CN203734885U - LED driving device and control circuit and output current detection circuit thereof - Google Patents

Abstract

The embodiment of the utility model discloses LED drive arrangement and control circuit and output current sampling circuit thereof. The LED driving device comprises at least one switching tube, and the average current of the LED lamp is adjusted by controlling the on and off of the at least one switching tube through a control signal. The LED output current sampling circuit comprises a switch current sampling circuit, a logic ground and a control circuit, wherein the switch current sampling circuit is coupled between at least one switch and the logic ground, samples the switch current flowing through the at least one switch and outputs a sampling signal; and the current estimation circuit is coupled with the switch current sampling circuit, receives the sampling signal and estimates the average current of the LED according to the sampling signal. The output current sampling circuit directly estimates the average current of the LED lamp by collecting the current of the switch tube, and avoids directly collecting the current of the LED lamp.

Description

LED drive unit and control circuit thereof and output current detection circuit

Technical field

The disclosed embodiment of the utility model relates to a kind of electronic circuit, relates in particular to a kind of LED drive unit and control circuit and output current detection circuit.

Background technology

In the application of LED general illumination, often adopt the LED drive scheme of AC-DC (AC-DC) Power supply, this scheme comprises isolated form and non-isolation type.

In isolated form LED drive circuit, anti exciting converter (FLYBACK) LED drive circuit as shown in Figure 1, AC-input voltage V _aCby being converted to direct voltage V after rectification circuit _dC, direct voltage V _dCcarry out voltage transformation by anti exciting converter, and then driving LED lamp.The LED lamp here can be single LEDs, or the LED of plurality of LEDs composition string, goes here and there the LED array forming again or by multiple LED.Drive in control at LED, need to be to the average current I of LED lamp _lEDcarry out constant current control, still due to the buffer action of transformer, secondary average current I samples _lEDneed the devices with high costs such as optocoupler.

In non-isolation type LED drive circuit, buck converter (BUCK) LED drive circuit as shown in Figure 2, because LED lamp is by AC-input voltage V _aCdirect current signal V after rectification _dCdirectly power supply, therefore the voltage on LED lamp is very high, directly gathers the average current I of LED lamp _lEDinfeasible.

Utility model content

For one or more problems of the prior art, embodiment of the present utility model provides a kind of LED drive unit and control circuit and output current detection circuit

According to some embodiment, a kind of control circuit for LED drive unit is provided, wherein, this LED drive unit comprises rectification circuit and switching circuit, rectification circuit receives AC-input voltage signal, and AC-input voltage signal is carried out rectification and produces d. c. voltage signal, switching circuit comprises at least one switching tube, described switching circuit receives d. c. voltage signal, regulate the average current of LED lamp by the turn-on and turn-off of at least one switching tube of control signal control, wherein, control circuit comprises: switched-current sampled circuit, be coupled in described at least one switch and logically between, sample streams is crossed the electric current of described at least one switch, and export the first sampled signal, electric current estimation circuit, has input and output, and the input of electric current estimation circuit receives the first sampled signal, and the first sampled signal is converted to the feedback signal that characterizes LED average current, error amplifying circuit, there is first input end, the second input and output, first input end couples the output of electric current estimation circuit, receiving feedback signals, the second input receives reference signal, error amplifying circuit amplifies the difference of feedback signal and reference signal, and at output output error signal, comparison circuit, has first input end, the second input and output, and first input end couples the output of error amplifying circuit, receives error signal, the second input couples sample circuit, receives sampled signal, and comparison circuit compares the value of sampled signal and error signal, and at output output comparison signal, zero cross detection circuit, sampling inductive current, output the second sampled signal, and by the second sampled signal and the comparison of zero passage threshold value, output zero passage comparison signal, logical circuit, there is first input end, the second input and output, first input end couples the output of comparison circuit, receive comparison signal, the second input couples zero cross detection circuit, receive zero passage comparison signal, logical circuit does logical operation to comparison signal and zero passage comparison signal, and exports the turn-on and turn-off of at least one switch of control signal control at output.

According to some embodiment, described electric current estimation circuit comprises: voltage conversion circuit, there is input and output, and the input of described voltage conversion circuit is as the input of electric current estimation circuit, receive the first sampled signal, and the first sampled signal is converted to the first voltage signal; Filter circuit, have input and output, the output of described filter circuit is as the output of electric current estimation circuit, and the input of described filter circuit receives the first voltage signal, and to the first voltage signal filtering, output characterizes the feedback signal of LED average current.

According to some embodiment, described voltage conversion circuit comprises buffer, the first switch, second switch, electric capacity, the first resistance and the second resistance, wherein, buffer has first input end, the second input and output, the first input end of buffer is coupled to the input of voltage conversion circuit by the first switch, the second input of buffer is connected to ground by second switch and resistance, and the output of buffer is coupled to the output of voltage conversion circuit; The first switch has first end, the second end and control end, the first end of the first switch couples the input of voltage conversion circuit, the second end of the first switch couples the first input end of buffer, the control end reception control signal of the first switch, make the conducting in the time of at least one switch conduction of the first switch, in the time that at least one switch turn-offs, turn-off; Second switch has first end, the second end and control end, the first end of second switch couples the second input of buffer, the second end of second switch couples the second resistance, the control end coupling reception control signal of second switch, make second switch conducting in the time of at least one switch conduction, in the time that at least one switch is disconnected, turn-off; The first electric capacity, be coupled in the first input end of buffer and logically between; The first resistance, is coupled between second input and the output of buffer of buffer; The second resistance, be coupled in the second end of second switch and logically between;

According to some embodiment, described filter circuit comprises: the second electric capacity, be coupled to the input of filter circuit and logically between; The 3rd resistance, is coupled between the input and output of filter circuit.

According to some embodiment, the utility model provides a kind of LED drive unit, and wherein, LED drive unit comprises control circuit as above.

According to some embodiment, the utility model provides a kind of current detection circuit for LED drive circuit, wherein, LED drive circuit comprises at least one switching tube, regulates the average current size of LED lamp, wherein by the turn-on and turn-off of at least one switching tube of control signal control, described current sampling circuit comprises: switched-current sampled circuit, be coupled in described at least one switch and logically between, sample streams is crossed the electric current of described at least one switch, and exports the first sampled signal; Electric current estimation circuit, couples switched-current sampled circuit, receives the first sampled signal, and the first sampled signal is converted to the feedback signal that characterizes LED average current.

According to some embodiment, wherein electric current estimation circuit comprises: voltage conversion circuit, there is input and output, and the input of described voltage conversion circuit is as the input of electric current estimation circuit, receive the first sampled signal, and the first sampled signal is converted to the first voltage signal; Filter circuit, have input and output, the output of described filter circuit is as the output of electric current estimation circuit, and the input of described filter circuit receives the first voltage signal, and to the first voltage signal filtering, output characterizes the feedback signal of LED average current.

According to some embodiment, wherein said voltage conversion circuit comprises buffer, the first switch, second switch, electric capacity, the first resistance and the second resistance, wherein, buffer has first input end, the second input and output, the first input end of buffer is coupled to the input of voltage conversion circuit by the first switch, the second input of buffer is connected to ground by second switch and resistance, and the output of buffer is coupled to the output of voltage conversion circuit; The first switch has first end, the second end and control end, the first end of the first switch couples the input of voltage conversion circuit, the second end of the first switch couples the first input end of buffer, the control end reception control signal of the first switch, make the conducting in the time of at least one switch conduction of the first switch, in the time that at least one switch turn-offs, turn-off; Second switch has first end, the second end and control end, the first end of second switch couples the second input of buffer, the second end of second switch couples the second resistance, the control end of second switch couples control signal, make second switch conducting in the time of at least one switch conduction, in the time that at least one switch is disconnected, turn-off; The first electric capacity, be coupled in the first input end of buffer and logically between; The first resistance, is coupled between second input and the output of buffer of buffer; The second resistance, be coupled in the second end of second switch and logically between;

According to some embodiment, wherein filter circuit comprises: the second electric capacity, be coupled to the input of filter circuit and logically between; The 3rd resistance, is coupled between the input and output of filter circuit.

According to some embodiment, wherein switched-current sampled circuit comprises sampling resistor.

Brief description of the drawings

Figure 1 shows that existing anti exciting converter LED drive circuit topology.

Figure 2 shows that existing buck converter LED drive circuit topology.

Figure 3 shows that according to the LED drive circuit schematic block diagram of the utility model one embodiment.

Figure 4 shows that according to the LED drive circuit schematic diagram of the utility model one embodiment.

Figure 5 shows that according to the oscillogram of the utility model middle parameters embodiment illustrated in fig. 4.

In institute's drawings attached, identical label represents to have identical, similar or corresponding feature or function.

Embodiment

To describe specific embodiment of the present disclosure below in detail, it should be noted that the embodiments described herein, only for illustrating, is not limited to the disclosure.On the contrary, the disclosure is intended to contain defined various alternatives, modification and equivalent in the disclosure spirit and scope that defined by claims.In the following description, in order to provide thorough understanding of the present disclosure, a large amount of specific detail have been set forth.But, there is no these details for it should be understood by one skilled in the art that, the disclosure can be implemented equally.In some other embodiment, for the ease of highlighting purport of the present disclosure, be not explained in detail for well-known scheme, flow process, components and parts and circuit or method.

Figure 3 shows that according to the schematic block diagram of the LED drive circuit 100 of the utility model one embodiment.LED drive circuit 100 shown in Fig. 3 is operated in critical conduction mode of operation, comprises rectification circuit 70, switching circuit 60 and control circuit.

Rectification circuit 70 receives ac voltage signal V _aC, and by ac voltage signal V _aCrectification, output dc voltage signal V _dC.

Switching circuit 60 comprises at least one switching tube M1, and switching circuit 60 receives d. c. voltage signal V _dC, and by the conducting and the average current I that turn-offs adjusting LED lamp of this at least one switching tube M1 _lED.In the embodiment shown in fig. 3, signal is that switching circuit 60 is by d. c. voltage signal V _dCbe converted to output voltage signal V _oUTand then driving LED lamp, in other embodiments, LED lamp also can with d. c. voltage signal V _dCdirectly be connected.In one embodiment, switching circuit 60 is a non-isolation type buck converter; In another embodiment, switching circuit 60 is an isolated form buck converter; In other embodiments, switching circuit 60 can be also other suitable topological structures.

Control circuit comprises switched-current sampled circuit (not shown), electric current estimation circuit 10, error amplifying circuit 20, comparison circuit 30, zero cross detection circuit 40 and logical circuit 50 that the electric current of switching tube M1 is sampled.The electric current of switched-current sampled circuit sampling switching tube M1, and pass through electric current estimation circuit 10 by switching tube electric current I _sbe equivalent to the average current I of LED lamp _lED.Control circuit is by control switch current I _s, just can realize the average current I to LED lamp _lEDconstant current control.

In one embodiment, switched-current sampled circuit couples switching tube M1 and logically between GND, sample streams is crossed the switching current of switching tube M1, and output switch current sampling signal V _cS.In one embodiment, by switching tube M1 be logically connected in series a sampling resistor, sampling switch electric current I between GND _s, and then obtain switched-current sampled signal V _cS.

Electric current estimation circuit 10 has input and output, and input couples switching circuit 60, receiving key current sampling signal V _cS, this switched-current sampled signal V _cSthe electric current of switching tube M1 is flow through in representative, and electric current estimation circuit 10 is passed through switch current sampling signal V _cSprocessing, represent the average current I of LED lamp in output output _lEDfeedback signal FB.In one embodiment, above-mentioned switched-current sampled circuit and output circuit electric current estimation circuit 10 can form output current detection circuit, for detection of the output current of LED drive circuit.

Error amplifying circuit 20 has first input end, the second input and output.First input end couples the output of electric current estimation circuit 10, receiving feedback signals FB; The second input receives reference signal REF, and wherein reference signal REF characterizes the LED lamp average current I expecting _lED; Error amplifying circuit 20 amplifies the difference of feedback signal FB and reference signal REF, and at output output error signal EA.

Comparison circuit 30 has first input end, the second input and output.Its first input end couples the output of error amplifying circuit 20, receives error signal EA; The second input receiving key current sampling signal V _cS; Comparison circuit 30 is switched-current sampled signal V relatively _cSwith the value of error signal EA, and at output output comparison signal CA.As switched-current sampled signal V _cSwhile being greater than error signal EA, switching tube M1 turn-offs.

The sampled signal CS2 of inductive current in zero cross detection circuit 40 receiving key circuit 60, and by sampled signal CS2 and threshold value comparison, at output output zero passage comparison signal ZCD, for judging the zero crossing of inductive current, in the time that inductive current equals zero, zero passage comparison signal ZCD starts actuating switch pipe M1.In one embodiment, such as in the isolated form LED drive circuit with transformer, transformer has the first winding and the second winding, zero cross detection circuit by pulling out one group of auxiliary winding as tertiary winding sensing the first winding current on transformer, and by zero-crossing comparator by sampling the first winding electric flow valuve and the comparison of zero passage threshold value, thereby obtain zero passage comparison signal ZCD.In another embodiment, such as in non-isolation BUCK type LED drive circuit, zero cross detection circuit is crossed the electric current of inductor as tertiary winding senses flow by pull out one group of auxiliary winding on inductor, and by zero-crossing comparator by sampling the inductive current value that flows through inductor and the comparison of zero passage threshold value, thereby obtain zero passage comparison signal ZCD.

Logical circuit 50 has first input end, the second input and output, and the first input end of logical circuit 50 couples the output of comparison circuit 30, receives comparison signal CA; The second input of logical circuit 50 couples zero cross detection circuit 40, and receives zero passage comparison signal ZCD; Logical circuit 50 does logical operation to comparison signal CA and zero passage comparison signal ZCD, and is used for the turn-on and turn-off of control switch pipe M1 at output output control signal CTRL, and then regulates the average current I of LED lamp _lED.

Figure 4 shows that according to the circuit theory diagrams of the LED drive circuit 200 of the utility model one embodiment.In embodiment as shown in Figure 4, switching circuit is a non-isolated buck (BUCK) type translation circuit, comprises inductor L, capacitor C _d, diode D and switching tube M1.But it will be appreciated by those skilled in the art that in other embodiments, switching circuit can comprise other circuit topological structures, such as isolated form flyback (FLYBACK) translation circuit etc.

As shown in Figure 4, rectification circuit 70 comprises four rectifier diodes, receives ac voltage signal V _aC, and by ac voltage signal V _aCrectification, output dc voltage signal V _dC.In other embodiments, rectification circuit 70 also can comprise the rectifier diode of other numbers, for example two.

As in the embodiment shown in fig. 4, control circuit comprises switched-current sampled circuit, electric current estimation circuit, error amplifying circuit, comparison circuit, zero cross detection circuit and logical circuit that the electric current of switching tube M1 is sampled.

In the embodiment shown in fig. 4, LED light fixture has first end and the second end, and its first end couples the output of rectification circuit 70, receives d. c. voltage signal V _dC, its second end couples one end of inductance L; Capacitor C _dfirst end couple the first end of LED lamp, capacitor C _dthe second end couple the other end of inductance L; The negative electrode of diode D couples the first end of LED lamp, and the anode of diode couples the other end of inductance L; Switching tube M1 is a metal semiconductor oxide field-effect pipe (MOSFET), have source electrode, drain and gate, its drain electrode couples the anode of diode D, and its source electrode is coupled to logically GND, its grid is coupled to the output of logical circuit, reception control signal CTRL.

In the embodiment shown in fig. 4, switched-current sampled circuit comprises a sampling resistor R _s, this sampling resistor R _sbe connected in series in switching tube M1 and logically between GND, sampling resistor R _sone end and the source electrode of switching tube M1 couple and form node CS, switched-current sampled signal V _cSrepresent the voltage of node CS, that is: V _cS=R _s× I _s.

In the embodiment shown in fig. 4, electric current estimation circuit 10 has input 11 and output 12, and the input 11 of electric current estimation circuit 10 couples node CS, receiving key current sampling signal V _cS; Electric current estimation circuit 10 is to switch current sampling signal V _cSprocess, and characterize the average current signal I of LED lamp in output 12 outputs _lEDfeedback signal FB, the average current signal I of feedback signal FB and LED lamp _lEDlinearly proportional, in one embodiment, FB=2 × I _lED× R _s.

Electric current estimation circuit 10 comprises voltage conversion circuit 110 and filter circuit 120.Voltage conversion circuit 110 has input 13 and output 14, and the input 13 of voltage conversion circuit 110 couples input 11 and the node CS of electric current estimation circuit 10, receives the electric current I that characterizes switching tube M1 _sswitched-current sampled signal V _cS, and by switched-current sampled signal V _cSchange, at the output 14 output voltage signal V of voltage conversion circuit 110 _eQ.Filter circuit 120 has input 15 and output 16, and the input 15 of filter circuit 120 couples the output 14 of voltage conversion circuit 110, and the output 16 of filter circuit 120 couples the output 12 of electric current estimation circuit 10.The input 15 receiver voltage signal V of filter circuit 120 _eQ, and to voltage signal V _eQcarry out filtering, be used for the feedback signal FB of feedback control loop in output 16 outputs of filter circuit 120, feedback signal FB equals voltage signal V _eQmean value, now, feedback signal FB characterizes the average current signal I of LED lamp _lED.In the embodiment shown in fig. 4, voltage conversion circuit 110 comprises the first switch S 1, second switch S2, the first capacitor C 1, buffer 12, the first resistance R 1 and the second resistance R 2.

Buffer 12 has first input end 121, the second input 122 and output 123, and the first end 121 of buffer 12 couples the input 13 of voltage conversion circuit 110 and the input 11 of electric current estimation circuit by the first switch S 1; The second input 122 of buffer 12 couples the output 123 of buffer 12 by the first resistance R 1; The output 123 of buffer 12 couples the output 14 of voltage conversion circuit and the input 15 of filter circuit 120.In one embodiment, buffer comprises an operational amplifier.

The first switch S 1 has first end 101 and the second end 102 and control end, and the first end 101 of the first switch S 1 couples the input 13 of voltage conversion circuit 110 and the input 11 of electric current estimation circuit; The second end 102 of the first switch S 1 couples the first input end 121 of buffer 12; The control end of the first switch S 1 couples the output 53 of trigger FF1, and reception control signal CTRL makes the conducting in the time of switching tube M1 conducting of the first switch S 1, in the time that switching tube M1 turn-offs, turn-offs.The first capacitor C 1 is coupled in the first input end 121 of buffer 12 and logically between GND.The in the situation that of the first switch S 1 conducting, the first input end 121 receiving key current sampling signal V of buffer _cS, meanwhile, the first capacitor C 1 is charged to switched-current sampled signal V _cSmaximum V _c1; In the situation that the first switch S 1 is turn-offed, the first input end 121 of buffer 12 receives the voltage V that the first capacitor C 1 provides _c1.

Second switch S2 has first end 131 and the second end 132 and control end, and the first end 131 of second switch S2 couples the second input 122 of buffer 12; The second end 132 of second switch S2 couples one end of the second resistance R 2; The control end of second switch S2 couples the output 53 of trigger FF1, and reception control signal CTRL makes second switch S2 conducting in the time of switching tube M1 conducting, in the time that switching tube M1 turn-offs, turn-offs.The second resistance R 2 is coupled in the second end 132 of second switch S2 and logically between GND, the first resistance R 1 is coupled between second input 122 and output 123 of buffer 12.The in the situation that of second switch S2 conducting, the voltage signal V of voltage conversion circuit 110 outputs 14 _eQequal switched-current sampled signal V _cStwice, i.e. V _eQ=2V _cS; In the situation that second switch S2 turn-offs, the voltage V of voltage conversion circuit 110 outputs 14 _eQequal the voltage V in the first capacitor C 1 _c1, i.e. V _eQ=V _c1.

Filter circuit 120 comprises the second capacitor C 0 and the 3rd resistance R 0.The second capacitor C 0 is coupled in the input 15 of filter circuit 120 and logically between GND, the 3rd resistance R 0 is coupled between the input 15 and output 16 of filter circuit 120.The voltage signal V that filter circuit 120 receiver voltage change-over circuits 110 are exported _eQ, to its filtering, and export representative voltage signal V at output 16 _eQthe feedback signal FB of mean value.In some other embodiment, filter circuit 120 has other forms of structure.Such as, in one embodiment, filter circuit 120 comprises the filter circuit network being made up of multiple resistance and multiple electric capacity, in another embodiment, the value size of the second capacitor C 0 and the 3rd resistance R 0 is adjustable.

Continue referring to Fig. 4, in the embodiment shown in fig. 4, error amplifying circuit comprises error amplifier COM1, and error amplifier COM1 has first input end 21, the second input 22 and output 23.First input end 21 receives reference signal REF, and wherein reference signal REF characterizes the LED lamp average current I expecting _lED; Its second input couples the output 12 of electric current estimation circuit 10, receiving feedback signals FB; Error amplifier COM1 amplifies the difference of feedback signal FB and reference signal REF, and at output 23 output error signal EA.

In the embodiment shown in fig. 4, comparison circuit comprises comparator C OM2, and comparator C OM2 has first input end 31, the second input 32 and output 33.Its first input end 31 couples the output of error amplifier COM1, receives error amplification signal EA; The second input couples node CS, receiving key current sampling signal V _cS; Comparator C OM2 is switched-current sampled signal V relatively _cSwith the value of error signal EA, and at output output comparison signal CA.As switched-current sampled signal V _cSwhile being greater than error signal EA, switching tube M1 turn-offs.

In the embodiment shown in fig. 4, zero cross detection circuit comprises inductive current sample circuit and zero-crossing comparator COM3.Inductive current sample circuit sampling inductive current, and inductive current sampled signal CS2 is provided.Zero-crossing comparator COM3 has first input end 41, the second input 42 and output 43.Its first input end 41 receiving inductance current sampling signal CS2; The second input 42 receives zero passage threshold signal V _tH; The output 43 of zero-crossing comparator COM3 is exported zero passage comparison signal ZCD.When detecting that inductive current sampled signal CS2 equals zero passage threshold signal V _tHtime, zero passage comparison signal ZCD is for actuating switch pipe M1.In the embodiment shown in fig. 4, inductive current sample circuit comprises auxiliary winding L _pand voltage grading resistor.

In the embodiment shown in fig. 4, logical circuit comprises trigger FF1, and trigger FF1 has first input end 51, the second input 52 and output 53, and the first input end 51 of trigger FF1 couples the output 33 of comparator C OM2, receives comparison signal CA; The second input 52 of trigger FF1 couples zero-crossing comparator COM3, receives zero passage comparison signal ZCD; Trigger FF1 does logical operation to comparison signal CA and zero passage comparison signal ZCD, and exports the turn-on and turn-off of control signal CTRL for control switch pipe M1 at output 53, and then regulates the average current I of LED lamp _lED.

Figure 5 shows that according to the oscillogram of the utility model middle parameters embodiment illustrated in fig. 4.As shown in Figure 5, when control signal CTRL is logic when high, that is to say main switch M1 conduction period, the first switch S 1 in voltage conversion circuit 110 and the equal conducting of second switch S2, switched-current sampled signal V _cSlinearity rises to maximum V _c1, the voltage V of voltage conversion circuit 110 outputs 14 _eQequal switched-current sampled signal V _cStwice, i.e. 2V _cS; In the time that control signal CTRL is logic low, that is to say main switch M1 blocking interval, the first switch S 1 in voltage conversion circuit 110 and second switch S2 turn-off, switched-current sampled signal V _cSequal zero, the voltage V of voltage conversion circuit 110 outputs 14 _eQequal the input voltage signal V of electric current estimation circuit 10 _cSmaximum V _c1.Voltage signal V _eQafter filtering after circuit 120 filtering, V _eQaverage voltage equal switched-current sampled signal V _cSpeak value V _c1.Also be that feedback signal FB equals switched-current sampled signal V _cSpeak value V _c1, FB=I _pEAK× R _s=2 × I _lED× R _s.

Reference signal REF=2 × I is set _lED× R _s, feedback signal FB follows reference signal REF, according to average current signal I _lEDneeds, by different reference signal REF is set, directly gather switching tube electric current and just can control the average current I of LED lamp _lED.

In another embodiment, if driven in utilization at LED lamp, its demanded power output is higher than 25W, and LED driver is faced with the problem of power factor correction (PFC).In the embodiment shown in fig. 4, also need to add a multiplier, multiplier receives input voltage V _dCsampled signal and the output signal EA of error amplifier COM1, and two signals are carried out to multiplication, produce one with input voltage V _dCsynchronous reference signal, makes input current follow the tracks of input voltage, realizes the function of power factor correction.

Those skilled in the art should also be understood that term used in disclosure illustrated embodiment is explanation and exemplary and nonrestrictive term.Because the disclosure can specifically be implemented in a variety of forms and not depart from spirit or the essence of utility model, so be to be understood that, above-described embodiment is not limited to any aforesaid details, and explain widely in the spirit and scope that should limit in the claim of enclosing, therefore fall into whole variations in claim or its equivalent scope and remodeling and all should be the claim of enclosing and contain.

Claims (10)

1. the control circuit for LED drive unit, it is characterized in that, this LED drive unit comprises rectification circuit and switching circuit, rectification circuit receives AC-input voltage signal, and AC-input voltage signal is carried out rectification and produces d. c. voltage signal, switching circuit comprises at least one switching tube, described switching circuit receives d. c. voltage signal, the average current that regulates LED lamp by the turn-on and turn-off of at least one switching tube of control signal control, control circuit comprises:

Switched-current sampled circuit, be coupled in described at least one switch and logically between, sample streams is crossed the electric current of described at least one switch, and exports the first sampled signal;

Electric current estimation circuit, has input and output, and the input of electric current estimation circuit receives the first sampled signal, and the first sampled signal is converted to the feedback signal that characterizes LED average current;

Error amplifying circuit, there is first input end, the second input and output, first input end couples the output of electric current estimation circuit, receiving feedback signals, the second input receives reference signal, error amplifying circuit amplifies the difference of feedback signal and reference signal, and at output output error signal;

Comparison circuit, has first input end, the second input and output, and first input end couples the output of error amplifying circuit, receives error signal; The second input couples sample circuit, receives sampled signal, and comparison circuit compares the value of sampled signal and error signal, and at output output comparison signal;

Zero cross detection circuit, sampling inductive current, output the second sampled signal, and by the second sampled signal and the comparison of zero passage threshold value, output zero passage comparison signal;

Logical circuit, there is first input end, the second input and output, first input end couples the output of comparison circuit, receive comparison signal, the second input couples zero cross detection circuit, receive zero passage comparison signal, logical circuit does logical operation to comparison signal and zero passage comparison signal, and exports the turn-on and turn-off of at least one switch of control signal control at output.

2. control circuit as claimed in claim 1, is characterized in that, electric current estimation circuit comprises:

Voltage conversion circuit, has input and output, and the input of described voltage conversion circuit, as the input of electric current estimation circuit, receives the first sampled signal, and the first sampled signal is converted to the first voltage signal;

Filter circuit, have input and output, the output of described filter circuit is as the output of electric current estimation circuit, and the input of described filter circuit receives the first voltage signal, and to the first voltage signal filtering, output characterizes the feedback signal of LED average current.

3. control circuit as claimed in claim 2, is characterized in that, described voltage conversion circuit comprises buffer, the first switch, second switch, electric capacity, the first resistance and the second resistance, wherein,

Buffer has first input end, the second input and output, the first input end of buffer is coupled to the input of voltage conversion circuit by the first switch, the second input of buffer is connected to ground by second switch and resistance, and the output of buffer is coupled to the output of voltage conversion circuit;

The first switch has first end, the second end and control end, the first end of the first switch couples the input of voltage conversion circuit, the second end of the first switch couples the first input end of buffer, the control end reception control signal of the first switch, make the conducting in the time of at least one switch conduction of the first switch, in the time that at least one switch turn-offs, turn-off;

Second switch has first end, the second end and control end, the first end of second switch couples the second input of buffer, the second end of second switch couples the second resistance, the control end coupling reception control signal of second switch, make second switch conducting in the time of at least one switch conduction, in the time that at least one switch is disconnected, turn-off;

The first electric capacity, be coupled in the first input end of buffer and logically between;

The first resistance, is coupled between second input and the output of buffer of buffer;

The second resistance, be coupled in the second end of second switch and logically between.

4. control circuit as claimed in claim 2, is characterized in that, filter circuit comprises:

The second electric capacity, be coupled to the input of filter circuit and logically between;

The 3rd resistance, is coupled between the input and output of filter circuit.

5. a LED drive unit, is characterized in that, comprises the control circuit as described in claim 1-4.

6. the output current detection circuit for LED drive circuit, it is characterized in that, LED drive circuit comprises at least one switching tube, regulates the average current size of LED lamp by the turn-on and turn-off of at least one switching tube of control signal control, wherein, described current sampling circuit comprises:

Switched-current sampled circuit, be coupled in described at least one switch and logically between, sample streams is crossed the electric current of described at least one switch, and exports the first sampled signal;

Electric current estimation circuit, couples switched-current sampled circuit, receives the first sampled signal, and the first sampled signal is converted to the feedback signal that characterizes LED average current.

7. output current detection circuit as claimed in claim 6, is characterized in that electric current estimation circuit comprises:

Voltage conversion circuit, has input and output, and the input of described voltage conversion circuit, as the input of electric current estimation circuit, receives the first sampled signal, and the first sampled signal is converted to the first voltage signal;

Filter circuit, have input and output, the output of described filter circuit is as the output of electric current estimation circuit, and the input of described filter circuit receives the first voltage signal, and to the first voltage signal filtering, output characterizes the feedback signal of LED average current.

8. output current detection circuit as claimed in claim 7, is characterized in that described voltage conversion circuit comprises buffer, the first switch, second switch, electric capacity, the first resistance and the second resistance, wherein,

Buffer has first input end, the second input and output, the first input end of buffer is coupled to the input of voltage conversion circuit by the first switch, the second input of buffer is connected to ground by second switch and resistance, and the output of buffer is coupled to the output of voltage conversion circuit;

The first switch has first end, the second end and control end, the first end of the first switch couples the input of voltage conversion circuit, the second end of the first switch couples the first input end of buffer, the control end reception control signal of the first switch, make the conducting in the time of at least one switch conduction of the first switch, in the time that at least one switch turn-offs, turn-off;

Second switch has first end, the second end and control end, the first end of second switch couples the second input of buffer, the second end of second switch couples the second resistance, the control end of second switch couples control signal, make second switch conducting in the time of at least one switch conduction, in the time that at least one switch is disconnected, turn-off;

The first electric capacity, be coupled in the first input end of buffer and logically between;

The first resistance, is coupled between second input and the output of buffer of buffer;

The second resistance, be coupled in the second end of second switch and logically between.

9. output current detection circuit as claimed in claim 7, is characterized in that filter circuit comprises:

The second electric capacity, be coupled to the input of filter circuit and logically between;

The 3rd resistance, is coupled between the input and output of filter circuit.

10. output current detection circuit as claimed in claim 6, is characterized in that switched-current sampled circuit comprises sampling resistor.