CN100574079C - Inverter and driving method thereof and light-emitting device and the LCD TV of having used it - Google Patents

Inverter and driving method thereof and light-emitting device and the LCD TV of having used it Download PDF

Info

Publication number
CN100574079C
CN100574079C CN 200680013163 CN200680013163A CN100574079C CN 100574079 C CN100574079 C CN 100574079C CN 200680013163 CN200680013163 CN 200680013163 CN 200680013163 A CN200680013163 A CN 200680013163A CN 100574079 C CN100574079 C CN 100574079C
Authority
CN
China
Prior art keywords
mentioned
side transistor
voltage
triangular signal
during
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
CN 200680013163
Other languages
Chinese (zh)
Other versions
CN101164222A (en
Inventor
福本宪一
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Rohm Co Ltd
Original Assignee
Rohm Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Rohm Co Ltd filed Critical Rohm Co Ltd
Publication of CN101164222A publication Critical patent/CN101164222A/en
Application granted granted Critical
Publication of CN100574079C publication Critical patent/CN100574079C/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • Y02B20/202

Landscapes

  • Inverter Devices (AREA)
  • Circuit Arrangements For Discharge Lamps (AREA)

Abstract

Moment of configuration switch neatly in inverter.Based on triangular signal (Vosc) and error voltage (Verr) control H bridge circuit.At this moment, arrive to triangular signal error voltage the 1st during make the 1st high-side transistor (MH1) and the 2nd low side transistors (ML2) conducting.Arrive to triangular signal peak edge the 2nd during make the 1st high-side transistor (MH1) conducting.Arrive to triangular signal the edge floors the 3rd during make the 2nd high-side transistor (MH2) conducting.Arrive once more to triangular signal error voltage the 4th during make the 1st low side transistors (ML1) and the 2nd high-side transistor (MH2) conducting.Arrive once more to triangular signal peak edge the 5th during make the 2nd high-side transistor (MH2) conducting.Arrive once more to triangular signal the edge floors the 6th during make the 1st high-side transistor (MH1) conducting.

Description

Inverter and driving method thereof and light-emitting device and the LCD TV of having used it
Technical field
The present invention relates to fluorescent lamp etc. is provided the inverter of driving voltage, particularly the type of drive of inverter.
Background technology
In recent years, can realize that LCD TV slim, that maximize is just replacing cathode-ray tube TV and popularizes gradually.LCD TV is at many cold-cathode fluorescence lamp (Cold Cathode Fluorescent Lamp of the back side of the liquid crystal display screen of show image configuration, to call CCFL in the following text) or external electrode fluorescent lamp (External Electrode Fluorescent Lamp, to call EEFL in the following text), make it luminous as backlight.
For carrying out the driving of CCFL or EEFL, for example use that the direct voltage about 12V boosts, the inverter of exporting as alternating voltage (DC/AC transducer).The current conversion that inverter will flow through CCFL becomes Voltage Feedback to give control circuit, comes connection, the disconnection of control switch element based on the voltage of this feedback.For example, such fluorescent lamp drive technology based on inverter is disclosed in the patent documentation 1.
Patent documentation 1: the spy opens the 2003-323994 communique
Summary of the invention
(inventing problem to be solved)
For generating the alternating voltage after boosting by inverter, need provide switching voltage, energy accumulation off and on to the primary winding of transformer.For the primary winding to transformer applies switching voltage, adopt the structure that four switching transistors is configured to be known as H bridge circuit or full-bridge (full bridge) circuit sometimes, and the two ends of primary winding are applied the method for switching voltage.
1. when using such H bridge circuit to generate switching voltage, each switching transistor conducting, the moment that ends can produce a very large impact the efficient of inverter.In addition, in the switching transistor that constitutes the H bridge circuit, be connected in series in the pair of transistor between input voltage and ground connection, carry out switch control dead time (dead time) so need be provided with if conducting simultaneously then can be flow through perforation electric current.
2. in addition, for the conducting of switching transistor, end, the grid potential of MOSFET or the base current of bipolar transistor are changed.Under the situation of MOSFET, change for making grid potential, need discharge and recharge grid capacitance, so if transistorized size is bigger, then the needed time of the transformation of grid potential is elongated.As a result, after indication ends to certain transistor, become to the actual gate current potential and to end, sometimes generation time of delay to a certain degree.If transistorized conducting, the moment that ends postpone, then constitute the just conducting simultaneously of pair of transistor of being connected in series in the switching transistor of H bridge circuit, flow through perforation electric current.
The present invention designs in view of such problem, and one of its purpose is to provide a kind of can set the conducting of the switching transistor of the inverter that has used the H bridge circuit, the inverter of deadline neatly.
In addition, other purposes of the present invention are to provide a kind of inverter that can prevent to produce perforation electric current in the inverter that has used the H bridge circuit.
(being used to solve the means of problem)
1. the inverter of a scheme of the present invention comprises: transformer; The 1st high-side transistor, the one end links to each other with the input terminal that is applied in input voltage, and the other end links to each other with the 1st terminal of the primary winding of transformer; The current potential fixed terminal that the 1st low side transistors, one end and current potential have been fixed links to each other, and the other end links to each other with the 1st terminal of primary winding; The 2nd high-side transistor, the one end links to each other with input terminal, and the other end links to each other with the 2nd terminal of primary winding; The 2nd low side transistors, the one end links to each other with above-mentioned current potential fixed terminal, and the other end links to each other with the 2nd terminal of primary winding; Current-voltage conversion portion changes the electrorheological of the secondary coil of transformer into voltage, as detecting voltage output; The triangular signal generating unit generates triangular signal; Error amplifier, the corresponding error voltage of error of output and detection voltage and the reference voltage of being scheduled to; Logic control portion based on from the error voltage of error amplifier output and the triangular signal that is generated by the triangular signal generating unit, controls the conducting of the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors and ends.Logic control portion triangular signal arrive from the edge floors error voltage the 1st during make the 1st high-side transistor and the 2nd low side transistors conducting, ensuing arrive to triangular signal peak edge the 2nd during make the 1st high-side transistor conducting, and above-mentioned the 2nd high-side transistor is ended, ensuing arrive to triangular signal the edge floors the 3rd during make the 2nd high-side transistor conducting, ensuing arrive once more to triangular signal error voltage the 4th during make the 1st low side transistors and the 2nd high-side transistor conducting, ensuing arrive once more to triangular signal peak edge the 5th during make the 2nd high-side transistor conducting, and above-mentioned the 1st high-side transistor is ended, ensuing arrive once more to triangular signal the edge floors the 6th during make the 1st high-side transistor conducting.
In this scheme, cross the electric current of the secondary coil of transformer by monitor flows, and compare with triangular signal, drive the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors that constitute the H bridge circuit.As a result, by regulating the shape of triangular signal, the moment that can regulate each transistorized conducting, ends.
Logic control portion can be during the 5th in, arrive in error voltage rises during through the 1st predetermined deadline at triangular signal, the 1st high-side transistor is ended, after through the 1st deadline, make the 1st high-side transistor conducting.
If continue to make the 1st high-side transistor to end in during the 5th, then electric current can flow through the body diode (parasitic diode) of the 1st high-side transistor, so can produce the voltage drop of forward voltage Vf amount, it is big that power loss can become.Therefore, during the 5th in, through making the 1st high-side transistor conducting after the 1st predetermined deadline, can make the electric current that flows through body diode flow through the 1st high-side transistor thus, thereby can reduce power loss.In addition, by the 1st deadline of suitable setting, can prevent the conducting simultaneously of the 1st high-side transistor and the 1st low side transistors and flow through perforation electric current.
Logic control portion can be during the 2nd in, arrive in error voltage rises during through the 2nd predetermined deadline at triangular signal, the 2nd high-side transistor is ended, after through the 2nd deadline, make the 2nd high-side transistor conducting.
If continue to make the 2nd high-side transistor to end in during the 2nd, then electric current can flow through body diode, and it is big that power loss can become.Therefore, after through the 2nd predetermined deadline, make the 2nd high-side transistor switch to conducting, can reduce power loss thus.In addition, by the 2nd deadline of suitable setting, can prevent the conducting simultaneously of the 2nd high-side transistor and the 2nd low side transistors and flow through perforation electric current.
The fringe time of triangular signal from the edge floors to peak edge can be set in 2 times to the 100 times scopes of fringe time, preferably set in 5 times to 15 times scopes from peak edge to the edge floors.At this moment, can set distribution well at the dead time of conduction time of primary winding and non-conduction time.
Logic control portion can make the counter-rotating of peak edge and edge floors, control the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors conducting, end.In addition, can constitute the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors with MOSFET.
Triangular signal generating unit, error amplifier, logic control portion can be integrated on a Semiconductor substrate.So-called " integrating ", all structure important documents that comprise circuit all are formed on the situation on the Semiconductor substrate, and the primary structure important document of circuit situation about being integrated, also can a part of resistance, electric capacity etc. be arranged on the outside of Semiconductor substrate for the regulating circuit constant.By these circuit elements being integrated into a LSI, can reduce circuit area.
Another program of the present invention is a light-emitting device.This light-emitting device comprises: fluorescent lamp; Fluorescent lamp is provided the above-mentioned inverter of driving voltage.Inverter can have two, is separately positioned on the two ends of fluorescent lamp, and driving voltage inverting each other is provided.In addition, fluorescent lamp can be the cold-cathode tube fluorescent lamp, also can be external electrode fluorescent lamp.
By this scheme,, can improve the efficient of device integral body because can regulate the efficient of inverter and the luminous efficiency of fluorescent lamp.
Another scheme of the present invention is a LCD TV.This LCD TV comprises: liquid crystal display screen; Be configured in a plurality of above-mentioned light-emitting device at the back side of liquid crystal display screen.
2. the inverter of another program of the present invention comprises: transformer; The 1st high-side transistor, the one end links to each other with the input terminal that is applied in input voltage, and the other end links to each other with the 1st terminal of the primary winding of transformer; The current potential fixed terminal that the 1st low side transistors, one end and current potential have been fixed links to each other, and the other end links to each other with the 1st terminal of primary winding; The 2nd high-side transistor, the one end links to each other with input terminal, and the other end links to each other with the 2nd terminal of primary winding; The 2nd low side transistors, the one end links to each other with the current potential fixed terminal, and the other end links to each other with the 2nd terminal of primary winding; Pulse-width modulator monitors the electric current of the secondary coil of transformer to generate the pulse width modulating signal that utilizes the feedback regulation pulse duration, makes the electric current of this secondary coil near the predetermined current value; Logic control portion based on the pulse width modulating signal that is generated by pulse-width modulator, controls the conducting of the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors and ends.Logic control portion comprises: time control part, output indication the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors conducting separately, the control signal of ending; The 1st comparator, the 1st switching voltage that the 1st terminal of primary winding is presented compares with the 1st predetermined threshold voltage, and output becomes the 1st comparison signal of predetermined level when the 1st switching voltage is higher than the 1st threshold voltage; Pre-driver, based on the control signal that generates by the time control part with from the 1st comparison signal of the 1st comparator output, control the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors conducting, end.The control signal that pre-driver will be generated by the time control part and to carry out logic from the 1st comparison signal of the 1st comparator output synthetic is being instructed to make the 1st high-side transistor conducting, and the 1st comparison signal makes the 1st high-side transistor conducting when being predetermined level.
After the 1st low side transistors was ended, the 1st switching voltage can be from jumping near the earthing potential near the input voltage.Therefore, monitor the 1st switching voltage, become be higher than the 1st predetermined threshold voltage after, indicate the 1st high-side transistor conducting, can prevent the conducting simultaneously of the 1st high-side transistor and the 1st low side transistors thus, can prevent the generation of perforation electric current.
After the time control part can rise through the 1st predetermined deadline in the control signal that output indication the 1st low side transistors is ended, the control signal of output indication the 1st high-side transistor conducting.
Logic control portion can also comprise the 2nd comparator, the 2nd comparator compares the 2nd terminal the 2nd switching voltage that is presented and the 2nd threshold voltage of being scheduled to of primary winding, and output becomes the 2nd comparison signal of predetermined level when the 2nd switching voltage is higher than the 2nd threshold voltage.After the time control part can rise through the 2nd predetermined deadline in the control signal that output indication the 2nd low side transistors is ended, the control signal of output indication the 2nd high-side transistor conducting, pre-driver is being instructed to make the 2nd high-side transistor conducting, and when the 2nd comparison signal is predetermined level, make the 2nd high-side transistor conducting.
After the 2nd low side transistors was ended, the 2nd switching voltage can be from jumping near the earthing potential near the input voltage.Therefore, monitor the 2nd switching voltage, become be higher than the 2nd predetermined threshold voltage after, indicate the 2nd high-side transistor conducting, can prevent the conducting simultaneously of the 2nd high-side transistor and the 2nd low side transistors thus, can prevent the generation of perforation electric current.
The time control part is exported the control signal of indication the 2nd high-side transistor conducting after the control signal that output indication the 2nd low side transistors is ended rises through the 2nd predetermined deadline.
Pulse-width modulator can comprise: error amplifier, and output and the corresponding error voltage of error that detects voltage and predetermined reference voltage, described detection voltage is the electric current relevant detection voltage with the secondary coil of transformer; The triangular signal generating unit generates triangular signal; Pwm comparator compares triangular signal and error voltage, the output pulse width modulation signal.The time control part can triangular signal arrive from the edge floors error voltage during, the control signal of output indication the 1st high-side transistor and the 2nd low side transistors conducting, then to during through the 2nd deadline, the control signal of output indication the 1st high-side transistor conducting, then during triangular signal arrival peak edge, the control signal of output indication the 1st high-side transistor and the 2nd high-side transistor conducting, then during triangular signal arrival edge floors, the control signal of output indication the 2nd high-side transistor conducting, then arrive once more to triangular signal error voltage during, the control signal of output indication the 1st low side transistors and the 2nd high-side transistor conducting, then to during through the 1st deadline, the control signal of output indication the 2nd high-side transistor conducting, then arrive once more to triangular signal peak edge during, the control signal of output indication the 1st high-side transistor and the 2nd high-side transistor conducting, then arrive once more to triangular signal the edge floors during, the control signal of output indication the 1st high-side transistor conducting, so repeatedly.
The fringe time of triangular signal from the edge floors to peak edge can be set in 2 times to the 100 times scopes of fringe time, preferably set in 5 times to 15 times scopes from peak edge to the edge floors.At this moment, can set distribution well at the dead time of conduction time of primary winding and non-conduction time.
The time control part of logic control portion can make peak edge and the counter-rotating of above-mentioned edge floors, exports control signal.In addition, can constitute the 1st, the 2nd high-side transistor and the 1st, the 2nd low side transistors with MOSFET.
Pulse-width modulator and logic control portion can be integrated on a Semiconductor substrate.By these circuit being integrated into a LSI, can reduce circuit area.
Another program of the present invention is a light-emitting device.This light-emitting device comprises: fluorescent lamp; Fluorescent lamp is provided the above-mentioned inverter of driving voltage.Inverter can have two, is separately positioned on the two ends of fluorescent lamp, and driving voltage inverting each other is provided.In addition, fluorescent lamp can be a cold-cathode fluorescence lamp, also can be external electrode fluorescent lamp.
Another scheme of the present invention is a LCD TV.This LCD TV comprises: liquid crystal display screen; Be configured in a plurality of above-mentioned light-emitting device at the back side of liquid crystal display screen.
In above-mentioned inverter, owing to suppressed the generation of perforation electric current, so can improve the reliability of light-emitting device, LCD TV.
The driving method of inverter of the present invention, comprise: change the electrorheological of the secondary coil of transformer into voltage, convert the step that detects voltage to, generate and the step of above-mentioned detection voltage with the corresponding error voltage of error of the reference voltage of being scheduled to, and based on above-mentioned error voltage and triangular signal, control constitutes the 1st high-side transistor, the 2nd high-side transistor and the 1st low side transistors of H bridge circuit, the conducting of the 2nd low side transistors, the controlled step of ending; Wherein, in above-mentioned controlled step, above-mentioned triangular signal arrive from the edge floors above-mentioned error voltage the 1st during make above-mentioned the 1st high-side transistor and above-mentioned the 2nd low side transistors conducting, ensuing above-mentioned triangular signal arrive peak edge the 2nd during make above-mentioned the 1st high-side transistor conducting, and above-mentioned the 2nd high-side transistor is ended, ensuing above-mentioned triangular signal arrive the edge floors the 3rd during make above-mentioned the 2nd high-side transistor conducting, ensuing above-mentioned triangular signal arrive once more above-mentioned error voltage the 4th during make above-mentioned the 1st low side transistors and above-mentioned the 2nd high-side transistor conducting, ensuing above-mentioned triangular signal arrive once more peak edge the 5th during make above-mentioned the 2nd high-side transistor conducting, and above-mentioned the 1st high-side transistor is ended, ensuing above-mentioned triangular signal arrive once more the edge floors the 6th during make above-mentioned the 1st high-side transistor conducting.
In addition, with the scheme of the combination in any of above inscape, inscape of the present invention and expression way phase double replacement between method, device, system etc., also be effective as embodiments of the present invention.
(invention effect)
By the inverter of a scheme of the present invention, can set conducting, the deadline of the switching transistor of the inverter that has used the H bridge circuit neatly, perhaps can prevent to produce perforation electric current.
Description of drawings
Fig. 1 is the circuit diagram of structure of the light-emitting device of expression the 1st execution mode.
Fig. 2 is the block diagram of structure of LCD TV of the light-emitting device of expression installation diagram 1, Fig. 8.
Fig. 3 is the circuit diagram of structure of the control circuit of expression the 1st execution mode.
Fig. 4 is the circuit diagram of the structure example of expression triangular signal generating unit.
(a)~(h) of Fig. 5 is the sequential chart of operate condition of the inverter of presentation graphs 1.
(a)~(f) of Fig. 6 is the circuit diagram of current direction of H bridge circuit of the inverter of presentation graphs 1.
Fig. 7 is the sequential chart of operate condition of the inverter of expression variation.
Fig. 8 is the circuit diagram of structure of the light-emitting device of expression the 2nd execution mode.
Fig. 9 is the circuit diagram of structure of the control circuit of expression the 2nd execution mode.
(a)~(i) of Figure 10 is the sequential chart of the operate condition of expression inverter.
(a)~(f) of Figure 11 is the circuit diagram of current direction of H bridge circuit of the inverter of presentation graphs 8.
(a)~(e) of Figure 12 is the sequential chart of inverter of the time of delay of Fig. 8 more in short-term.
(a)~(e) of Figure 13 is the sequential chart of inverter of the time of delay of Fig. 8 when longer.
Embodiment
Below, based on preferred embodiment, with reference to description of drawings the present invention.Mark identical label for inscape, parts, the processing identical or that be equal to shown in each accompanying drawing, and suitably the repetitive description thereof will be omitted.In addition, execution mode is an illustration, and non-limiting the present invention, and all features recorded and narrated in the execution mode and combination thereof not necessarily are exactly substantive characteristics of the present invention.
(the 1st execution mode)
In the 1st execution mode, explanation can be set conducting, the inverter of deadline and the control circuit thereof of the switching transistor of the inverter that has used the H bridge circuit neatly.
Fig. 1 is the circuit diagram of structure of the light-emitting device 200 of expression embodiment of the present invention.Fig. 2 is the block diagram of structure of LCD TV 300 of the light-emitting device 200 of expression installation diagram 1.LCD TV 300 is connected with antenna 310.Antenna 310 receives broadcast wave, to acceptance division 304 output received signals.Acceptance division 304 carries out detection, amplification to received signal, exports to signal processing part 306.Signal processing part 306 will carry out the demodulation acquired image data to modulated data and output to liquid crystal driver 308.Liquid crystal driver 308 is exported to liquid crystal display screen 302 with view data by each scan line, display video, image.At the back side of liquid crystal display screen 302,, a plurality of light-emitting devices 200 are installed as backlight.The light-emitting device 200 of present embodiment can be very suitably uses as the backlight of such liquid crystal display screen 302.Below, get back to Fig. 1, describe the structure and the action of light-emitting device 200 in detail.
The light-emitting device 200 of present embodiment comprises EEFL210, the 1st inverter 100a, the 2nd inverter 100b.EEFL210 is configured in the back side of liquid crystal display screen 302.The 1st inverter 100a, the 2nd inverter 100b are the DC/AC transducers, to be transformed into alternating voltage from the input voltage vin of DC power supply output and boost, the 1st terminal the 212, the 2nd terminal 214 to EEFL210 provides the 1st driving voltage Vdrv1, the 2nd driving voltage Vdrv2 respectively.The 1st driving voltage Vdrv1, the 2nd driving voltage Vdrv2 are alternating voltages inverting each other.
In Fig. 1, represented an EEFL210, but also can in parallelly dispose a plurality of.Below, the 1st inverter 100a of execution mode, the structure of the 2nd inverter 100b are described.The 1st inverter 100a, the 2nd inverter 100b are same structures, do not describe so below the two is not done to be referred to as inverter 100 with distinguishing.
Inverter 100 comprises H bridge circuit 10, transformer 12, current-voltage conversion portion 14, control circuit 20, capacitor C 10.
H bridge circuit 10 comprises the 1st high-side transistor (high side transistor) MH1, the 1st low side transistors (low side transistor) ML1, these four power transistors (power transistor) of the 2nd high-side transistor MH2, the 2nd low side transistors ML2.
The 1st high-side transistor MH1 one end is connected with the input terminal 102 that is applied in input voltage, and the other end is connected with the 1st terminal of the primary winding 12a of transformer 12.The earth terminal that the 1st low side transistors ML1 one end and current potential have been fixed is connected, and the other end is connected with the 1st terminal of primary winding 12a.The 2nd high-side transistor MH2 one end is connected with input terminal 102, and the other end is via being used to stop the capacitor C 10 of direct current to be connected with the 2nd terminal of primary winding.The 2nd low side transistors ML2 one end is connected with earth terminal, and the other end is via being used to stop the capacitor C 10 of direct current to be connected with the 2nd terminal of primary winding 12a.
Current-voltage conversion portion 14 is set between the secondary coil 12b and ground connection of transformer 12.The electrorheological that current-voltage conversion portion 14 will flow through the electric current of secondary coil 12b, promptly flow through EEFL210 changes voltage into, as detecting voltage Vdet ' output.Current-voltage conversion portion 14 comprises rectification circuit 16, filter 18.
Rectification circuit 16 comprises the 1st diode D1, the 2nd diode D2, resistance R 1.The 1st diode D1 plus earth, negative electrode links to each other with the end of secondary coil 12b.The anode of the 2nd diode D2 links to each other with the negative electrode of the 1st diode D1.Resistance R 1 is set between the negative electrode and ground connection of the 2nd diode D2.The alternating current that flows through secondary coil 12b is flowed to resistance R 1 by the 1st diode D1, the 2nd diode D2 halfwave rectifier.Produce on the resistance R 1 and the proportional voltage drop of electric current of flowing through secondary coil 12b.Rectification circuit 16 is exported the voltage drop that produces on the resistance R 1 as detecting voltage Vdet.
Filter 18 is the low pass filters that comprise resistance R 2, capacitor C 1.Filter 18 will have been removed the detection voltage Vdet ' that detects the radio-frequency component of voltage Vdet and feed back to control circuit 20.
Control circuit 20 is based on the detection voltage Vdet ' that is fed back, and the 1st high-side transistor MH1, the 1st low side transistors ML1 of control H bridge circuit 10, the conducting of the 2nd high-side transistor MH2, the 2nd low side transistors ML2, ends.By the control of H bridge circuit 10, provide switching voltage to the primary winding 12a of transformer 12.Its result carries out power conversion with transformer 12, provides the 1st driving voltage Vdrv1 to the EEFL210 that links to each other with secondary coil 12b.
The following describes the structure of control circuit 20.Fig. 3 is the circuit diagram of structure of the control circuit 20 of expression the 1st execution mode.Control circuit 20 comprises error amplifier 22, PWM comparator 24, triangular signal generating unit 30, logic control portion 40, is integrated the function IC on a Semiconductor substrate.
Non-inverting input of error amplifier 22 is transfused to from the next detection voltage Vdet ' of current-voltage conversion portion 14 feedbacks, and reversed input terminal is transfused to predetermined reference voltage V ref.Reference voltage V ref decides according to the luminosity of EEFL210.Error amplifier 22 outputs and the corresponding error voltage Verr of error that detects voltage Vdet ' and reference voltage V ref.
Triangular signal generating unit 30 generates the wavy triangular signal Vosc of triangle of preset frequency.Fig. 4 is the circuit diagram of the structure example of expression triangular signal generating unit 30.Triangular signal generating unit 30 comprises the 1st comparator the 32, the 2nd comparator 34, rest-set flip-flop the 36, the 1st constant current supply 38a, the 2nd constant current supply 38b, capacitor C 2.
This triangular signal generating unit 30 is general structures, so only its structure of simple declaration and action.The 1st constant current supply 38a is the current source that is used for capacitor C 2 chargings of an end ground connection, and the 2nd constant current supply 38b is the current source that is used to make capacitor C 2 discharges.The voltage that capacitor C 2 is presented is used as triangular signal Vosc output.
The maximum voltage Vmax of the peak value of the triangular signal that the current potential of 32 couples of triangular signal Vosc of the 1st comparator and setting should be exported compares.The 1st comparator 32 is the output high level when Vosc>Vmax.In addition, the 2nd comparator 34 compares the current potential of the triangular signal Vosc minimum voltage Vmin with the floors of setting the triangular signal that should export.The 2nd comparator 34 is the output high level when Vosc<Vmin.
The output signal of the 1st comparator the 32, the 2nd comparator 34 is imported into set terminal, the reseting terminal of rest-set flip-flop 36 respectively.The output signal Vq of rest-set flip-flop 36 is output to the 1st constant current supply 38a, and reversed-phase output signal * Vq is output to the 2nd constant current supply 38b.The 1st constant current supply 38a connects during for high level at output signal Vq, by constant current Ic1 to capacitor C 2 chargings.In addition, the 2nd constant current supply 38b connects during for high level at reversed-phase output signal * Vq, makes capacitor C 2 discharges by constant current Ic2.
Be configured to the triangular signal Vosc that Vmax, floors voltage are configured to Vmin from the triangular signal generating unit 30 output crest voltages of above such formation.In addition, the output signal Vq of rest-set flip-flop 36 is output to logic control portion 40 as periodic signal.In addition, triangular signal generating unit 30 also can use hysteresis comparator to constitute.
Get back to Fig. 3.24 pairs of PWM comparators compare from the error voltage Verr of error amplifier 22 outputs with from the triangular signal Vosc of triangular signal generating unit 30 outputs, become high level when being created on Verr<Vosc, become low level pulse width modulating signal (to call pwm signal in the following text) Vpwm when Verr>Vosc.This pwm signal Vpwm is imported into logic control portion 40 with triangular signal Vosc, periodic signal Vq.
Logic control portion 40 is based on pwm signal Vpwm, triangular signal Vosc, periodic signal Vq, the 1st high-side transistor MH1, the 1st low side transistors ML1 of control H bridge circuit 10, the conducting of the 2nd high-side transistor MH2, the 2nd low side transistors ML2, ends.The following describes logic control portion 40.
Logic control portion 40 is 1 with two cycles from the triangular signal Vosc of triangular signal generating unit 30 output and controls H bridge circuit 10 circularly.Specifically, be divided into the 1st~the 6th six in two cycles with triangular signal Vosc during, carry out switch control.(a)~(h) of Fig. 5 is the sequential chart of the operate condition of expression inverter 100.(a) expression error voltage Verr and the triangular signal Vosc of Fig. 5, (b) expression pwm signal Vpwm of this figure, the signal Vq of (c) indication cycle of this figure, (d)~(g) of this figure represents the state of the 1st high-side transistor MH1, the 2nd high-side transistor MH2, the 1st low side transistors ML1, the 2nd low side transistors ML2 respectively, the current potential Vsw of the 1st terminal of the primary winding 12a of (h) indication transformer 12 of this figure.In (d)~(g) of this figure, high level is represented the state of transistor turns, and low level is represented the state that transistor ends.In addition, in the figure, the longitudinal axis and transverse axis are suitably amplified, have been dwindled for convenience of explanation.
At first, be described during the 1st cutting apart of φ 6 during the φ the 1 to the 6th.Logic control portion 40 with triangular signal Vosc from its edge floors (bottom edge) to reach error voltage Verr during as φ 1 during the 1st.With next to triangular signal Vosc arrive peak edge during as φ 2 during the 2nd.With next to triangular signal Vosc arrive the edge floors during as φ 3 during the 3rd.With next to triangular signal Vosc arrive once more error voltage Verr during as φ 4 during the 4th.With next to triangular signal Vosc arrive once more peak edge during as φ 5 during the 5th.With next to triangular signal Vosc arrive once more the edge floors during as φ 6 during the 6th.This is cut apart and can constitute with general logical circuit based on pwm signal Vpwm and periodic signal Vq.
Next, φ 6 during the φ during the 1st the 1 to the 6th is described, the transistorized conducting of H bridge circuit 10, cut-off state.
Logic control portion 40 makes the 1st high-side transistor MH1 and the 2nd low side transistors ML2 conducting among the φ 1 during the 1st, other transistors are ended.During the ensuing the 2nd, among the φ 2, make the 1st high-side transistor MH1 conducting, other transistors are ended.During the ensuing the 3rd, among the φ 3, make the 2nd high-side transistor MH2 conducting, other transistors are ended.During the ensuing the 4th, among the φ 4, make the 1st low side transistors ML1 and the 2nd high-side transistor MH2 conducting, other transistors are ended.During the ensuing the 5th, among the φ 5, make the 2nd high-side transistor MH2 conducting, other transistors are ended.During the ensuing the 6th, among the φ 6, make the 1st high-side transistor MH1 conducting, other transistors are ended.Then, turn back to the 1st during φ 1.
The following describes the action of the inverter 100 of the present embodiment that as above constitutes like that.(a) of Fig. 6 is the circuit diagram of current direction of H bridge circuit 10 of the inverter 100 of expression present embodiment to (f).(a) of Fig. 6 represents during the 1st the state of each transistorized conducting, cut-off state and the coil current Isw of φ 6 during φ 1~6th respectively to (f).
Shown in Fig. 6 (a), during the 1st among the φ 1, the 1st high-side transistor MH1, the 2nd low side transistors ML2 conducting.Its result, coil current Isw flow through the path of the 1st high-side transistor MH1, primary winding 12a, the 2nd low side transistors ML2.The switching voltage Vsw of this moment becomes the voltage almost equal with input voltage vin.In the φ 1, it is big that coil current Isw slowly becomes during the 1st.
Among the φ 2, shown in Fig. 6 (b), the 2nd low side transistors ML2 is cut off during the ensuing the 2nd, only the 1st high-side transistor MH1 conducting.Its result based on the energy of savings in primary winding 12a, flows through regenerative current in the body diode of the 2nd high-side transistor MH2 (body diode).During this, switching voltage Vsw keeps the voltage almost equal with input voltage.
Next during the 3rd among the φ 3, shown in Fig. 6 (c), the 2nd high-side transistor MH2 is switched into conducting, and the 1st high-side transistor MH1 is cut off.At this moment, the coil current Isw that during the 2nd, provides from the 1st high-side transistor MH1 among the φ 2, the body diode that becomes via the 1st low side transistors ML 1 provides from ground connection.The switching voltage Vsw of φ 3 becomes the negative value than the forward voltage Vf of the body diode of low the 1st low side transistors ML1 of earthing potential (0V) during the 3rd.In addition, at the energy of 1 savings of φ during the 1st in primary winding 12a, all be sent to secondary coil 12b among the φ 3 during the 3rd, coil current Isw becomes 0.
Among the φ 4, shown in Fig. 6 (d), keep under the state of conducting at the 2nd high-side transistor MH2 during the ensuing the 4th, the 1st low side transistors ML1 is switched to conducting.At this moment, switching voltage Vsw is fixed near the earthing potential.In addition, coil current Isw flows left from the right side of primary winding 12a by the path of the 2nd high-side transistor MH2, primary winding 12a, the 1st low side transistors ML1.φ 4 during the 4th, and it is big that coil current Isw slowly becomes.
During the ensuing the 5th, among the φ 5, shown in Fig. 6 (e), keep the 2nd high-side transistor MH2 conducting ground, the 1st low side transistors ML1 switched to end.As a result, the coil current Isw that flows through the 1st low side transistors ML1 during the 4th among the φ 4 becomes the body diode that flows through the 1st high-side transistor MH1.The switching voltage Vsw of this moment becomes the voltage than the forward voltage Vf of the high body diode of input voltage vin.
Among the φ 6, shown in Fig. 6 (f), the 1st high-side transistor MH1 is switched to conducting during the ensuing the 6th, and the 2nd high-side transistor MH2 is cut off.At this moment, the coil current Isw that during the 5th, provides from the 2nd high-side transistor MH2 among the φ 5, the body diode that becomes via the 2nd low side transistors ML2 provides from ground connection.The switching voltage Vsw of φ 6 becomes with input voltage vin almost equal during the 6th.φ 4 is accumulated in the energy among the primary winding 12a during the 4th, all is sent to secondary coil 12b during the 6th among the φ 6, and coil current Isw becomes 0.
According to the inverter 100 of present embodiment, by the electric current that flows through among the secondary coil 12b that monitors transformer 12, and compare with triangular signal Vosc, drive the transistor that constitutes H bridge circuit 10.Therefore, by regulating the shape of triangular signal Vosc, the moment that can regulate each transistorized conducting neatly, ends.
For example, in the present embodiment, during the 1st during the φ the 1, the 4th length of φ 4 depend on gradient when the edge floors of triangular signal Vosc changes peak edge into.This gradient can make it to change by regulate constant current Ic1 in the triangular signal generating unit 30 of Fig. 4.
In addition, in the present embodiment, from the peak edge of triangular signal Vosc to the tour of edge floors being φ 6 during the φ 3 and the 6th during the 3rd.For the length of φ 6 during the φ 3 and the 6th during the 3rd, in the triangular signal generating unit 30 of Fig. 4, can make it to change by regulating constant current Ic2.
Here, the energy of savings in primary winding 12a depends on during the 1st the length of φ 4 during the φ the 1, the 4th.In addition, the energy of being put aside among the φ 4 during the φ the 1, the 4th during the 1st is sent to secondary coil 12b among the φ 6 during the φ 3 and the 6th during the 3rd.Therefore, by regulating shape and the cycle of triangular signal Vosc, can drive efficiently according to the characteristic of transformer 12 with as the characteristic of the EEFL210 of driven object.
In addition, preferably the fringe time of triangular signal Vosc from the edge floors to peak edge is set at 2 times~100 times scopes of fringe time, is more preferably 5 times~15 times scopes that are set at from peak edge to the edge floors.Which as for setting value for, get final product according to the decisions such as characteristic of triangle wave frequency and transformer.By design triangular signal Vosc in this scope, can carry out high efficiency driving.
Execution mode is an illustration, can carry out various distortion to the combination of each inscape and variety of processes, and those skilled in the art can understand these variation and also be in the scope of the present invention.
For example, as the control of the H bridge circuit 10 of logic-based control part 40, consider to have following variation.
In this variation, logic control portion 40 is during the 5th among the φ 5, triangular signal Vosc reach error voltage Verr rise to through predetermined the 1st deadline Toff1 during in, the 1st high-side transistor MH1 is ended, through making the 1st high-side transistor MH1 conducting the 1st deadline behind the Toff1.
And then, logic control portion 40 reaches error voltage Verr at triangular signal Vosc to rise, to through predetermined the 2nd deadline Toff2 during in the 2nd high-side transistor MH2 is ended, through making the 2nd high-side transistor MH2 conducting the 2nd deadline behind the Toff2.For the 1st deadline Toff1, the 2nd deadline Toff2, can set in the 200ns degree at 50ns according to the cycle of triangular signal Vosc.
(a)~(e) of Fig. 7 is the sequential chart of operate condition of the inverter 100 of expression variation.The conducting cut-off state of (a) expression the 1st high-side transistor MH1 of Fig. 7, the conducting cut-off state of (b) expression the 2nd high-side transistor MH2 of Fig. 7, the conducting cut-off state of (c) expression the 1st low side transistors ML1 of Fig. 7, the conducting cut-off state of (d) expression the 2nd low side transistors ML2 of Fig. 7, (e) expression switching voltage Vsw of Fig. 7.
If the 2nd high-side transistor MH2 continues to end among the φ 5 during the 5th, then coil current Isw flows through the body diode (parasitic diode) of the 2nd high-side transistor MH2, so produce the voltage drop of forward voltage Vf size, it is big that power loss becomes.Therefore, in this variation, make the 1st high-side transistor MH1 conducting the 1st deadline that process is scheduled in the φ 5 during the 5th behind the Toff1.Its result, shown in Fig. 7 (e), switching voltage Vsw is through dropping to input voltage vin behind the Toff1 the 1st deadline.At this moment, the coil current Isw that flows through the body diode of the 1st high-side transistor MH1 flows through the 1st high-side transistor MH1, so can reduce power loss.In addition, by suitable setting Toff1 the 1st deadline, can prevent the 1st high-side transistor MH1 and the 1st low side transistors ML1 conducting simultaneously and flow through perforation electric current.
Similarly, also be, then to cause power loss to become big among the φ 2 during the 2nd owing to its body diode flows through electric current if the 2nd high-side transistor MH2 continues to end.Therefore,, make among the 2nd high-side transistor MH2 and flow through electric current, can reduce power loss thus by through making the 2nd high-side transistor MH2 conducting behind the Toff2 the 2nd predetermined deadline.
The 1st deadline Toff1 and the 2nd section time T off2 get final product according to the characteristic decision of transformer 12, preferably in the scope of 150ns degree, set at 30ns.More preferably in the scope of 100ns, set, can reduce power loss like this at 50ns.
In the present embodiment, control circuit 20 can all integrate, and perhaps also can be that its part is made of discrete parts or chip part.In addition, control circuit 20 can comprise H bridge circuit 10 ground and is integrated.Which partly carries out the integrated of what degree as for, get final product according to decisions such as the specification of inverter 100, cost, area occupied.
In the present embodiment, the high level of logical circuit, the setting of low level logical value only are examples, can suitably reverse freely to change by utilizing inverter etc.For example, logic control portion 40 can be with the counter-rotating of peak edge and edge floors, control H bridge circuit 10 transistorized conducting, end.
In execution mode, the situation of the transistor of the high side in the transistor that will constitute H bridge circuit 10 with N-channel MOS FET formation has been described, but also can have used the P channel mosfet.
In execution mode, illustrated in light-emitting device 200, connect inverter 100 at the two ends of EEFL210, situation about driving with anti-phase driving voltage, but be not limited thereto.In addition, the fluorescent tube of driven object also is not limited to EEFL, can be other fluorescent tubes such as CCFL.In addition, the load that is driven by the inverter 100 of present embodiment is not limited to fluorescent tube, goes for the driving that other need the various devices of ac high voltage.
(the 2nd execution mode)
In the 2nd execution mode, the technology that is used for preventing at the inverter that has used the H bridge circuit perforation electric current is described.
Fig. 8 is the circuit diagram of structure of the light-emitting device 200 of expression the present invention the 2nd execution mode.The light-emitting device 200 of Fig. 8 is the same with the light-emitting device of Fig. 1, is installed in the LCD TV 300 of Fig. 2.
The light-emitting device 200 of the 2nd execution mode shown in Figure 8 comprises EEFL210, the 1st inverter 100a, the 2nd inverter 100b.EEFL210 is configured in the back side of liquid crystal display screen 302.The 1st inverter 100a, the 2nd inverter 100b are the DC/AC transducers, to be transformed into alternating voltage from the input voltage vin of DC power supply output and boost, the 1st terminal the 212, the 2nd terminal 214 to EEFL210 provides the 1st driving voltage Vdrv1, the 2nd driving voltage Vdrv2 respectively.The 1st driving voltage Vdrv1, the 2nd driving voltage Vdrv2 are alternating voltages inverting each other.
In Fig. 8, represented an EEFL210, but also can in parallelly dispose a plurality of.Below, the 1st inverter 100a of execution mode, the structure of the 2nd inverter 100b are described.The 1st inverter 100a, the 2nd inverter 100b are same structures, do not describe so below the two is not done to be referred to as inverter 100 with distinguishing.
Inverter 100 comprises H bridge circuit 10, transformer 12, current-voltage conversion portion 14, control circuit 20, capacitor C 10.
H bridge circuit 10 comprises the 1st high-side transistor MH1, the 1st low side transistors ML1, these four power transistors (powertransistor) of the 2nd high-side transistor MH2, the 2nd low side transistors ML2.
The 1st high-side transistor MH1 one end is connected with the input terminal 102 that is applied in input voltage, and the other end is connected with the 1st terminal of the primary winding 12a of transformer 12.The earth terminal that the 1st low side transistors ML1 one end and current potential have been fixed is connected, and the other end is connected with the 1st terminal of primary winding 12a.The 2nd high-side transistor MH2 one end is connected with input terminal 102, and the other end is via being used to stop the capacitor C 10 of direct current to be connected with the 2nd terminal of primary winding.The 2nd low side transistors ML2 one end is connected with earth terminal, and the other end is via being used to stop the capacitor C 10 of direct current to be connected with the 2nd terminal of primary winding 12a.
Below, the voltage of the 1st terminal of the primary winding 12a of transformer 12 is called the 1st switching voltage Vsw1, the voltage of the 2nd terminal is called the 2nd switching voltage Vsw2.
Current-voltage conversion portion 14 is set between the secondary coil 12b and ground connection of transformer 12.The electrorheological that current-voltage conversion portion 14 will flow through the electric current of secondary coil 12b, promptly flow through EEFL210 changes voltage into, as detecting voltage Vdet ' output.Current-voltage conversion portion 14 comprises rectification circuit 16, filter 18.
Rectification circuit 16 comprises the 1st diode D1, the 2nd diode D2, resistance R 1.The 1st diode D1 plus earth, negative electrode links to each other with the end of secondary coil 12b.The anode of the 2nd diode D2 links to each other with the negative electrode of the 1st diode D1.Resistance R 1 is set between the negative electrode and ground connection of the 2nd diode D2.The alternating current that flows through secondary coil 12b is flowed to resistance R 1 by the 1st diode D1, the 2nd diode D2 halfwave rectifier.Produce on the resistance R 1 and the proportional voltage drop of electric current of flowing through secondary coil 12b.Rectification circuit 16 is exported the voltage drop that produces on the resistance R 1 as detecting voltage Vdet.
Filter 18 is the low pass filters that comprise resistance R 2, capacitor C 1.Filter 18 will have been removed the voltage Vdet ' that detects the radio-frequency component of voltage Vdet and feed back to control circuit 20.
Control circuit 20 is based on the detection voltage Vdet ' that is fed back, the 1st switching voltage Vsw1, the 2nd switching voltage Vsw2, the 1st high-side transistor MH1, the 1st low side transistors ML1 of control H bridge circuit 10, the conducting of the 2nd high-side transistor MH2, the 2nd low side transistors ML2, ends.The control result of H bridge circuit 10 provides switching voltage to the primary winding 12a of transformer 12.As a result, carry out power conversion, provide the 1st driving voltage Vdrv1 to the EEFL210 that links to each other with secondary coil 12b with transformer 12.
The following describes the structure of control circuit 20.Fig. 9 is the circuit diagram of structure of the control circuit 20 of expression present embodiment.Control circuit 20 comprises pulse-width modulator 60, logic control portion 40, is integrated the function IC on a Semiconductor substrate.
Pulse-width modulator 60 monitors detection voltage Vdet ', is the electric current of the secondary coil 12b of transformer 12, generate to utilize feedback to come the pulse width modulating signal (to call pwm signal Vpwm in the following text) of regulating impulse width, make the electric current of this secondary coil near the predetermined current value.
Logic control portion 40 is based on the pwm signal Vpwm that is generated by pulse-width modulator 60, control the 1st high-side transistor MH1, the 2nd high-side transistor MH2, the 1st low side transistors ML1, the 2nd low side transistors ML2 conducting, end.
Pulse-width modulator 60 comprises error amplifier 22, PWM comparator 24, triangular signal generating unit 30.
Non-inverting input of error amplifier 22 is transfused to from the next detection voltage Vdet ' of current-voltage conversion portion 14 feedbacks, and reversed input terminal is transfused to predetermined reference voltage V ref.Reference voltage V ref decides according to the luminosity of EEFL210.Error amplifier 22 outputs and the corresponding error voltage Verr of error that detects voltage Vdet ' and reference voltage V ref.
Triangular signal generating unit 30 generates the wavy triangular signal Vosc of triangle of preset frequency.Fig. 4 is the circuit diagram of the structure example of expression triangular signal generating unit 30.Triangular signal generating unit 30 comprises comparator 32, comparator 34, rest-set flip-flop the 36, the 1st constant current supply 38a, the 2nd constant current supply 38b, capacitor C 2.
This triangular signal generating unit 30 is general structures, so only its structure of simple declaration and action.The 1st constant current supply 38a is the current source that is used for capacitor C 2 chargings of an end ground connection, and the 2nd constant current supply 38b is the current source that is used to make capacitor C 2 discharges.The voltage that capacitor C 2 is presented is used as triangular signal Vosc output.
The maximum voltage Vmax of the peak value of the triangular signal that the current potential of 32 couples of triangular signal Vosc of comparator and setting should be exported compares.Comparator 32 is the output high level when Vosc>Vmax.In addition, comparator 34 compares the current potential of the triangular signal Vosc minimum voltage Vmin with the floors of setting the triangular signal that should export.Comparator 34 is the output high level when Vosc<Vmin.
The output signal of comparator 32,34 is imported into set terminal, the reseting terminal of rest-set flip-flop 36 respectively.The output signal Vq of rest-set flip-flop 36 is output to the 1st constant current supply 38a, and reversed-phase output signal * Vq is output to the 2nd constant current supply 38b.The 1st constant current supply 38a connects during for high level at output signal Vq, by constant current Ic1 capacitor C 2 is charged.In addition, the 2nd constant current supply 38b connects during for high level at reversed-phase output signal * Vq, makes capacitor C 2 discharges by constant current Ic2.
Be configured to the triangular signal Vosc that Vmax, floors voltage are configured to Vmin from the triangular signal generating unit 30 output crest voltages of above such formation.In addition, the output signal Vq of rest-set flip-flop 36 is output to logic control portion 40 as periodic signal.In addition, triangular signal generating unit 30 also can constitute with hysteresis comparator.
Get back to Fig. 9.24 pairs of PWM comparators compare from the error voltage Verr of error amplifier 22 outputs with from the triangular signal Vosc of triangular signal generating unit 30 outputs, become high level when being created on Verr<Vosc, become low level pwm signal Vpwm when Verr>Vosc.This pwm signal Vpwm is imported into logic control portion 40 with triangular signal Vosc, periodic signal Vq.
Logic control portion 40 is based on pwm signal Vpwm, triangular signal Vosc, periodic signal Vq, the 1st high-side transistor MH1, the 1st low side transistors ML1 of control H bridge circuit 10, the conducting of the 2nd high-side transistor MH2, the 2nd low side transistors ML2, ends.The following describes logic control portion 40.
Logic control portion 40 comprises time control part the 42, the 1st comparator the 44, the 2nd comparator 46, pre-driver (pre-driver) 48.
Time control part 42 output indication the 1st high-side transistor MH1, the 2nd high-side transistor MH2, the 1st low side transistors ML1, the 2nd low side transistors ML2 conducting or the control signal SH1 that ends, SH2, SL1, SL2.
The 1st switching voltage Vsw1 that the 1st terminal of the primary winding 12a of 44 pairs of transformers 12 of the 1st comparator is presented and the 1st threshold voltage vt h1 that is scheduled to compare.The 1st comparison signal Vcmp1 of the 1st comparator 44 outputs when the 1st switching voltage Vsw1 is higher than the 1st threshold voltage vt h1, becoming high level.
In addition, the 2nd terminal of the primary winding 12a of 46 pairs of transformers 12 of the 2nd comparator the 2nd switching voltage Vsw2 that is presented and the 2nd threshold voltage vt h2 that is scheduled to compares.The 2nd comparison signal Vcmp2 of the 2nd comparator 46 outputs when the 2nd switching voltage Vsw2 is higher than the 2nd threshold voltage vt h2, becoming high level.
Pre-driver 48 is based on control signal SH1, SH2, SL1, SL2 from 42 outputs of time control part, with the 1st comparison signal Vcmp1 from 44 outputs of the 1st comparator, and, each transistorized conducting of control H bridge circuit 10, end from the 2nd comparison signal Vcmp2 of the 2nd comparator 46 output.
Pre-driver 48 comprises AND gate 70,72, to each transistorized grid output drive signal DH1, DH2, DL1, the DL2 of H bridge circuit 10.AND gate 70 is exported the logic product of control signal SH1 and the 1st comparison signal Vcmp1 as drive signal DH1.In addition, AND gate 72 is exported the logic product of control signal SH2 and the 2nd comparison signal Vcmp2 as drive signal DH2.The logical value of drive signal DL1 is identical with control signal SL1, and the logical value of drive signal DL2 is identical with control signal SL2.Drive signal DH1, DH2, DL1, DL2 are amplified by not shown buffer as required, output to H bridge circuit 10.
Next, the generation to the control signal SH1 in the time control part 42, SH2, SL1, SL2 describes.Time control part 42 is that 1 circulation generates the control signal that is used to control H bridge circuit 10 with two cycles from the triangular signal Vosc of triangular signal generating unit 30 output.More particularly, two cycles of triangular signal Vosc are divided into during the 1st during the φ the 1 to the 8th during eight of φ 8, carry out switch control.
(a)~(i) of Figure 10 is the sequential chart of the operate condition of expression inverter 100.(a) expression error voltage Verr and the triangular signal Vosc of Figure 10, (b) expression pwm signal Vpwm of this figure, the signal Vq of (c) indication cycle of this figure, this figure (d)~(g) represents control signal SH1, SH2, SL1, SL2 respectively.(h) of this figure, (i) represent the 1st switching voltage Vsw1, the 2nd switching voltage Vsw2 respectively.
In (d)~(g) of this figure, the high level of supposing control signal SH1, SH2, SL1, SL2 is corresponding to transistorized conducting, and low level is ended corresponding to transistorized.In the figure, the longitudinal axis and transverse axis are suitably amplified, have been dwindled for convenience of explanation.
At first, be described during the 1st cutting apart of φ 8 during the φ the 1 to the 8th.Logic control portion 40 with triangular signal Vosc from its edge floors to reach error voltage Verr during as φ 1 during the 1st.With next to through the 2nd deadline Toff2 during as φ 2 during the 2nd.With next to triangular signal Vosc arrive peak edge during as φ 3 during the 3rd.With next to triangular signal Vosc arrive the edge floors during as φ 4 during the 4th.With next to triangular signal Vosc arrive once more error voltage Verr during as φ 5 during the 5th.With next to through the 1st deadline Toff1 during as φ 6 during the 6th.With next to triangular signal Vosc arrive once more peak edge during as φ 7 during the 7th.With next to triangular signal Vosc arrive once more the edge floors during as φ 8 during the 8th.
More than during each cut apart can based on pwm signal Vpwm, periodic signal Vq, the 1st deadline Toff1 and the 2nd deadline Toff2, with general logical circuit formation.The 1st deadline Toff1, the 2nd deadline Toff2 can in 50ns to 200ns degree, set according to the cycle of triangular signal Vosc.Next, illustrate the conducting of transistor MH1, the MH2 the φ 8, ML1, ML2 during the φ the 1 to the 8th during the 1st, by control.
During the 1st, among the φ 1, indicate the 1st high-side transistor MH1 and the 2nd low side transistors ML2 conducting.Next during the 2nd, among the φ 2, indicate the 1st high-side transistor MH1 conducting.Next during the 3rd, among the φ 3, indicate the 1st high-side transistor MH1, the 2nd high-side transistor MH2 conducting.Next during the 4th, among the φ 4, indicate the 2nd high-side transistor MH2 conducting.Next during the 5th, among the φ 5, indicate the 1st low side transistors ML1 and the 2nd high-side transistor MH2 conducting.Next during the 6th, among the φ 6, indicate the 2nd high-side transistor MH2 conducting.Next during the 7th, among the φ 7, indicate the 1st high-side transistor MH1, the 2nd high-side transistor MH2 conducting.Next during the 8th, among the φ 8, indicate the 1st high-side transistor MH1 conducting.Then, get back to the 1st during φ 1.Control signal SH1, SH2 shown in Figure 10 (d)~(g), SL1, SL2 corresponding to above control be generated.
Along with the conducting of transistor MH1, MH2, ML1, ML2, by action, the 1st, the 2nd terminal of the primary winding 12a of transformer 12 is applied the 1st switching voltage Vsw1, the 2nd switching voltage Vsw2 respectively anti-phasely as (h) of Figure 10 with (i).In addition, in (a)~(i) of Figure 10, for ease of understanding, each transistor of H bridge circuit 10 is as representing with respect to drive signal conducting without delay, the perfect condition of ending.
The following describes the action of the inverter 100 of the present embodiment that as above constitutes like that.(a)~(f) of Figure 11 is the circuit diagram of current direction of H bridge circuit 10 of the inverter 100 of expression present embodiment.The state of each transistorized conducting, cut-off state and the coil current Isw of φ 1 during (a) expression the 1st of Figure 11; The state of each transistorized conducting, cut-off state and the coil current Isw of φ 3 during the φ 2 and the 3rd during (b) expression the 2nd of Figure 11; The state of each transistorized conducting, cut-off state and the coil current Isw of φ 4 during (c) expression the 4th of Figure 11; The state of each transistorized conducting, cut-off state and the coil current Isw of φ 5 during (d) expression the 5th of Figure 11; The state of each transistorized conducting, cut-off state and the coil current Isw of φ 7 during the φ 6 and the 7th during (e) expression the 6th of Figure 11; The state of each transistorized conducting, cut-off state and the coil current Isw of φ 8 during (f) expression the 8th of Figure 11.
Shown in Figure 11 (a), the 1st high-side transistor MH1, the 2nd low side transistors ML2 become conducting among the φ 1 during the 1st.As a result, coil current Isw flows through the path of the 1st high-side transistor MH1, primary winding 12a, the 2nd low side transistors ML2.The 1st switching voltage Vsw1 of this moment becomes the voltage almost equal with input voltage vin.Among the φ 1, it is big that coil current Isw slowly becomes during the 1st.
Among the φ 2, shown in solid line in Figure 11 (b), the 2nd low side transistors ML2 is cut off, and has only the 1st high-side transistor MH1 conducting during the ensuing the 2nd.As a result, by being accumulated in the energy among the primary winding 12a, in the body diode of the 2nd high-side transistor MH2, flow through regenerative current.During this, the 1st switching voltage Vsw1 keeps the voltage almost equal with input voltage.Among the φ 3, shown in dotted line in this figure (b), the 2nd high-side transistor MH2 is switched on during the ensuing the 3rd, and current path switches to the 2nd high-side transistor MH2 from body diode.
Among the φ 4, shown in Figure 11 (c), the 2nd high-side transistor MH2 is switched into conducting during the ensuing the 4th, and the 1st high-side transistor MH1 is cut off.At this moment, the body diode that becomes via the 1st low side transistors ML1 of the coil current Isw that provides from the 1st high-side transistor MH1 among the φ 2 during the 2nd provides from ground connection.The 1st switching voltage Vsw1 of φ 3 becomes the value than the forward voltage Vf of the body diode of low the 1st low side transistors ML1 of earthing potential (0V) during the 3rd.In addition, the energy of savings in primary winding 12a among the φ 1 all is sent among the secondary coil 12b among the φ 3 during the 3rd during the 1st, and coil current Isw becomes 0.
Among the φ 5, shown in Figure 11 (d), keep under the state of conducting at the 2nd high-side transistor MH2 during the ensuing the 5th, the 1st low side transistors ML1 is switched into conducting.At this moment, the 1st switching voltage Vsw1 is fixed near the earthing potential.In addition, coil current Isw is by the path of the 2nd high-side transistor MH2, primary winding 12a, the 1st low side transistors ML1, flows to the 1st terminal from the 2nd terminal of primary winding 12a.Coil current Isw slowly becomes big among the φ 5 during the 5th.
Among the φ 6, shown in solid line in Figure 11 (e), the conducting ground of keeping the 2nd high-side transistor MH2 switches to the 1st low side transistors ML1 and ends during the ensuing the 6th.As a result, the coil current Isw that flows through the 1st low side transistors ML1 during the 5th among the φ 5 becomes the body diode that flows through the 1st high-side transistor MH1.The 1st switching voltage Vsw1 of this moment becomes the voltage than the forward voltage Vf of the high body diode of input voltage vin.Among the φ 7, shown in dotted line in this figure (e), the 1st high-side transistor MH1 is switched on during the ensuing the 7th, and current path is switched to the 1st high-side transistor MH1 from body diode.
Among the φ 8, shown in Figure 11 (f), the 1st high-side transistor MH1 is switched into conducting during the ensuing the 8th, and the 2nd high-side transistor MH2 is cut off.At this moment, the body diode that becomes via the 2nd low side transistors ML2 of the coil current Isw that provides from the 2nd high-side transistor MH2 among the φ 7 during the 7th provides from ground connection.The 1st switching voltage Vsw1 of φ 8 becomes almost equal with input voltage vin during the 8th.The energy of savings in primary winding 12a among the φ 5 all is sent to secondary coil 12b among the φ 8 during the 8th during the 5th, and coil current Isw becomes 0.
In (a)~(i) of Figure 10, transistor MH1, the MH2 of H bridge circuit 10, ML1, ML2 are assumed that with respect to drive signal DH1, DH2, DL1, DL2 conducting without delay, end, but owing to the influence of parasitic capacitance, dead resistances etc. such as grid capacitance, can produce delay τ in the reality.If delay time T become greater than the 1st deadline Toff1, then might the 1st high-side transistor MH1 conducting before the 1st low side transistors ML1 ends, flow through perforation electric current in two transistor paths.Below, with reference to (a)~(e) of Figure 12, (a)~(e) of Figure 13, the anti-locking mechanism of perforation electric current of the inverter 100 of present embodiment is described.
At first, (a)~(e) with reference to Figure 12 illustrates that delay time T is than the 1st Toff1 deadline action in short-term.The (a) and (b) of Figure 12 are represented control signal SH1, SL1, (c) expression the 1st switching voltage Vsw1 of this figure, (d) expression the 1st comparison signal Vcmp1 of this figure, (e) expression drive signal DH1 of this figure.
At moment t0, the control signal SL1 shown in Figure 12 (b) becomes low level, indicates the 1st low side transistors ML1 to end.Then, the moment t1 after process delay time T 1, the 1st low side transistors ML1 ends.After the 1st low side transistors ML1 ended, the 1st switching voltage Vsw1 rose near the magnitude of voltage (Vin+Vf) shown in this figure (b).At moment t1, the 1st comparison signal Vcmp1 also becomes high level.
From the moment t2 of moment t0 after through the 1st deadline Toff1, the control signal SH1 shown in this figure (a) becomes high level.Drive signal DH1 is the logic product of the 1st comparison signal Vcmp1 and control signal SH1, so become high level at moment t1.As a result, indicate the 1st high-side transistor MH1 conducting at moment t1.Under the situation of Figure 12, control signal SH1 becomes identical signal with drive signal DH1.
Next with reference to the action of Figure 13 (a)~(e) explanation delay time T when the 1st deadline, Toff1 grew.At moment t0, the control signal SL1 shown in Figure 13 (b) becomes low level, indicates the 1st low side transistors ML1 to end.Then, the moment t3 after process delay time T 2, the 1st low side transistors ML1 ends.
After the 1st low side transistors ML1 ended, the 1st switching voltage Vsw1 rose, so the 1st comparison signal Vcmp1 also becomes high level.
From the moment t2 of moment t0 after through the 1st deadline Toff1, the control signal SH1 shown in this figure (a) becomes high level.Drive signal DH1 is the logic product of the 1st comparison signal Vcmp1 and control signal SH1, so become high level at moment t3.As a result, indicate the 1st high-side transistor MH1 conducting at moment t3.
More than, the structure and the action of the inverter 100 of present embodiment have been described.By the inverter 100 of present embodiment, monitor the 1st switching voltage Vsw1, its become be higher than the 1st threshold voltage vt h1 after, after promptly the 1st low side transistors ML1 ends, indicate the 1st high-side transistor MH1 conducting.As a result, the 1st high-side transistor MH1 and the 1st low side transistors ML1 conducting simultaneously can be prevented, the generation of perforation electric current can be prevented.
Similarly, by monitoring the 2nd switching voltage Vsw2, can prevent the 2nd high-side transistor MH2 and the 1st low side transistors ML1 conducting simultaneously, flow through perforation electric current with the 2nd comparator 46.
In addition,,, and compare, drive the transistor that constitutes H bridge circuit 10 with triangular signal Vosc by the electric current that flows through among the secondary coil 12b that monitors transformer 12 according to the inverter 100 of present embodiment.Therefore, by regulating the shape of triangular signal Vosc, the moment that can regulate each transistorized conducting neatly, ends.
For example, in the present embodiment, during the 1st during the φ the 1, the 5th length of φ 5 depend on the gradient when the edge floors is converted to peak edge of triangular signal Vosc.This gradient can make it to change by regulate constant current Ic1 in the triangular signal generating unit 30 of Fig. 4.
In addition, in the present embodiment, φ 8 during the φ 4 and the 8th during be configured to the 4th between peak edge is converted to the tour of edge floors of triangular signal Vosc.During the 4th during the φ the 4, the 8th length of φ 8 can make it to change by in the triangular signal generating unit 30 of Fig. 4, regulating constant current Ic2.
Here, φ during the φ the 1, the 5th during the energy of savings in primary winding 12a depends on the 1st 5 length.In addition, the energy of putting aside among the φ 5 during the φ the 1, the 5th during the 1st is sent to secondary coil 12b among the φ 8 during the φ the 4, the 8th during the 4th.Therefore, by according to the characteristic of transformer 12, regulate shape, the cycle of triangular signal Vosc, can drive expeditiously as the characteristic of the EEFL210 of driven object.
In addition, preferably the fringe time of triangular signal Vosc from the edge floors to peak edge is set in 2 times~100 times scopes of fringe time, is more preferably and is set in 5 times~15 times scopes from peak edge to the edge floors.Which as for setting value for, get final product according to the decisions such as characteristic of triangle wave frequency and transformer.By design triangular signal Vosc in this scope, can carry out high efficiency driving.
In addition, if make the 2nd high-side transistor MH2 continue to end behind φ during the 1st 1, then coil current Isw flows through the body diode (parasitic diode) of the 2nd high-side transistor MH2, so can produce the voltage drop of forward voltage Vf amount, it is big that power loss becomes.Therefore, in the present embodiment, after making the 2nd low side transistors ML2 end through the 2nd deadline Toff2, transfer to the 3rd during φ 3, make the 2nd high-side transistor MH2 conducting.
As a result, shown in Figure 10 (h), the 1st switching voltage Vsw1 is through dropping to input voltage vin behind the Toff1 the 1st deadline.At this moment, the coil current Isw that flows through in the body diode of the 2nd high-side transistor MH2 flows through the 2nd high-side transistor MH2, so can reduce power loss.
Similarly, also be, then to make power loss become big among the φ 6 during the 6th because of its body diode flows through electric current if the 1st high-side transistor MH1 continues to end.Therefore, by through making the 1st high-side transistor MH1 conducting behind the Toff2 the 2nd predetermined deadline, make among the 1st high-side transistor MH1 and flow through electric current, thereby can reduce power loss.
Execution mode is an illustration, can carry out various distortion to the combination of its each inscape and variety of processes, and those skilled in the art can understand these variation and also be in the scope of the present invention.
In the present embodiment, control circuit 20 can all integrate, and perhaps also can be that its part is made of discrete parts or chip part.In addition, control circuit 20 can comprise H bridge circuit 10 ground and is integrated.Which partly carries out the integrated of what degree as for, get final product according to decisions such as the specification of inverter 100, cost, area occupied.
In the present embodiment, the high level of logical circuit, the setting of low level logical value only are examples, can be by carrying out suitable logical inverse with inverter etc. then freely change.For example, logic control portion 40 can make peak edge and edge floors reversally carry out the setting of φ 8 during the φ the 1 to the 8th during the 1st.
In execution mode, the situation that the transistor of the high side in the transistor that will constitute H bridge circuit 10 constitutes with N-channel MOS FET has been described, but also can have used the P channel mosfet.
In execution mode, illustrated in light-emitting device 200, connect inverter 100 at the two ends of EEFL210, situation about driving with anti-phase driving voltage, but be not limited thereto.In addition, the fluorescent tube of driven object also is not limited to EEFL, can be other fluorescent tubes such as CCFL.In addition, the load that is driven by the inverter 100 of present embodiment is not limited to fluorescent tube, goes for the driving that other need the various devices of ac high voltage.
(industrial utilizability)
The present invention can be applied to generate from DC voltage the inverter of alternating voltage.

Claims (15)

1. an inverter is characterized in that, comprising:
Transformer,
The 1st high-side transistor, the one end links to each other with the input terminal that is applied in input voltage, and the other end links to each other with the 1st terminal of the primary winding of above-mentioned transformer,
The current potential fixed terminal that the 1st low side transistors, one end and current potential have been fixed links to each other, and the other end links to each other with the 1st terminal of above-mentioned primary winding,
The 2nd high-side transistor, the one end links to each other with above-mentioned input terminal, and the other end links to each other with the 2nd terminal of above-mentioned primary winding,
The 2nd low side transistors, the one end links to each other with above-mentioned current potential fixed terminal, and the other end links to each other with the 2nd terminal of above-mentioned primary winding,
Current-voltage conversion portion changes the electrorheological of the secondary coil of above-mentioned transformer into voltage, as detecting voltage output,
The triangular signal generating unit generates triangular signal,
Error amplifier, output and the error corresponding error voltage of above-mentioned detection voltage with the reference voltage of being scheduled to, and
Logic control portion, based on from the above-mentioned error voltage of above-mentioned error amplifier output and the above-mentioned triangular signal that generates by above-mentioned triangular signal generating unit, control the conducting of above-mentioned the 1st high-side transistor, the 2nd high-side transistor and above-mentioned the 1st low side transistors, the 2nd low side transistors and end;
Wherein, above-mentioned logic control portion
Above-mentioned triangular signal arrive from the edge floors above-mentioned error voltage the 1st during make above-mentioned the 1st high-side transistor and above-mentioned the 2nd low side transistors conducting,
Ensuing above-mentioned triangular signal arrive peak edge the 2nd during make above-mentioned the 1st high-side transistor conducting, and above-mentioned the 2nd high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive the edge floors the 3rd during make above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more above-mentioned error voltage the 4th during make above-mentioned the 1st low side transistors and above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more peak edge the 5th during make above-mentioned the 2nd high-side transistor conducting, and above-mentioned the 1st high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive once more the edge floors the 6th during make above-mentioned the 1st high-side transistor conducting.
2. inverter according to claim 1 is characterized in that:
Above-mentioned logic control portion during the above-mentioned the 5th in, arrive in above-mentioned error voltage rises during through the 1st predetermined deadline at above-mentioned triangular signal, above-mentioned the 1st high-side transistor is ended,, make above-mentioned the 1st high-side transistor conducting through after above-mentioned the 1st deadline.
3. inverter according to claim 1 and 2 is characterized in that:
Above-mentioned logic control portion during the above-mentioned the 2nd in, arrive in above-mentioned error voltage rises during through the 2nd predetermined deadline at above-mentioned triangular signal, above-mentioned the 2nd high-side transistor is ended,, make above-mentioned the 2nd high-side transistor conducting through after above-mentioned the 2nd deadline.
4. inverter according to claim 1 and 2 is characterized in that:
The fringe time of above-mentioned triangular signal from the edge floors to peak edge is set at 2 times to 100 times scopes of fringe time from peak edge to the edge floors.
5. inverter according to claim 1 and 2 is characterized in that:
Constitute above-mentioned the 1st high-side transistor, the 2nd high-side transistor and above-mentioned the 1st low side transistors, the 2nd low side transistors with MOSFET.
6. inverter according to claim 1 and 2 is characterized in that:
Above-mentioned triangular signal generating unit, above-mentioned error amplifier, above-mentioned logic control portion are integrated on a Semiconductor substrate.
7. an inverter is characterized in that, comprising:
Transformer,
The 1st high-side transistor, the one end links to each other with the input terminal that is applied in input voltage, and the other end links to each other with the 1st terminal of the primary winding of above-mentioned transformer,
The current potential fixed terminal that the 1st low side transistors, one end and current potential have been fixed links to each other, and the other end links to each other with the 1st terminal of above-mentioned primary winding,
The 2nd high-side transistor, the one end links to each other with above-mentioned input terminal, and the other end links to each other with the 2nd terminal of above-mentioned primary winding,
The 2nd low side transistors, the one end links to each other with above-mentioned current potential fixed terminal, and the other end links to each other with the 2nd terminal of above-mentioned primary winding,
Current-voltage conversion portion changes the electrorheological of the secondary coil of above-mentioned transformer into voltage, as detecting voltage output,
The triangular signal generating unit generates triangular signal,
Error amplifier, output and the error corresponding error voltage of above-mentioned detection voltage with the reference voltage of being scheduled to, and
Logic control portion, based on from the above-mentioned error voltage of above-mentioned error amplifier output and the above-mentioned triangular signal that generates by above-mentioned triangular signal generating unit, control the conducting of above-mentioned the 1st high-side transistor, the 2nd high-side transistor and above-mentioned the 1st low side transistors, the 2nd low side transistors and end;
Wherein, above-mentioned logic control portion
Above-mentioned triangular signal arrive from peak edge above-mentioned error voltage the 1st during make above-mentioned the 1st high-side transistor and above-mentioned the 2nd low side transistors conducting,
Ensuing above-mentioned triangular signal arrive the edge floors the 2nd during make above-mentioned the 1st high-side transistor conducting, and above-mentioned the 2nd high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive peak edge the 3rd during make above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more above-mentioned error voltage the 4th during make above-mentioned the 1st low side transistors and above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more the edge floors the 5th during make above-mentioned the 2nd high-side transistor conducting, and above-mentioned the 1st high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive once more peak edge the 6th during make above-mentioned the 1st high-side transistor conducting.
8. according to claim 1 or 7 described inverters, it is characterized in that:
During above-mentioned logic control portion complete during the above-mentioned the 2nd above-mentioned the 2nd high-side transistor is ended, above-mentioned the 1st high-side transistor is ended in during complete during the above-mentioned the 5th.
9. a light-emitting device is characterized in that, comprising:
Fluorescent lamp; With
Above-mentioned fluorescent lamp is provided the claim 1 or the 2 described inverters of driving voltage.
10. light-emitting device according to claim 9 is characterized in that:
Above-mentioned inverter has two, is separately positioned on the two ends of above-mentioned fluorescent lamp, and driving voltage inverting each other is provided.
11. light-emitting device according to claim 9 is characterized in that:
Above-mentioned fluorescent lamp is the cold-cathode tube fluorescent lamp.
12. light-emitting device according to claim 9 is characterized in that:
Above-mentioned fluorescent lamp is an external electrode fluorescent lamp.
13. a LCD TV is characterized in that, comprising:
Liquid crystal display screen; With
Be configured in the described light-emitting device of a plurality of claims 8 at the back side of above-mentioned liquid crystal display screen.
14. the driving method of an inverter is characterized in that, comprising:
Change the electrorheological of the secondary coil of transformer into voltage, convert the step that detects voltage to,
Generate and the step of above-mentioned detection voltage with the corresponding error voltage of error of the reference voltage of being scheduled to, and
Based on above-mentioned error voltage and triangular signal, control constitutes the 1st high-side transistor, the 2nd high-side transistor and the 1st low side transistors of H bridge circuit, the conducting of the 2nd low side transistors, the controlled step of ending;
Wherein, in above-mentioned controlled step,
Above-mentioned triangular signal arrive from the edge floors above-mentioned error voltage the 1st during make above-mentioned the 1st high-side transistor and above-mentioned the 2nd low side transistors conducting,
Ensuing above-mentioned triangular signal arrive peak edge the 2nd during make above-mentioned the 1st high-side transistor conducting, and above-mentioned the 2nd high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive the edge floors the 3rd during make above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more above-mentioned error voltage the 4th during make above-mentioned the 1st low side transistors and above-mentioned the 2nd high-side transistor conducting,
Ensuing above-mentioned triangular signal arrive once more peak edge the 5th during make above-mentioned the 2nd high-side transistor conducting, and above-mentioned the 1st high-side transistor is ended,
Ensuing above-mentioned triangular signal arrive once more the edge floors the 6th during make above-mentioned the 1st high-side transistor conducting.
15. the driving method of inverter according to claim 14 is characterized in that:
In the above-mentioned controlled step, above-mentioned the 2nd high-side transistor is ended in during complete during the above-mentioned the 2nd, above-mentioned the 1st high-side transistor is ended in during complete during the above-mentioned the 5th.
CN 200680013163 2005-11-16 2006-11-15 Inverter and driving method thereof and light-emitting device and the LCD TV of having used it Expired - Fee Related CN100574079C (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
JP332207/2005 2005-11-16
JP2005332199A JP4823650B2 (en) 2005-11-16 2005-11-16 Inverter and driving method thereof, and light emitting device and liquid crystal television using the same
JP332199/2005 2005-11-16

Publications (2)

Publication Number Publication Date
CN101164222A CN101164222A (en) 2008-04-16
CN100574079C true CN100574079C (en) 2009-12-23

Family

ID=38205455

Family Applications (1)

Application Number Title Priority Date Filing Date
CN 200680013163 Expired - Fee Related CN100574079C (en) 2005-11-16 2006-11-15 Inverter and driving method thereof and light-emitting device and the LCD TV of having used it

Country Status (2)

Country Link
JP (1) JP4823650B2 (en)
CN (1) CN100574079C (en)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2009048836A (en) * 2007-08-17 2009-03-05 Sanken Electric Co Ltd Discharging tube lighting device
EP2246968B1 (en) * 2008-02-19 2017-05-17 Shima Seiki Manufacturing., Ltd. Drive circuit for inductive load

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP4267883B2 (en) * 2001-09-21 2009-05-27 ミネベア株式会社 LCD display unit
JP4168660B2 (en) * 2002-05-07 2008-10-22 松下電器産業株式会社 Discharge lamp lighting device
JP2004166445A (en) * 2002-11-15 2004-06-10 Rohm Co Ltd Dc-ac converter and its controller ic
JP2004241136A (en) * 2003-02-03 2004-08-26 Tdk Corp Discharge lamp lighting device and display device having the same
JP2005123008A (en) * 2003-10-16 2005-05-12 Harison Toshiba Lighting Corp Driving device for dielectric barrier type low-pressure discharge lamp

Also Published As

Publication number Publication date
JP4823650B2 (en) 2011-11-24
CN101164222A (en) 2008-04-16
JP2007143261A (en) 2007-06-07

Similar Documents

Publication Publication Date Title
US6969958B2 (en) Square wave drive system
US7825605B2 (en) DA/AC convert for driving cold cathode fluorescent lamp
CN100442115C (en) Power supply topologies for liquid crystal display screen
CN102065600B (en) LED dimming driving system
CN100555829C (en) Switched mode power converter and method of operating thereof
CN101103528B (en) Triangle wave generating circuit, inverter using same, light emitting apparatus, and liquid crystal television receiver
US20090014050A1 (en) Solar module system and method using transistors for bypass
CN106329977B (en) The control method of inverter circuit
CN101335485A (en) Soft start circuit and power supply including the same
CN101356733A (en) Triangular waveform generating circuit, generating method, inverter using them, light emitting device and liquid crystal television
CN102549647B (en) Light-emitting diode driving circuit capable of controlling the current of a constant light-emitting diode
CN101572479A (en) Electronic component for power supply and a power supply device
CN101595764A (en) Electric ballast with flyback cat-ear power supply
CN103745701B (en) Inverse-excitation type booster circuit, LED-backlit drive circuit and liquid crystal display
US20150097507A1 (en) Motor driving apparatus
CN102651939A (en) Electrical load driving circuit
CN1620747A (en) DC/AC converter and its controller IC
CN100574079C (en) Inverter and driving method thereof and light-emitting device and the LCD TV of having used it
KR100997397B1 (en) Inverter system and its operating method
CN101521462B (en) Switch power supply circuit
US6798674B2 (en) Half-bridge converter with high power factor
US7859197B2 (en) Inverter using PWM method
KR101056420B1 (en) Step-down converter type LED driving circuit capable of directly detecting the voltage / current at the output stage
KR100835101B1 (en) Full-bridge inverter and converter for lcd backlight
JP7286295B2 (en) Gate drive devices, isolated DC/DC converters, AC/DC converters, power adapters and electrical equipment

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
C17 Cessation of patent right
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20091223

Termination date: 20121115