2316 current value (such as, the electric current I that instruction flows through light source _lED1or electric current I _lED2value) current monitor signal SEN, and produce drive singal DRV according to current monitor signal SEN.The input voltage of the former limit winding of drive singal DRV control transformer 2304, thus the output voltage V regulating DC-DC converter 2302 _oUT.

Figure 23 B is depicted as the circuit diagram of the light source driving circuit 2300 according to the embodiment of the present invention.Light source driving circuit 2300 is by power supply V _iN(such as, 110/120V exchanges, 60Hz) powers via mains switch 304.In one embodiment, the structure that AC/DC converter 306 tool in Figure 23 B with Fig. 4 is identical.AC/DC converter 306 is coupled in DC-DC converter 2302 and color-temperature controller 2306.Current monitor 2316 can be current sense resistance R5.

DC-DC converter 2302 receives input voltage V from AC/DC converter 306 _dCand provide the V of the output voltage after adjustment to light source (such as, a LED chain 2308 and the 2nd LED chain 2310) _oUT.In the example of Figure 23 B, DC-DC converter 2302 comprises transformer 2304, control switch Q23, diode D4 and electric capacity C6.Transformer 2304 comprises for receiving input voltage V from AC/DC converter 306 _dCformer limit winding 2305, for providing output voltage V to a LED chain 2308 and the 2nd LED chain 2310 _oUTvice-side winding 2307, magnetic core 2325 and for providing the auxiliary winding 2309 of voltage to color-temperature controller 2306.Transformer 2304 shown in Figure 23 B comprise three windings just citing and and unrestricted, in other embodiments, transformer 2304 can comprise the winding of other varying number.In the embodiment shown in Figure 23 B, the control switch Q23 being coupled in former limit winding 2305 is positioned at the outside of color-temperature controller 2306.In other embodiments, control switch Q23 also can be integrated in the inside of color-temperature controller 2306.

Color-temperature controller 2306 is coupled in former limit winding 2305 and the auxiliary winding 2309 of transformer 2304.Color-temperature controller 2306 can be flyback pulse width modulation (PWM) controller, optionally connect the control switch Q23 connected with former limit winding 2305 for generation of pwm signal, and adjust the output voltage of transformer 2304 by the duty ratio adjusting pwm signal.Citing but and unrestricted, the port of color-temperature controller 2306 comprises port CLK, PWM, VDD, CS, FB, SW1 and SW2.

Color-temperature controller 2306 receives the conducting state of instruction mains switch 304 (such as at port CLK place, be switched on or switched off state) switch monitors signal TS, and produce the first control signal CTR1(at port SW1 place according to switch monitors signal TS) and the second control signal CTR2(at port SW2 place) control a LED chain 2308 and the 2nd LED chain 2310 respectively.More particularly, in one embodiment, if switch monitors signal TS indicates the switch 304 that switches on power for the first time, then color-temperature controller 2306 produces the first control signal CTR1 to connect the first control switch 2312 and produces the second control signal CTR2 to disconnect the second control switch 2314, therefore, electric current I _lED1flow through a LED chain 2308 and do not have electric current to flow through the 2nd LED chain 2310; If switch monitors signal TS indicates mains switch 304 disconnect and again connect within a predetermined period of time, then color-temperature controller 2306 produces the first control signal CTR1 to disconnect the first control switch 2312 and produces the second control signal CTR2 to connect the second control switch 2314, therefore, electric current is not had to flow through a LED chain 2308, electric current I _lED2flow through the 2nd LED chain 2310.Because the 2nd LED chain 2310 can have the colour temperature different from a LED chain 2308, so color-temperature controller 2306 can adjust the colour temperature of light source according to switch monitors signal TS.

Port FB receives indicator current I from current monitor 2316 _lED1or electric current I _lED2the current monitor signal SEN of value.Port CS receives the monitor signal LPSEN that instruction flows through the electric current of former limit winding 2305.Color-temperature controller 2306 received current monitor signal SEN and monitor signal LPSEN, and control control switch Q23 to regulate the output voltage VO UT of DC-DC converter 2302 at port PWM place generation drive singal DRV.

Color-temperature controller 2306 produces at port PWM place the conducting state (such as, being switched on or switched off state) that drive singal DRV controls control switch Q23 according to current monitor signal SEN and monitor signal LPSEN.More particularly, the voltage of current monitor signal SEN can compare with indicating the voltage flowing through the reference signal of the target current value of light source, the voltage of monitor signal LPSEN can compare with the voltage of another reference signal of indicating target current value, if the instantaneous current value that arbitrary comparative result instruction flows through light source is greater than target current value, then color-temperature controller 2306 reduces the duty ratio of drive singal DRV, and vice versa.In one embodiment, if drive singal DRV is the first state (such as, logic high), then control switch Q23 connects, and electric current flows through former limit winding 2305, and magnetic core 2325 carries out energy storage.If drive singal DRV be the second state (such as, logic low), control switch Q23 disconnects, and the diode D4 forward bias being coupled in vice-side winding 2307 is released into electric capacity C6 and light source to make the energy be stored in magnetic core 2325 through vice-side winding 2307.Therefore, the electric energy of light source (such as, a LED chain 2308 and the 2nd LED chain 2310) can be adjusted according to drive singal DRV.

Port VDD is coupled in auxiliary winding 2309.In one embodiment, the energy-storage units (such as, electric capacity C5) be coupled between port VDD and ground is that color-temperature controller 2306 is powered when mains switch 304 disconnects.

Advantageously, in response to the opening operation of mains switch 304 in the circuit of former limit, again switch on power after switch 304 in predetermined amount of time after the opening operation of mains switch 304, the colour temperature of the light source (such as, a LED chain 2308 and the 2nd LED chain 2310) in secondary circuit is adjusted to aim colour temperature value by color-temperature controller 2306.

Figure 24 is depicted as the structural representation according to the color-temperature controller 2306 in Figure 23 B of the embodiment of the present invention.Figure 24 will be described in conjunction with Figure 20 and Figure 23 B.Parts identical with Figure 20 with Figure 23 B label in Figure 24 have similar function.In the example of Figure 24, color-temperature controller 2306 comprises startup and low pressure locking (UVL) circuit 508, driver 2410, control unit 2420, identifying unit 2431 and not gate 2433.

Driver 2410 for receiving from current monitor 2316 the current monitor signal SEN that instruction flows through the value of the electric current of a LED chain 2308 or the 2nd LED chain 2310, and produces drive singal DRV according to current monitor signal SEN.In one embodiment, driver 2410 comprises error amplifier 2411, going sawtooth signal generator 2413, comparator 2415 and pulse width modulating signal generator 2417.Error amplifier 2411 produces error signal VEA based on reference signal REF and current monitor signal SEN, and reference signal REF indicates the target current value of light source (such as, a LED chain 2308 or the 2nd LED chain 2310).Error amplifier 2411 is in the electric current I of port FB place received current monitor signal SEN, current monitor signal SEN instruction from current monitor 2316 _lED1or electric current I _lED2value.Error signal VEA is used for the electric current I that will flow through a LED chain 2308 _lED1value or flow through the electric current I of the 2nd LED chain 2310 _lED2value be adjusted to target current value.Going sawtooth signal generator 2413 produces sawtooth signal SAW.Comparator 2415 is coupled in error amplifier 2411 and going sawtooth signal generator 2413, for comparison error signal VEA and sawtooth signal SAW, and produces output signal to pulse width modulating signal generator 2417.Monitor signal LPSEN is received by port CS, and instruction flows through the electric current of former limit winding 2305.Pulse width modulating signal generator 2417 is coupled in comparator 2415 and port CS, and the output signal of device 2415 and monitor signal LPSEN and produce the state that drive singal DRV carrys out control switch Q23 based on the comparison.In one embodiment, if another reference signal that the voltage of monitor signal LPSEN is greater than indicating target current value is (not shown, such as can in be built in pulse width modulating signal generator 2417) voltage, the electric current flowing through former limit winding 2305 is then indicated to be greater than target current value, then pulse width modulating signal generator 2417 reduces the duty ratio of drive singal DRV, and vice versa.

When the voltage of current monitor signal SEN is greater than the voltage of reference signal REF, instruction flows through the electric current I of a LED chain 2308 _lED1value or flow through the electric current I of the 2nd LED chain 2310 _lED2value be greater than the target current value determined by reference signal REF, the duty ratio that driver 2410 reduces drive singal DRV according to current monitor signal SEN reduces to make the output voltage of DC-DC converter 2302.Similarly, when the voltage of current monitor signal SEN is less than the voltage of reference signal REF, instruction flows through the electric current I of a LED chain 2308 _lED1value or flow through the electric current I of the 2nd LED chain 2310 _lED2value be less than the target current value determined by reference signal REF, the duty ratio that driver 2410 increases drive singal DRV according to current monitor signal SEN increases to make the output voltage of DC-DC converter 2302.

Identifying unit 2431 detect color-temperature controller 2306 energy state and based on color-temperature controller 2306 energy state and produce the first decision signal VDD_L and the second decision signal VDD_H.Color-temperature controller 2306 adjusts the colour temperature of light source based on the first decision signal VDD_L, the second decision signal VDD_H and switch monitors signal TS.Such as, if the voltage at the port VDD place of color-temperature controller 2306 is less than reset threshold voltage (such as, 4V), then the first decision signal VDD_L has the first state (such as, logic high); If the voltage at the port VDD place of color-temperature controller 2306 is greater than reset threshold voltage (such as, 4V), then the first decision signal VDD_L has the second state (such as, logic low); If the voltage at the port VDD place of color-temperature controller 2306 is less than enable threshold voltage (such as, 10V), then the second decision signal VDD_H has the first state (such as, logic low); If the voltage at the port VDD place of color-temperature controller 2306 is greater than enable threshold voltage (such as, 10V), then the second decision signal VDD_H has the second state (such as, logic high).

Control unit 2420 controls a LED chain 2308 and the 2nd LED chain 2310 respectively for producing the first control signal CTR1 and the second control signal CTR2 according to switch monitors signal TS, the first decision signal VDD_L and the second decision signal VDD_H.In one embodiment, control unit 2420 comprises timer 2421, first d type flip flop 2423, second d type flip flop 2425, first and door 2427 and second and door 2429.Timer 2421 receiving key monitor signal TS and start timing when trailing edge appears in switch monitors signal TS, timer 2421 also produces pulse signal TS_DE after the time predefined interval of delta t of each trailing edge of switch monitors signal TS.Pulse signal TS_DE is coupled in the input port CLK of the first d type flip flop 2423, and switch monitors signal TS is coupled in the input port CLK of the second d type flip flop 2425.The input port D1 of the first d type flip flop 2423 is coupled in its output port and the output port Q1 of the first d type flip flop 2423 is coupled in the input port D2 of the second d type flip flop 2425.

The input port R of the first d type flip flop 2423 and the second d type flip flop 2425 is all coupled in the output port of not gate 2433, and the input port of not gate 2433 is coupled in identifying unit 2431.If the voltage at the port VDD place of color-temperature controller 2306 is less than reset threshold voltage (such as, 4V), first decision signal VDD_L is logic high, then the first d type flip flop 2423 and the second d type flip flop 2425 are all reset through not gate 2433, therefore, the output port Q1 of the first d type flip flop 2423 and output port Q2 of the second d type flip flop 2425 is reset as logic low, and the output port of the first d type flip flop 2423 with the output port of the second d type flip flop 2425 all be reset as logic high.

The output port of the second decision signal VDD_H and the second d type flip flop 2425 all be coupled in first and produce the first control signal CTR1 to control the first control switch 2312 and the electric current I flowing through a LED chain 2308 with door 2427, first and door 2427 _lED1.The output port Q2 of the second decision signal VDD_H and the second d type flip flop 2425 is all coupled in second and produces the second control signal CTR2 to control the second control switch 2314 and the electric current I flowing through the 2nd LED chain 2310 with door 2429, second and door 2429 _lED2.In this way, color-temperature controller 2306 can adjust the colour temperature of light source in response to the opening operation of mains switch 304.

Figure 25 is depicted as the signal waveforms of the light source driving circuit comprising the color-temperature controller shown in Figure 24.Figure 25 shows switch monitors signal TS, pulse signal TS_DE, the first decision signal VDD_L, the second decision signal VDD_H, the voltage at input port D1 place, the voltage at output port Q1 place, the voltage at output port Q2 place, the signal waveform of the first control signal CTR1 and the second control signal CTR2.Composition graphs 23B and Figure 24 is described by Figure 25.

In the t0 moment, mains switch 304 is connected.In the t1 moment, switch monitors signal TS from the first state (such as, logic low) change into the second state (such as, logic high), the voltage at port VDD place increases to reset threshold voltage (such as, 4V) and the first decision signal VDD_L changes into the second state (such as, logic low) from the first state (such as, logic high).In the t2 moment, the voltage at port VDD place increases to enable threshold voltage (such as, 10V) and the second decision signal VDD_H changes into the second state (such as, logic high) from the first state (such as, logic low).Within the time interval of t0 moment to the t2 moment, the output port Q1 of the first d type flip flop 2423 and output port Q2 of the second d type flip flop 2425 is logic low.Due to first with door 2427 and second and the second decision signal VDD_H of receiving of door 2429 be logic low, the first control signal CTR1 and the second control signal CTR2 is also logic low.After instant t 2, because the second decision signal VDD_H changes into logic high, the first control signal CTR1 also changes into logic high, and therefore, the first control switch 2312 is connected and electric current I _lED1start to flow through a LED chain 2308.In the t3 moment, mains switch 304 disconnects, and the voltage at the port VDD place of color-temperature controller 2306 starts to decline.As mentioned above, once trailing edge appears in switch monitors signal TS, pulse signal TS_DE can be produced after time predefined interval of delta t.In the t4 moment, in response to the rising edge that pulse signal TS_DE occurs, the input port D1 of the first d type flip flop 2423 changes into logic low from logic high, and the output port Q1 of the first d type flip flop 2423 changes into logic high from logic low.In the t5 moment, the voltage drop at port VDD place is low to moderate enable threshold voltage (such as, 10V), and the second decision signal VDD_H changes into the first state (such as, logic low) from the second state (such as, logic high).Therefore, due to first with door 2427 and second and the second decision signal VDD_H of receiving of door 2429 be logic low, the first control signal CTR1 and the second control signal CTR2 is also logic low.

In the t6 moment, there is rising edge in switch monitors signal TS, and instruction mains switch 304 connects t again.The time interval in t3 moment to t6 moment is less than predetermined (regulation) time interval (such as, t6 subtracts t3<3 second), more than reset threshold voltage (such as, 4V) is remained on and the first decision signal VDD_L remains logic low to make the voltage at port VDD place.In response to the rising edge that switch monitors signal TS occurs, the output port Q2 of the second d type flip flop 2425 changes into logic high from logic low, and its output port logic low is changed into from logic high.Be similar to the time interval of t1 moment to the t2 moment, from the t6 moment to the time interval in t7 moment, the first control signal CTR1 and the second control signal CTR2 is logic low.After the t7 moment, the voltage at port VDD place increases to more than enable threshold voltage, and the second decision signal VDD_H changes into logic high, and the second control signal CTR2 also changes into logic high, and the second control switch 2314 is connected and electric current I _lED2start to flow through the 2nd LED chain 2310.Then, mains switch 304 disconnects again, and is low to moderate enable threshold voltage (such as, 10V) in the voltage drop at t8 moment port VDD place.Signal waveform from the t8 moment to the time interval in t10 moment is similar to the signal waveform from the t0 moment to the time interval in t5 moment.In the t9 moment, the first control switch 2312 is connected and electric current I _lED1start to flow through a LED chain 2308.

Therefore, color-temperature controller 2306 alternately connects the first control switch 2312 and the second control switch 2314 in response to the opening operation of mains switch 304, because the 2nd LED chain 2310 can have the colour temperature different from a LED chain 2308, therefore, color-temperature controller 2306 can adjust the colour temperature of light source in response to the opening operation of mains switch 304.

Figure 26 is depicted as the signal waveforms comprising the light source driving circuit of the color-temperature controller shown in Figure 24 according to another embodiment of the invention.Figure 26 shows switch monitors signal TS, pulse signal TS_DE, the first decision signal VDD_L, the second decision signal VDD_H, the voltage at input port D1 place, the voltage at output port Q1 place, the voltage at output port Q2 place, the signal waveform of the first control signal CTR1 and the second control signal CTR2.Composition graphs 23B, Figure 24 and Figure 25 are described by Figure 26.

Waveform from the t0 moment to the time interval in t6 ' moment be similar in Figure 25 from the t0 moment to the time interval in t6 moment waveform.In the t7 ' moment, mains switch 304 is connected again.T3 moment to the t7 ' moment interval greater than predetermined time interval (such as, t7 ' subtract t3>3 second).Therefore, in the t6 ' moment, the voltage drop at port VDD place is low to moderate reset threshold voltage (such as, 4V), and the first decision signal VDD_L changes into logic high from logic low, and output port Q1 and output port Q2 is reset as logic low.Due to first with door 2427 and second and the second decision signal VDD_H of receiving of door 2429 be logic low, the first control signal CTR1 and the second control signal CTR2 is also logic low.

In the t8 ' moment, switch monitors signal TS from the first state (such as, logic low) change into the second state (such as, logic high), the voltage at port VDD place increases to reset threshold voltage (such as, 4V), and the first decision signal VDD_L from the first state (such as, logic high) change into the second state (such as, logic low).In the t9 ' moment, the voltage at port VDD place increases to enable threshold voltage (such as, 10V), and the second decision signal VDD_H changes into the second state (such as, logic high) from the first state (such as, logic low).Signal waveform in t7 ' moment to the time interval in t9 ' moment is similar to the signal waveform in t0 moment to the time interval in t2 moment.After the t9 ' moment, the voltage at port VDD place increases to more than enable threshold voltage, and the second decision signal VDD_H changes into logic high, and the first control signal CTR1 also changes into logic high.Then, the first control switch 2312 is connected and electric current I _lED1start to flow through a LED chain 2308.

As shown in figure 25, if switch monitors signal TS indicates the time interval between the opening operation of mains switch 304 and next making operation to be less than predetermined time interval (such as, 3 seconds), then the colour temperature of light source (such as, a LED chain 2308 and the 2nd LED chain 2310) is changed into the second color temperature value from the first color temperature value in response to next making operation of mains switch 304 by color-temperature controller 2306.More particularly, in the example of Figure 25, the interim very first time (such as, from the t2 moment to the time interval in t5 moment), the first control signal CTR1 is logic high, and a LED chain 2308 is connected, 2nd LED chain 2310 disconnects, and is adjusted to the first color temperature value to make the colour temperature of light source; During second time interval being different from very first time interval (such as, from the t7 moment to the time interval in t8 moment), the second control signal CTR2 is logic high, and a LED chain 2308 disconnects, 2nd LED chain 2310 is connected, and is adjusted to the second color temperature value to make the colour temperature of light source.Therefore, the colour temperature of light source is changed into the colour temperature of the 2nd LED chain 2310 by color-temperature controller 2306 from the colour temperature of a LED chain 2308 by alternately connecting the first control switch 2312 and the second control switch 2314.But, as shown in figure 26, if switch monitors signal TS indicate between the opening operation of mains switch 304 and next making operation interval greater than predetermined time interval, then the colour temperature of light source is reset to preset color temperature value in response to next making operation of mains switch 304 by color-temperature controller 2306.In the example of Figure 26, preset color temperature value can be the color temperature value of the first LED chain 2308, such as, by the color temperature value arranged when dispatching from the factory; Preset color temperature value is not limited to the color temperature value shown in the example of Figure 26.

Figure 27 is depicted as the method flow diagram 2700 of the control light source color temperature according to the embodiment of the present invention.Composition graphs 23A-Figure 26 is described by Figure 27.The concrete steps contained in Figure 27 are as just example, that is, the present invention is applicable to perform other step various or the step improved the step stated in Figure 27.

In step 2702, drive circuit (such as, light source driving circuit 2300) receive electric energy and provide the electric energy after adjustment to light source (such as, a LED chain 2308 and the 2nd LED chain 2310) by electric power converter (such as AC/DC converter 306 and transformer 2304) from power supply.

In step 2704, receiving key monitor signal, switch monitors signal TS(such as, the switch monitors signal received by color-temperature controller 2306) instruction is coupling in the operation of mains switch (such as, mains switch 304) between power supply and electric power converter.

In step 2706, adjust the colour temperature of light source based on switch monitors signal TS.Such as, the interim very first time (such as, the time interval in t2 moment in fig. 25 to t5 moment), color-temperature controller 2306 can produce the first control signal CTR1 to connect a LED chain 2308 with the first color temperature value, and produce the second control signal CTR2 to disconnect the 2nd LED chain 2310 with the second color temperature value, be adjusted to the first color temperature value to make the colour temperature of light source; During second time interval being different from very first time interval (such as, the time interval in t7 moment in fig. 25 to t8 moment), color-temperature controller 2306 can produce the first control signal CTR1 to disconnect a LED chain 2308, and produce the second control signal CTR2 to connect the 2nd LED chain 2310, be adjusted to the second color temperature value to make the colour temperature of light source.

Therefore, the drive circuit of the embodiment of the present invention can according to instruction mains switch (such as, be placed in the on/off switch on metope) the switch monitors signal of operation to control light source (such as, one LED chain 2308 and the 2nd LED chain 2310) colour temperature, and the electric energy of the light source provided by DC-DC converter can be adjusted by the switch controlling the former limit winding that be coupled in series with transformer in DC-DC converter by color-temperature controller.Therefore, user can by the operation of docking on/off switch power supply switch (such as, opening operation) adjust the colour temperature of light source, avoid the colour temperature using extra device (such as custom-designed have regulate the switch of button) to adjust light source, thus save cost.

More than describe is illustrate based on the embodiment of LED chain.But, the light source of other types can also be applied to according to embodiments of the invention.In other words, embodiments of the invention are not limited to LED light source, are equally applicable to the light source of other types.

All be illustrative rather than definitive thereof with expressing in the wording of this use, use these wording and express and any equivalent (or part equivalent) of the characteristic in this diagram and description is not got rid of outside invention scope, various amendment may be there is within the scope of the claims.Other amendment, variant and alternative also may exist.Therefore, claim is intended to contain this type of equivalents all.

Claims (20)

1. a light source driving circuit, for driving the light source with adjustable color temperature, is characterized in that, described light source driving circuit comprises:

Electric power converter, is coupling between power supply and described light source, for receiving electric energy from described power supply and providing the electric energy after adjustment to described light source; And

Color-temperature controller, is coupled in described electric power converter, is coupling in the switch monitors signal of the operation of the mains switch between described power supply and described electric power converter, and adjusts the colour temperature of described light source based on described switch monitors signal for receiving instruction.

2. light source driving circuit according to claim 1, it is characterized in that, described light source comprises first light-emitting component with the first color temperature value and second light-emitting component with the second color temperature value, described color-temperature controller comprises the control unit for producing the first control signal and the second control signal according to described switch monitors signal, wherein said first control signal is optionally connected the first control switch be coupling between described color-temperature controller and described first light-emitting component and is adjusted to described first color temperature value to make the colour temperature of described light source, described second control signal is optionally connected the second control switch be coupling between described color-temperature controller and described second light-emitting component and is adjusted to described second color temperature value to make the colour temperature of described light source.

3. light source driving circuit according to claim 2, is characterized in that, described control unit comprises:

Timer, for receiving described switch monitors signal, described timer starts timing when trailing edge appears in described switch monitors signal, and produces pulse signal after the time predefined interval of described trailing edge;

First d type flip flop, for receiving described pulse signal; And

Second d type flip flop, is coupled in described first d type flip flop, for receiving described switch monitors signal;

Wherein said first control signal and described second control signal are output signal based on described second d type flip flop and produce.

4. light source driving circuit according to claim 1, it is characterized in that, described color-temperature controller comprises identifying unit, described identifying unit is for detecting the energy state of described color-temperature controller and the described energy state based on described color-temperature controller produces the first decision signal and the second decision signal, and described color-temperature controller adjusts the colour temperature of described light source based on described first decision signal, described second decision signal and described switch monitors signal.

5. light source driving circuit according to claim 1, it is characterized in that, if the time interval between the opening operation of mains switch described in described switch monitors signal designation and next making operation is less than predetermined time interval, then the colour temperature of described light source is adjusted to the second color temperature value from the first color temperature value in response to next making operation described in described mains switch by described color-temperature controller.

6. light source driving circuit according to claim 5, it is characterized in that, described light source comprises first light-emitting component with described first color temperature value and second light-emitting component with described second color temperature value, described color-temperature controller adjusts the colour temperature of described light source by producing the first control signal and the second control signal, when described first control signal connects the first control switch be coupling between described color-temperature controller and described first light-emitting component, electric current flows through described first light-emitting component and the colour temperature of described light source is adjusted to described first color temperature value; When described second control signal connects the second control switch be coupling between described color-temperature controller and described second light-emitting component, electric current flows through described second light-emitting component and the colour temperature of described light source is adjusted to described second color temperature value.

7. light source driving circuit according to claim 1, it is characterized in that, if between the opening operation of mains switch described in described switch monitors signal designation and next making operation interval greater than predetermined time interval, then the colour temperature of described light source is reset to preset color temperature value in response to next making operation described in described mains switch by described color-temperature controller.

8. light source driving circuit according to claim 1, it is characterized in that, described electric power converter comprises AC/DC converter and transformer, described transformer comprises former limit winding, vice-side winding and auxiliary winding, described former limit winding coupled is in described AC/DC converter and for receiving electric energy by described AC/DC converter from described power supply, described vice-side winding is used for providing the electric energy after described adjustment to described light source, described auxiliary winding is used for powering to described color-temperature controller, described mains switch is coupling between described power supply and described AC/DC converter.

9. light source driving circuit according to claim 1, it is characterized in that, described color-temperature controller flows through the current monitor signal of the current value of described light source for receiving instruction, and controls the electric energy after being provided to the adjustment of described light source according to described current monitor signal.

10. a color-temperature controller, is characterized in that, described color-temperature controller comprises:

Driver element, flows through the current monitor signal of the current value of light source for receiving instruction and produces drive singal according to described current monitor signal and control electric power converter and provide the electric energy after adjustment to described light source; And

Control unit, be coupled in described driver element, for receiving the switch monitors signal of the operation of the mains switch in the circuit of instruction former limit, and based on the colour temperature of the described light source in described switch monitors signal adjustment secondary circuit, wherein said mains switch is coupling between power supply and described electric power converter.

11. color-temperature controller according to claim 10, it is characterized in that, described light source comprises first light-emitting component with the first color temperature value and second light-emitting component with the second color temperature value, described control unit produces the first control signal and the second control signal according to described switch monitors signal, described first control signal is optionally connected the first control switch be coupling between described color-temperature controller and described first light-emitting component and is adjusted to described first color temperature value to make the colour temperature of described light source, described second control signal is optionally connected the second control switch be coupling between described color-temperature controller and described second light-emitting component and is adjusted to described second color temperature value to make the colour temperature of described light source.

12. color-temperature controller according to claim 11, is characterized in that, described control unit comprises:

Timer, for receiving described switch monitors signal, and starting timing when trailing edge appears in described switch monitors signal, after the time predefined interval of described trailing edge, producing pulse signal;

First d type flip flop, for receiving described pulse signal; And

Second d type flip flop, is coupled in described first d type flip flop, for receiving described switch monitors signal;

Wherein said first control signal and described second control signal are output signal based on described second d type flip flop and produce.

13. color-temperature controller according to claim 10, it is characterized in that, described color-temperature controller also comprises identifying unit, described identifying unit is for detecting the energy state of described color-temperature controller and the described energy state based on described color-temperature controller produces the first decision signal and the second decision signal, and described color-temperature controller adjusts the colour temperature of described light source based on described first decision signal, described second decision signal and described switch monitors signal.

14. color-temperature controller according to claim 10, it is characterized in that, if the time interval between the opening operation of mains switch described in described switch monitors signal designation and next making operation is less than predetermined time interval, then the colour temperature of described light source is adjusted to the second color temperature value from the first color temperature value in response to next making operation described in described mains switch by described color-temperature controller.

15. color-temperature controller according to claim 14, it is characterized in that, described light source comprises first light-emitting component with described first color temperature value and second light-emitting component with described second color temperature value, described color-temperature controller adjusts the colour temperature of described light source by producing the first control signal and the second control signal, when described first control signal connects the first control switch be coupling between described color-temperature controller and described first light-emitting component, electric current flows through described first light-emitting component and the colour temperature of described light source is adjusted to described first color temperature value; When described second control signal connects the second control switch be coupling between described color-temperature controller and described second light-emitting component, electric current flows through described second light-emitting component and the colour temperature of described light source is adjusted to described second color temperature value.

16. color-temperature controller according to claim 10, it is characterized in that, if between the opening operation of mains switch described in described switch monitors signal designation and next making operation interval greater than predetermined time interval, then the colour temperature of described light source is reset to preset color temperature value in response to next making operation described in described mains switch by described color-temperature controller.

17. 1 kinds of methods controlling light source color temperature, it is characterized in that, the method for described control light source color temperature comprises the following steps:

Receive electric energy from power supply and provide the electric energy after adjustment by electric power converter to described light source;

Receive the switch monitors signal that instruction is coupling in the operation of the mains switch between described power supply and described electric power converter; And

The colour temperature of described light source is adjusted based on described switch monitors signal.

The method of 18. control light source color temperatures according to claim 17, is characterized in that, the described colour temperature adjusting described light source based on described switch monitors signal comprises the following steps:

If the time interval between the opening operation of mains switch described in described switch monitors signal designation and next making operation is less than predetermined time interval, then in response to next making operation described in described mains switch, the colour temperature of described light source is adjusted to the second color temperature value from the first color temperature value.

The method of 19. control light source color temperatures according to claim 17, is characterized in that, the described colour temperature adjusting described light source based on described switch monitors signal comprises the following steps:

If between the opening operation of mains switch described in described switch monitors signal designation and next making operation interval greater than predetermined time interval, then in response to next making operation described in described mains switch, the colour temperature of described light source is reset to preset color temperature value.

The method of 20. control light source color temperatures according to claim 17, is characterized in that, the described colour temperature adjusting described light source based on described switch monitors signal comprises the following steps:

In the interim very first time, produce the first control signal to connect first light-emitting component with the first color temperature value and produce the second control signal to disconnect second light-emitting component with the second color temperature value and be adjusted to described first color temperature value to make the colour temperature of described light source; And

During second time interval being different from described very first time interval, produce described first control signal and be adjusted to described second color temperature value to connect described second light-emitting component to make the colour temperature of described light source to disconnect described first light-emitting component and to produce described second control signal.