CN1667458A - Liquid crystal display system with lamp feedback - Google Patents

Liquid crystal display system with lamp feedback Download PDF

Info

Publication number
CN1667458A
CN1667458A CN 200510008141 CN200510008141A CN1667458A CN 1667458 A CN1667458 A CN 1667458A CN 200510008141 CN200510008141 CN 200510008141 CN 200510008141 A CN200510008141 A CN 200510008141A CN 1667458 A CN1667458 A CN 1667458A
Authority
CN
China
Prior art keywords
switch
cathode fluorescence
fluorescence lamp
cold
coupled
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.)
Granted
Application number
CN 200510008141
Other languages
Chinese (zh)
Other versions
CN1667458B (en
Inventor
林永霖
柳达
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.)
O2 Tech. International Ltd.
Original Assignee
O2Micro Inc
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
Priority claimed from US10/776,417 external-priority patent/US6804129B2/en
Priority claimed from US10/870,750 external-priority patent/US7394209B2/en
Application filed by O2Micro Inc filed Critical O2Micro Inc
Publication of CN1667458A publication Critical patent/CN1667458A/en
Application granted granted Critical
Publication of CN1667458B publication Critical patent/CN1667458B/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • Y02B20/204

Abstract

A liquid crystal display system and CCFL power converter circuit is provided using a high-efficiency zero-voltage-switching technique that eliminates switching losses associated with the power MOSFETs. An optimal sweeping-frequency technique is used in the CCFL ignition by accounting for the parasitic capacitance in the resonant tank circuit. Additionally, the circuit is self-learning and is adapted to determine the optimum operating frequency for the circuit with a given load. An over-voltage protection circuit can also be provided to ensure that the circuit components are protected in the case of open-lamp condition.

Description

Liquid crystal display system with lamp feedback
Technical field
The present invention about direct current to exchanging power converter circuit.More particularly, the invention provides a kind of efficient controller circuitry, this controller circuitry uses the zero voltage switching technology to be adjusted to the power of load.The present invention generally is applied to drive the circuit of one or more cold-cathode fluorescence lamps (CCFL), and still, those skilled in the art can learn that the present invention can be applied to the load of the efficient and accurate power control of any needs.
Background technology
Fig. 1 has described a traditional C CFL power-supply system 10.This system comprises a power supply 12, one CCFL driving circuit 16, one controllers, 14, one feedback control loops 18 and the one or more CCFL that are associated with LCD plate 20 substantially.Power supply 12 provides a DC voltage to circuit 16, and is controlled by controller 14 by transistor Q3.Circuit 16 is self-resonance circuit, is known as Roy's circuit (Royer circuit).In essence, circuit 16 be a self-oscillation direct current to a-c transducer, its resonance frequency determined by L1 and C1, N1 to N4 specifies the number of turn of Transformer Winding and winding.At work, alternately conducting and switch in input voltage on winding N1 and the N2 respectively of transistor Q1 and Q2, if the Q1 conducting, then input voltage is added on the winding N1.Voltage with relative polarity will be placed on another winding.The base stage that the induced voltage of N4 makes Q2 is for just, and Q1 is by the small voltage drop conducting between the collector and emitter.The induced voltage of N4 also makes Q2 remain on cut-off state.The Q1 conducting is till the magnetic flux in the TX1 magnetic core reaches capacity.
When saturated, the voltage of the collector of Q1 rises rapidly (to the numerical value by base circuit determined), and the induced voltage in the transformer descends rapidly.Q1 far is pulled away from state of saturation, and the VCE rising, causes that the voltage on the N1 further descends.Loss in the base drive causes Q1 to end, like this and magnetic flux in the iron core is descended slightly and produce an electric current in N4 and make the Q2 conducting.The induced voltage of N4 makes Q1 remain on the saturation conduction state, and is saturated in inverse direction until iron core, and a similar inverse process generation, switches circulation to finish.
Although anti-phase appliance circuit 16 is made of quite few element, the non-linear complicated interaction of transistor and transformer is depended in its suitable work.In addition, the variation of C1, Q1 and Q2 (typically being 35% tolerance) does not allow circuit 16 to be applicable to the parallel pressure change apparatus, because any duplicating of circuit 16 all can produce extra undesirable frequency of operation, this frequency of operation may be at some harmonic wave place resonance.When being applied to the CCFL load, this circuit produces " flapping " effect of significantly not expecting in CCFL.Even tolerance almost meets, but because circuit 16 is operated in the self-resonance pattern, " flapping " effect can not be removed, because duplicating of any this circuit will have himself distinctive frequency of operation.
In United States Patent (USP) the 5th, 430,641; 5,619,402; 5,615,093; Can find some other drive system in 5,818, No. 172.These reference papers all have poor efficiency, two-stage power conversion, and frequency conversion operation, and/or the shortcoming of correlativity is arranged with load.In addition, when load comprises CCFL and assembly, can introduce stray capacitance, thereby influence the impedance of CCFL itself.In order to design a circuit of suitably working effectively, this circuit design must be considered the spurious impedance that is used to drive the CCFL load.This type of effort is not only consuming time, expensive, and also is difficult to produce the converter design an of the best when handling different loads.Therefore, need overcome these shortcomings and a circuit solution is provided, this circuit have reliably the lighting a lamp of high-level efficiency, CCFL, with the characteristics of the power transfer of irrelevant power adjustments of load and single-frequency.
Summary of the invention
The invention provides a liquid crystal display systems, this system comprises: a LCD panel; One cold-cathode fluorescence lamp that is used for throwing light on described LCD panel; One is coupled to the secondary transformer winding of cold-cathode fluorescence lamp, and this winding provides electric current to cold-cathode fluorescence lamp; One is coupled to the primary transformers winding of secondary transformer winding, and this winding provides magnetic flux for the secondary transformer winding; One is coupled to the switch of primary transformers winding, and this switch allows electric current primary transformers winding of flowing through; One is coupled to the feedback control loop circuit of cold-cathode fluorescence lamp, this circuit receives an expression and provides to the feedback signal of the power of cold-cathode fluorescence lamp, and and if only if described feedback signal during greater than predetermined threshold value control be sent to the power of cold-cathode fluorescence lamp.
In an alternate embodiments, liquid crystal display systems comprises: a LCD panel; One cold-cathode fluorescence lamp that is used for throwing light on LCD panel; One is coupled to the secondary transformer winding of cold-cathode fluorescence lamp, and this winding provides electric current to cold-cathode fluorescence lamp; One is coupled to the primary transformers winding of secondary transformer winding, and this winding provides magnetic flux for the secondary transformer winding; One is coupled to the switch of primary transformers winding, and this switch allows electric current primary transformers winding of flowing through; One is coupled to the feedback control loop circuit of cold-cathode fluorescence lamp, and this circuit receives a feedback signal from cold-cathode fluorescence lamp, when described feedback signal is expressed as open-circuit condition, reduces to provide the power to cold-cathode fluorescence lamp.
In another alternate embodiments, liquid crystal display systems comprises: a LCD panel; One cold-cathode fluorescence lamp that is used for throwing light on LCD panel; One is coupled to the secondary transformer winding of cold-cathode fluorescence lamp, and this winding provides electric current to cold-cathode fluorescence lamp; One is coupled to the primary transformers winding of secondary transformer winding, and this winding provides magnetic flux for the secondary transformer winding; One is coupled to first switch of primary transformers winding, and this switch allows electric current along the first direction primary transformers winding of flowing through; One is coupled to the second switch of primary transformers winding, and this switch allows electric current along the second direction primary transformers winding of flowing through; One is coupled to the 3rd switch of primary transformers winding, and when having an overlap condition between the 3rd switch and first switch, first switch provides electric current for the primary transformers winding; With a feedback control loop circuit that is coupled to cold-cathode fluorescence lamp, this circuit receives a feedback signal from cold-cathode fluorescence lamp, and by keeping the minimum overlay between the 3rd switch and first switch to make cold-cathode fluorescence lamp keep a predetermined minimum power.
The present invention also provides the method for controlling the power that offers cold-cathode fluorescence lamp in the liquid crystal display systems, and this method comprises step: provide a pulse signal to the guiding path of transistor as the primary transformers winding; Generation one comes from the feedback signal of the cold-cathode fluorescence lamp that is coupled to the secondary transformer winding, and this signal indication is at the residing electricity condition of cold-cathode fluorescence lamp; Reception is from the feedback signal of cold-cathode fluorescence lamp; With and if only if when feedback signal represents that cold-cathode fluorescence lamp is lit a lamp, regulate the power that offers described cold-cathode fluorescence lamp.
Those skilled in the art will know, though following embodiment will be illustrated as a reference with preferred embodiment and using method, and do not mean that the present invention is limited to these preferred embodiments and using method.More exactly, the present invention has scope more widely, and the claim scope of only being enclosed limits and illustrates.
Other characteristics of the present invention and advantage will be illustrated in following embodiment, and with reference to the accompanying drawings, wherein same section is described with identical numbering.
Description of drawings
Figure 1 shows that traditional AC/DC converter circuit;
Figure 2 shows that a preferred embodiment of AC/DC converter circuit of the present invention;
Fig. 2 a-2f is depicted as the typical sequential chart of Fig. 2 circuit;
Figure 3 shows that another preferred embodiment of AC/DC converter circuit of the present invention;
Fig. 3 a-3f is depicted as the typical sequential chart of Fig. 3 circuit;
Fig. 4 a-4f is depicted as the analogous diagram of Fig. 2 and circuit shown in Figure 3;
Figure 5 shows that an embodiment of liquid crystal display systems of the present invention;
Figure 6 shows that an embodiment of liquid crystal display systems of the present invention;
Figure 7 shows that an embodiment of liquid crystal display systems of the present invention;
Figure 8 shows that an embodiment of the display illumination system of liquid crystal display systems of the present invention; With
Figure 9 shows that the waveform among the embodiment of liquid crystal display systems of the present invention;
Embodiment
Though do not wish to be limited by example, following detailed description will be carried out as the load of circuit of the present invention with reference to the display screen with CCFL.Yet significantly, the present invention is not limited to only drive one or more CCFL, and the present invention more should be interpreted as a power converter circuit and a method that is independent of the certain loads that application-specific is arranged widely.
Generally speaking, the invention provides and use feedback signal and pulse signal, adjust the ON time of two pairs of switches, and then control is sent to power in the circuit of load.When the conducting controllably of pair of switches quilt, make that its ON time is overlapping, power will be along by this defined guiding path of switch being sent to load by a transformer.Similarly, when another to switch by conducting controllably, make when its ON time is overlapping that power is transported to load to the defined guiding path of switch by transformer along this another.Therefore, by overlapping between actuating switch and gauge tap selectively, the present invention can accurately control and be sent to a power of giving fixed load.In addition, the present invention comprises excess current and excess voltage protection, and this circuit is ended the power to load under the situation of short circuit or open circuit.And controllable switch topological structure described herein makes that circuit can be irrelevant down with load, and uses one to work down with the irrelevant one working frequency of the resonance effect of transformer configuration.These characteristics will be in following discussion, with reference to the accompanying drawings.
Circuit diagram shown in Figure 2 shows the preferred embodiment of phase shift of the present invention, full-bridge, zero voltage switching power converter.In fact, circuit shown in Figure 2 comprises: a power supply 12; A plurality of switches 80, definition alternate conduction path, right with the switch of diagonal line arrangement; Drive the driving circuit 50 of each switch; One produces the frescan 22 of square-wave pulse to driving circuit 50; An one transformer TX1 (a primary side and the defined relevant resonance groove of a C1 circuit by TX1 arranged) and a load.Advantageously, the present invention also comprises an overlapping feedback control loop 40, and this loop is controlled each at least one pair of ON time of splitting the Central Shanxi Plain, allows may command power to be sent to load thus.
Power supply 12 is applied to this system.Originally, produce a biasing/reference signal 30 from this power supply and be used for control circuit (at control loop 40).Best, frescan 22 generations one dutycycle is 50% pulse signal, begin with a upper frequency, and with a set rate and the downward frequency sweep of predetermined process (i.e. the square-wave signal of a variable pulse width).Frescan 22 is preferably a programmable frequency generator known in the art.(from frescan 22) pulse signal 90 is transferred into B_ driving circuit (B_Drive) (its driving switch _ B, be the grid of gauge tap _ B), and being transferred into A_ driving circuit (A_Drive), this circuit produces a complementary pulse signal 92 and a ramp signal 26.This complementation pulse signal 92 differs greatly with pulse signal 90 and is about 180 degree, and ramp signal 26 approximately differs 90 degree with pulse signal, and this will be as described below.Ramp signal 26 is preferably a serrated signal, as shown in the figure.Ramp signal 26 will be compared with the output signal 24 (being called CMP here) of error amplifier 32 by comparer 28, produce signal 94 thus.The output signal 94 of comparer 28 is similarly one, and to be transferred into C_ driving circuit (C_Drive) dutycycle be 50% the pulse conducting with trigger switch _ C (Switch_C), and this signal is again between determine switch B and the switch C and the lap between switch A and the switch D subsequently.Its complementary signal (differ and be about 180 degree) is applied to switch _ D by D_ driving circuit (D_Drive).Those skilled in the art can know that driving circuit _ A is coupled respectively to the control line (for example grid) of switch _ A and switch _ D to the circuit of driving circuit _ D, as said, allows the conducting controllably of each switch.Finish the lamp current adjusting by the lap of adjusting between switch B, C and A, the D.In other words, be that switch has determined the quantity of power handled in the converter to the lap under the conducting state.Therefore, switch B and switch C and switch A and switch D are referred to herein as overlapping switch.
Though do not wish to be limited to by the example among this embodiment, the B driving circuit is preferably by totem-pote circuit, common Low ESR operation amplifier circuit, or emitter follower circuit constitutes.The D_ driving circuit has similar structure.Because A_ driving circuit and C_ driving circuit are not direct ground connection (promptly floating), so these driving circuits preferably are made of boot-strap circuit (boot_strap circuit) or other high side (high_side) driving circuits known in the art.In addition, as mentioned above, A_ driving circuit and C_ driving circuit comprise a phase inverter, the signal (being phase place) that this phase inverter is used for reversing respectively and comes from B_ driving circuit and D_ driving circuit.
Reach efficient operation by a zero voltage switching technology.(switch _ A is to switch _ D) 80 conductings after its intrinsic diode (D1 to D4) conducting for four MOSFET, this provide one in transformer/capacitor (TX1/C1) configuration the current flow path of energy, guarantee thus that when these switch conductions the voltage above them is zero.Because this controllable operation, handoff loss is minimized and has kept high-level efficiency.
The preferable blocked operation of overlapping switch 80 is with reference to the sequential chart among the figure 2a to 2f.Switch _ C disconnects (Fig. 2 f) in a certain period of switch B and C conducting simultaneously.After switch _ C disconnects, electric current in the groove (with reference to figure 2) now flows through the diode D4 (Fig. 2 e) among switch _ D, primary side, C1 and the switch _ B of transformer, make the voltage and current resonance in capacitor C 1 and the transformer thus, the result (Fig. 2 f) of NE BY ENERGY TRANSFER during as switch B and switch C conducting.Notice that this situation must occur, because will violate Faraday's law in the sudden change of transformer primary side current direction.Therefore, the electric current D4 that must flow through when switch _ C disconnects.During the D4 conducting, just closed conducting of switch _ D.Similarly, switch _ B disconnects that (Fig. 2 a), electric current is sent to the diode D1 (Fig. 2 e) that is associated with switch _ A before switch _ A closure.Similarly, switch _ D is disconnected (Fig. 2 d), and electric current is from switch _ A, through C1, transformer primary side and diode D3 now.Switch _ C is closed (Fig. 2 e) after the D3 conducting.It is closed that switch _ B disconnects the back at switch _ A, and this allows diode D2 at first to be switched on before switch _ B closure.Attention is to be the energy that the overlapping decision of the closure time of switch B, the C at diagonal angle and A, D is delivered to transformer, shown in Fig. 2 f.
In this embodiment, Fig. 2 b shows and only just produce ramp signal 26 when switch _ A is closed.Therefore, the driving circuit _ A that produces ramp signal 26 preferably comprises a constant current generator circuit (not shown), and this circuit comprises the electric capacity that the appropriate time constant arranged, and is used for producing ramp signal.For this purpose, utilize a reference current (not shown) to realize the electric capacity charging, and this capacity earth (by a for example transistor switch), discharge rate exceeds charge rate like this, produces a saw-tooth ramp signal 26 thus.Certainly, as mentioned above, this can realize by integrated pulse signal 90, therefore, can use an integrator circuit (for example, operational amplifier and electric capacity) to form ramp signal 26.
In the process of lighting a lamp, (promptly between switch A, D and B, C) produces a predetermined minimum overlay between two switches that are the diagonal angle.This produces one by the least energy that inputs to the groove circuit that comprises C1, transformer, C2, C3 and CCFL load.Notice that load can be ohmic and/or capacitive.Driving frequency starts from a predetermined upper frequency, and up to its convergence groove circuit with by the resonance frequency of the equivalent electrical circuit that Circuit Fault on Secondary Transformer reflected, lot of energy is transferred into the load that is connected with CCFL.Because its high-impedance behavior before lighting a lamp, CCFL is subjected to coming from the high-tension influence that offers the primary side energy.This voltage is enough to make CCFL to light a lamp.The CCFL impedance drops to its operate as normal value (for example 100K ohm is to 130K ohm), and the energy that work offers primary side based on minimum overlay no longer is enough to keep the steady operation of CCFL.The output of error amplifier 26 begins it, and to adjust function overlapping to be used for increasing this.The size that is error amplifier 26 outputs has determined overlapping amount.For example:
Feedback control loop 40 with reference to figure 2b, 2c and Fig. 2 is important to note that, when comparer 28 judges that ramp signal 26 (being produced by driving circuit _ A) equates with the value of signal CMP24 (being produced by error amplifier 32), and switch _ C closure.Shown in the point of crossing among Fig. 2 b 36.In order to prevent short circuit, switch A, B and C, D definitely can not be closed simultaneously.By the size of control CMP, regulate the energy that is delivered to transformer the overlapping time between switch A, D and B, the C.In order to adjust the energy (with regulating the energy that is delivered to the CCFL load thus) that is delivered to transformer, by the output CMP24 of departure amplifier, switch C and D are relevant to switch A and B does time shift.If move to right by the size that increases CMP from the driving pulse that the output of comparer 28 enters switch C and D as can be known by sequential chart, will realize increase overlapping between switch A and D, B and the C so, thereby the energy that is delivered to transformer is increased.In fact, this is corresponding to higher lamp current work (higher-lamp current operation).On the contrary, the driving pulse of switch C and D move to left (reduce CMP signal) energy of transmission will be reduced.
For this purpose, error amplifier 32 compares a feedback signal FB and a reference voltage REF.FB measures by detecting the current value of resistance R s, and its expression is by the total current of load 20.REF is the signal of an expression desired load situation, for example the expectation electric current by load.In operate as normal, REF=FB.Yet, if load condition is intentionally compensated, for example compensating by a dimmer switch that is connected in the LCD flat panel display, the value of REF can correspondingly increase/reduce.This fiducial value correspondingly produces CMP.The value of CMP has reflected load condition and/or a bias voltage intentionally, and is realized by the difference between REF and the FB (being REG-FB).
In order to protect load and circuit (for example not to be in open-circuit condition at load end; open circuit CCFL state under the operate as normal); the FB signal is preferably compared in current sense comparator 42 with a reference value (not shown and different with above-mentioned REF signal), and it exports the state of definition switch 28 as described below.This reference value can be programmable, and/or is that the user is definable, and the minimum that preferably reflects system and allowed or maximum current (for example, can specifiedly be used for individual elements, especially for CCFL load).If the value of feedback FB signal and reference signal is (operate as normal) in allowed limits, then current sense comparator is output as 1 (or high).This allows the CMP switch 38 of flowing through, and circuit is worked saidly, with delivering power to load.Yet if the value of FB signal and reference signal (open circuit or short-circuit condition) outside preset range, current sense comparator is output as 0 (or low), forbids that the CMP signal flow is through switch 38.(certainly, inverse process can realize that wherein switch triggers under 0 state).Allow electric current through stream Rs up to the current sense comparator indication, just minimum voltage Vmin is provided and is sent to comparer 28 by switch 38 (not shown).Correspondingly, switch 38 comprises and is used for when the detection electric current is 0, suitably selecting programmable voltage Vmin.Refer again to Fig. 2 b, the effect of this work is that the CMP D. C. value is reduced to specified or minimum value (being CM=Vmin), and transformer TX1 just high-voltage state can not occur like this.Therefore, point of crossing 36 is moved to left, and has reduced the lap between the complementary switch (in point of crossing 36 switches _ C closure) thus.Similarly, when detected value was 0 (or preset value of other expression open-circuit conditions), current sense comparator 42 was connected to frequency generator 22, to close generator 22.CMP is fed to holding circuit 62.If CCFL is removed (open-circuit condition) at work, this is to turn off frescan 22.
For holding circuit is not in overvoltage condition, present embodiment preferably comprises holding circuit 60, and its work is with following providing (to the description of the overcurrent protection by current sense comparator 42 as mentioned above).Circuit 60 comprises a protection comparer 62, and it is compared with one signal CMP by the voltage signal 66 of load 20 derivation.Preferably voltage signal is derived by as shown in Figure 2 dividing potential drop capacitor C 2 and C3 (in parallel with load 20).Under open-circuit condition (open-lamp condition), frescan continues frequency sweep, reaches a threshold value up to OVP signal 66.OVP signal 66 is taken from the dividing potential drop capacitor C 2 and the C3 of output, to detect the voltage of transformer TX1 output.For simplifying the analysis, these electric capacity are also represented the total capacitance of equivalent load capacitance.Threshold value is a reference value, and the voltage that circuit is designed to make Circuit Fault on Secondary Transformer is greater than smallest point modulating voltage (for example by the needed voltage of LCD display), and less than the rated voltage of transformer.When OVP exceeded threshold value, frescan stopped frequency sweep.Simultaneously, current detecting 42 detects less than signal on detection resistance R s.Therefore, in the signal sets at switch block 38 output 24 places in minimum value, overlapping between switch A and D, B and the C be minimum so.Best, in case when OVP exceeded threshold value, timer 64 was started working, start timing (time-out) sequence regularly thus.The cycle of this timing ga(u)ge time series is preferably designed according to load request (for example CCFL of LCD display), but also can be set at some programmable value.In case timing time finishes, driving pulse is invalid, and the trouble free service output of converter circuit is provided thus.That is, circuit 60 provides a sufficient voltage so that this lamp is lit a lamp, if this lamp is not connected to converter, then is closed after the certain hour section, therefore can avoid the high voltage in the mistake of output place.Must be arranged, because the non-process of lighting a lamp is similar to open-circuit condition such time period.
Fig. 3 and 3a-3f have described another preferred embodiment of AC/DC circuit of the present invention.In this embodiment, circuit is worked in the mode that is similar to Fig. 2 and 2a-2f and is provided, and is used for regularly importing the flip-flop circuit 72 of the signal of C_ driving circuit yet present embodiment has also comprised a phase-locked loop circuit (PLL) 70 and that is used for controlling frescan 22.Be appreciated that if make the driving pulse of switch C and D move to right 50% by sequential chart, just can realize increase overlapping between switch A and D, B and the C, thereby increase the energy that is delivered to transformer by the size that increases CMP.In fact, this is corresponding to higher lamp current work (may need the manual increase by aforesaid REF voltage).On the contrary, move to left (by reducing the CMP signal) of the driving pulse of switch C and D reduced the energy that is transferred.Phase-locked loop circuit 70 keeps the phase relation between feedback current (through Rs) and the cell current (through TX1/C1) under operate as normal, as shown in Figure 3.PLL circuit 70 preferably comprises from groove circuit (C1 and TX1 primary side) input signal, signal 98 and Rs (above-mentioned FB signal).In case CCFL is lit a lamp and by the electric current among the Rs detection CCFL, just activate the PLL70 circuit, phase place between this circuit locking lamp current and a resonant slots (C1 and the transformer primary side) electric current.That is, PLL is because of any parasitic frequency of regulating frescan 22 of changing that resembles temperature action, mechanical arrangements, and said mechanical arrangements is as the distance between the metal chassis of the converter that influences capacitance and inductance value and the wiring between the LCD plate, lamp and LCD plate.This system preferably keeps phase differential 180 degree between the electric current (load current) of the resonant slots circuit and the Rs that flows through.Therefore, no matter the frequency of operation of certain loads state and/or resonant slots circuit, this system can find a best operating point.
The operation class of Fig. 3 feedback loop is similar to above explanation to Fig. 2.Yet shown in Fig. 3 b, this embodiment carries out timing by the enabling signal of 72 pairs of C_ driving circuit outputs of trigger.For example, in operate as normal, the output of error amplifier 32 will be fed by gauge tap piece 38 (as mentioned above), and the result is a signal 24.Obtain certain lap between switch A and D, B and the C by comparer 28 and trigger 72, this trigger 72 driving switch C and D (the D driving circuit produces the complementary signal of C_ driving circuit).This is that CCFL (display board) load provides steady operation.Consider and remove CCFL (display board) when operate as normal, CMP increases to the boundary value (rail ofoutput) of error amplifier output, and trigger protection circuit immediately.This function is under an embargo when lighting a lamp.
Briefly with reference to figure 3a-3f, in this embodiment, by C_ driving circuit and D_ driving circuit alternately trigger switch C and D as the working result of trigger circuit 72.As Fig. 3 b, trigger is every once triggering, thus initialization C_ driving circuit (and, correspondingly initialization D_ driving circuit).Timing then as above-mentioned with reference to figure 2a-2f, is worked in an identical manner in addition.
Refer now to Fig. 4 a-4f, analogous diagram 2 or 3 output current.For example, Fig. 4 a is presented at 21V when input, and when frescan during near 75.7KHz (0.5us is overlapping), output reaches 1.67KVp-p.If CCFL needs 3300Vp-p to light a lamp, then this undertension is to light a lamp to CCFL.When frequency was reduced to as 68KHz, minimum overlay produced about 3.9KVp-p in output place, and this is enough to the CCFL that lights a lamp.Shown in Fig. 4 b.In this frequency, the overlapping 1.5us that increases to makes the about 1.9KVp-p of output be used for moving the lamp impedance of 130K ohm.This illustrates in Fig. 4 c.As another example, Fig. 4 d shows the work when input voltage is 7V.When 71.4KHz, before lamp is lit a lamp, be output as 750Vp-p.When frequency reduced, output voltage increased till lamp is lit a lamp.When Fig. 4 e illustrated 68.5KHz, output reached 3500Vp-p.The adjusting of CCFL electric current is by regulating overlapping finishing, and supports the impedance of 130K ohm in the back that lights a lamp.The voltage of CCFL is 1.9KVp-p for the 660Vrms lamp.This is also shown in Fig. 4 f.Though not shown, the circuit simulation of Fig. 3 carries out in a similar fashion.
The difference (that is, adding trigger and PLL among Fig. 3) that it should be noted first and second embodiment will can not have influence on the overall work parameter that proposes in Fig. 4 a-4f.Yet it is the imperfect impedance of considering in circuit that decision adds PLL, and can be used as the replacement circuit of the circuit shown in Fig. 2 and add.Simultaneously, add trigger and allowed to remove above-mentioned constant-current circuit.
Therefore, clearly provide the AC/DC converter circuit of an efficient adaptive, it satisfies the target in this proposition.For those skilled in the art, clearly, can carry out some modifications.For example, use the effect of MOSFET as switch, those skilled in the art can know that entire circuit can use the BJT transistor, or the transistorized combination of any kind, comprise MOSFET and BJT is made up though the present invention has described.Other modifications also are possible.For example related with driving circuit _ B and driving circuit _ D driving circuit can be formed by collecting a level circuit altogether, because therefore the transistor ground connection that is associated floating state can not occur.PLL circuit described here is preferably the known common PLL circuit 70 of this specialty, by suitably revising in order to receiving inputted signal and producing control signal, as mentioned above.Pulse generator 22 is preferably a pulse-width modulation circuit (PWM) or frequency range modulation circuit (FWM), and the both is that this specialty is known.Similarly, holding circuit 62 and timer are made of known circuit and suitably revise in addition, carry out work with said.
Fig. 5 has described an embodiment of liquid crystal display systems of the present invention.Liquid crystal display systems 500 comprises thin film transistor 501.Thin film transistor 501 is coupled to column drive circuit 502.Column drive circuit 502 is controlled at the row on the thin film transistor 501.Thin film transistor 501 also is coupled to horizontal drive circuit 503.Horizontal drive circuit 503 is controlled at the row on the thin film transistor 501.Column drive circuit 502 and horizontal drive circuit 503 are coupled to time schedule controller 504.The sequential of time schedule controller 504 control column drive circuits 502 and horizontal drive circuit 503.Time schedule controller 504 is coupled to video signal preprocessor 505.Video signal preprocessor 505 is handled vision signal.In another embodiment, video signal preprocessor 505 can be certain mark apparatus.
Thin film transistor 501 is by display illumination system 599 illuminations.Display illumination system 599 comprises cold-cathode fluorescence lamp 562.Cold-cathode fluorescence lamp 562 is coupled to secondary transformer winding 560.Secondary transformer winding 560 provides electric current for cold-cathode fluorescence lamp 562.Secondary transformer winding 560 is coupled to primary transformers winding 518.Primary transformers winding 518 provides magnetic flux for secondary transformer winding 560.Primary transformers winding 518 is coupled to switch 532.Switch 532 allows the electric currents primary transformers winding 518 of flowing through.Primary transformers winding 518 also is coupled to switch 512.Switch 512 allows electric current through primary transformers winding 518.Switch 532 and switch 512 are coupled to controller 550.Controller 550 provides pulse signal, is used for switching between gauge tap 532 and the switch 512.It should be noted that any controller described here all can be used as controller 550.It should be noted that all alternative display illumination system 599 of any display illumination system described here equally.
Fig. 6 has described another embodiment of liquid crystal display systems of the present invention.Liquid crystal display systems 600 comprises thin film transistor 601.Thin film transistor 601 is coupled to column drive circuit 602.Column drive circuit 602 is controlled at the row on the thin film transistor 601.Thin film transistor 601 also is coupled to horizontal drive circuit 603.Horizontal drive circuit 603 is controlled at the row on the thin film transistor 601.Column drive circuit 602 and horizontal drive circuit 603 are coupled to time schedule controller 604.The sequential of time schedule controller 604 control column drive circuits 602 and horizontal drive circuit 603.Time schedule controller 604 is coupled to video signal preprocessor 605.Video signal preprocessor 605 is handled vision signal.Video signal preprocessor 605 is coupled to video demodulator 606.Video demodulator 606 demodulated video signals.Video demodulator 606 is coupled to tuner 607.Tuner 607 provides vision signal for video demodulator 606.Tuner 607 is adjusted to a characteristic frequency to liquid crystal display systems 600.Video demodulator 606 also is coupled to microcontroller 608.Tuner 607 also is coupled to audio demodulator 611.The sound signal that audio demodulator 611 demodulation come self-tuner 607.Audio demodulator 611 also is coupled to audio signal processor 610.The sound signal that audio signal processor 610 is handled from audio demodulator 611.Audio signal processor 610 is coupled to note amplifier 609.The sound signal that note amplifier 609 amplifies from audio signal processor 610.
Thin film transistor 601 is by display illumination system 699 illuminations.Display illumination system 699 comprises cold-cathode fluorescence lamp 662.Cold-cathode fluorescence lamp 662 is coupled to secondary transformer winding 660.Secondary transformer winding 660 provides electric current for cold-cathode fluorescence lamp 662.Secondary transformer winding 660 is coupled to primary transformers winding 618.Primary transformers winding 618 provides magnetic flux for secondary transformer winding 660.Primary transformers winding 618 is coupled to switch 632.Switch 632 allows the electric currents primary transformers winding 618 of flowing through.Primary transformers winding 618 also is coupled to switch 612.Switch 612 allows electric current through primary transformers winding 618.Switch 632 and switch 612 are coupled to controller 650.Controller 650 provides pulse signal, is used for switching between gauge tap 632 and the switch 612.It should be noted that any controller described here can be used as controller 650.It should be noted that equally any display illumination system described here can substitute display illumination system 699.
Fig. 7 has described another embodiment of liquid crystal display systems of the present invention.Liquid crystal display systems 700 comprises graphics adapter 790.Liquid crystal display systems 700 also can comprise the parts of the liquid crystal display systems 500 shown in above-mentioned and Fig. 5, or the parts of the liquid crystal display systems 600 that shows among above-mentioned and Fig. 6.Graphics adapter 790 is coupled to a video signal preprocessor, and this video signal preprocessor 505 can be the video signal preprocessor 505 shown in above-mentioned and Fig. 5, or the video signal preprocessor 605 shown in above-mentioned and Fig. 6.
Graphics adapter 790 is coupled to chipset core logic 791.Chipset core logic 791 is transmitted in the data between the coupled device.Chipset core logic 791 also is coupled to microprocessor 792.Microprocessor 792 deal with data comprise video data.Chipset core logic 791 also is coupled to reservoir 793.Reservoir 793 random access memorys, and the short-term storage of data is provided.Chipset core logic 791 also is coupled to hard disk drive 794.Hard disk drive 794 provides the longer-term storage of data.Chipset core logic 791 also is coupled to CD drive 795.CD drive 795 is from CD-ROM or DVD-ROM retrieve data.
With reference to figure 8, an embodiment of switching mode CCFL feed circuit 100 of the present invention has been described.The present invention is a switched-mode power supply, and (CCFL) provides energy for cold-cathode fluorescence lamp.This power supply is a direct current (DC) low voltage transition one interchange (AC) high voltage, and offers CCFL.
The switched-mode power supply circuit comprises one first switch, and this switch contains source electrode, drain and gate.The drain electrode of first switch is connected to the elementary winding of step-up transformer.The number of turn of the secondary winding of this step-up transformer is 20 times of elementary umber of turn at least, is preferably 50 to 150 times.The source electrode of first switch is connected to a power supply.
Second switch also contains source electrode, drain and gate.The drain electrode of second switch is connected to the drain electrode of first switch and an end of primary winding simultaneously.The source electrode of second switch is connected to the ground connection reference of a power supply.Elementary winding contains one second end, and this second end is connected to the mid point of one or two capacitive dividers.Like this, these two switch series connection, input voltages of equal independent power source approx.Link to each other with both ends of power after these two capacitances in series.
One control circuit transmits and controls signal to first and second switches, is alternately closed switch with 180 degree phase shifts.When first switch closure, an electric current with one with reference to the elementary winding of positive flow through first switch and transformer.When second switch was closed, this electric current was with the elementary winding of reverse direction flow through transformer, and the second switch of flowing through.
Transformer is driven from both direction, so magnetic flux unshakable in one's determination sweeps two quadrants that are used for the B-H loop relevant with transformer.So just reduce the size of transformer core, thereby saved the cost of transformer.
Two electric capacity have been formed a capacitive divider, are connected to an end of primary winding.When each switch closure, two electric capacity the flowed through current charges or the discharge of primary winding.When first switch closure, be second electric capacity charging when electric current is first capacitor discharge, and in the disconnection of first switch, when being connected the body diode conducting of second switch, this electric current is reset.When second switch is closed, the current reversal of the primary of flowing through winding.Along with this direction of current flow, first electric capacity is recharged, and second electric capacity is discharged.After second switch was disconnected, electric current was recovered via the body diode of first switch.If switch closure when their body diode conducting, switch is closure when no-voltage basically so.It is minimum that this zero voltage switching technology drops to the handoff loss of switch.Therefore, the efficient of power converter is improved.
Feed circuit 100 comprise a controller 150, one first switch, 112, one second switches 132 and a transformer 120, and to be connected to that power supply 274 is used for be that a load (for example the CCFL162 in the flat-panel monitor, this flat-panel monitor can be a LCD) provides power.
First switch 112 can be N-channel mos field effect transistor (MOSFET) grid-control switch, and comprises a drain electrode 114, and this drain electrode is connected to an end of the elementary winding 118 of step-up transformer 120.Second end 125 of elementary winding 118 is connected on the node of first electric capacity 124 and second electric capacity 126.The source electrode 128 of first switch 112 is connected to the ground connection reference of power supply 274.Second switch 132 can be P-passage MOSFET grid-control switch.The drain electrode of P-channel switch 132 also is connected to the drain electrode 114 of switch 112.Switch 112 and switch 132 all comprise intrinsic diode 134 and 136 respectively.The grid 138 of switch 132 and 112 grid 152 are connected to the output terminal of controller 150.
The secondary winding 160 of step-up transformer 120 is connected to CCFL162.Compare with the nonlinear magnetism conductance of the saturable core of transformer adopting in the prior art Roy circuit, can form the magnetic core that linear magnetic permeability is arranged in the step-up transformer 120, this magnetic core is unsaturation when feed circuit 100 work.The turn ratio of step-up transformer 120 was at least 20: 1, and usually in 50: 1 to 150: 1 scope.
The secondary winding 160 of step-up transformer 120 and two electric capacity, 163,164 parallel connections of connecting.Electric capacity 163,164 constitutes a voltage divider, is used for detecting the voltage of the secondary winding 160 of step-up transformer 120, and the square wave of secondary winding 118 is transformed to the near sinusoidal ripple offers CCFL load 162.Under operate as normal, detect voltage 186 and often reset by switch 170, this switch is by the Current Control of the CCFL162 that flows through.The function of switch 170 will describe in detail below.
Controller 150 can be a PDM keyer, and it provides the grid 152 of first grid drive signal 152 to switch 112, and the grid 138 of a second grid drive signal 138 to switch 132 is provided.Except drive signal was provided for switch 112,132, controller 150 also provided other functions, and for example two are used for that CCFL lights a lamp and the distinct frequency of operate as normal.The identification circuit 250 of turning on light in controller 150 is used to judge whether CCFL162 is lighted, and judges which is output in two frequencies.When CCFL162 lit a lamp, the signal 252 of turning on light was not set up (de-asserted), and represented that CCFL162 is not lighted, and showed on its circuit it is open circuit.Based on signal 252, oscillator 254 places obtain a first frequency.Detect an electric current of flowing through CCFL162 after lighting a lamp.Therefore, signal 252 is set up (asserted), represents CCFL to be lit a lamp.Obtain a second frequency in oscillator 254 outputs place.It should be noted that the signal 252 of turning on light also determines the output 256 of low frequency width modulation (PWM) circuit 258.In the process of lighting a lamp, the waveform that provides to CCFL162 can not be provided signal 256, to obtain a level and smooth some modulating voltage.In other words, before signal 252 was set up, signal 256 can not influence output control logic 286.
Controller 150 also comprises lamp current and voltage detecting and control function.Lamp current is detected by resistance 182.Detected value 184 is compared with benchmark 212 by a comparer (for example error amplifier 230 of gauge tap 112 and 132 closure times).Modulating voltage is detected by capacitive divider 163 and 164.Detected value 186 is compared by a comparer 232 and benchmark 214.The startup of the output 234 decision digital dock timers 236 of comparer 232.After clock timer 236 starts (for example one to two second) after a while, still be not set up if export 234, the output signal 238 of clock timer 236 is set up holding circuit 240, with the work of shutdown switch 112 and 132.This period is to be used for providing one light a lamp the time (for example one to two second) for CCFL162.Oscillator 254 provides two frequencies for the work of feed circuit 100, and a upper frequency is used to light a lamp, and a lower frequency is used for operate as normal.Upper frequency can exceed 20% to 30% than lower frequency.Lower frequency can be the 68KHz shown in Fig. 4 b, or the 65.8KHz shown in Fig. 4 e, or is lower than arbitrary frequency values of these two frequencies.
Low frequency pulse-width modulation circuit 258 is adjusted the energy that is sent to lamp in order to produce signal 256, thereby realizes brilliance control.The frequency of signal 256 is preferably in 150Hz to the 400Hz scope.The identification circuit 250 receiving light current detection signals 184 of turning on light, its output signal 252 are provided for discerning the existence of CCFL load 162 or finishing of lighting a lamp.Holding circuit 240 receives the signal 252 that expression CCFL162 exist, the signal 238 when being illustrated in CCFL162 and detecting the timing ga(u)ge of signal 260 that electric current exists and expression open-circuit condition.Therefore, when open circuit, excess current, overvoltage condition appear in lamp 162, or take place when under-voltage in voltage input 130, the output signal 262 of holding circuit 240 is set up, with the work of shutdown switch 112 and 132.
Controller 150 comprises the voltage input pin 130 that a ground pin 272 and that is connected to circuit ground (circuit ground) is connected to a direct current voltage source.In controller 150, voltage input pin 130 is connected to one benchmark/biasing circuit 210, and this circuit produces different reference voltage 212,214 etc., for internal use.Voltage input pin 130 also is connected to a undervoltage lockout circuit (under-voltage lock-out circuit) 220 and output driving circuit 222.When providing when the voltage of voltage input pin 130 surpasses a threshold value, the output signal 224 of circuit 220 is started working the other parts of controller 150.On the other hand, if the voltage at voltage input pin 130 places is during less than threshold value, signal 224 is with the work of stop control 150 other parts.
In CCFL when work,, the function that function and open circuit are turned down in the brightness of CCFL comes down to complementary.Advantageously, two signals 168 and 186 can be multiplexing, receives signal 168 and 186 at a pin two 84 places of controller 150.This operation has reduced the cost of controller 150.
The clock pin two 76 of controller 150 is connected to oscillator 254, and this oscillator is connected to circuit ground through an electric capacity 278, or is connected to voltage input pin 130 through a resistance 280, so that a clock signal (being preferably a ramp signal) to be provided at 276 places.
Advantageously, in the present invention, feed circuit 100 utilize with the minimum linking number of controller 150 and have realized maximum functions, drive the CCFL load.The work of this power supply is as described below.
VIN puts on feed circuit 100 with direct current (DC) voltage.In case the input of the voltage at 130 places surpasses the threshold value that undervoltage lockout circuit 220 sets, controller 150 is started working.Benchmark/I-biasing circuit 210 is that other circuit in the controller 150 produces reference voltage.
Because CCFL162 is not lit a lamp, and not from the current feedback signal 184 of CCFL load 162, oscillator 254 produces a upper frequency pulse signal.Driving circuit 222 output one pulse width modulated drive signal 152 and 138 are given switch 112 and 132 respectively.Electric capacity 216 is charged gradually, and voltage 260 is along with the time increases gradually like this.Because the voltage at 260 places is along with the time increases gradually, so the pulsewidth of drive signal 138 and 152 increases gradually.Therefore, be sent to the also increase gradually of power of step-up transformer 120 and load 162.Electric capacity 124 and 126 design make half that is about input voltage by the voltage of each electric capacity.In first semiperiod, switch 132 closures, an electric current is from power supply, flow to elementary winding 118 through switch 132.This electric current flows into electric capacity 126 then, and comprises magnetization current and reflected load current (reflected load circuit).When electric capacity 126 chargings, electric capacity 124 discharges.When switch 132 disconnected, the electric current of elementary winding 118 continued to flow with same direction.Diode 134 makes this electric current continue equidirectional circulation.After switch 132 closures through about 180 the degree differ after, switch 112 closures.Power supply makes electric current flow to elementary winding 118 through electric capacity 124, flow to reference circuit ground 272 along opposite direction through switch 112.This electric current (comprising magnetization current and reflected load current) can be along reversed flow.Meanwhile, when electric capacity 126 discharges, electric capacity 124 chargings.When switch 112 disconnections, diode 136 supports the continuation of electric current in elementary winding 118 to flow.After switch 112 closures through about 180 the degree differ after, switch 132 closures.Switch continues periodically to work.Therefore, the voltage of elementary winding 118 is essentially a square wave.
Fig. 9 has described the waveform at different port place.Fig. 9 (a) shows the drive waveforms at 152 places.Fig. 9 (b) shows 138 place's corresponding driving waveforms.The switch closure of noting switch 112 and 132 differs 180 degree during the time.Certainly, switch 132 can be used the N lane device instead.In the case, the logic of drive signal 138 is reversed, in order to expression ON/OFF (ON/OFF) drive signal.Fig. 9 (c) shows the waveform at 125 places.Be superimposed upon ripplet on the DC voltage (half of input voltage VIN) and represent the charging and the discharge of electric capacity 126.The voltage that input voltage VIN deducts 125 places obtains a similar waveform, and this waveform is represented the voltage of electric capacity 124, and this voltage also has a ripplet that is superimposed upon on 1/2nd input voltages.Fig. 9 (d) illustrates the voltage at 114 places, and Fig. 9 (f) shows the electric current of the elementary winding 118 of flowing through.Notice that when switch was closed at the t1 place, the voltage at 114 places was near VIN.The electric current of elementary winding 118 is with a benchmark forward flow, so that electric capacity 126 chargings make electric capacity 124 discharges simultaneously.Therefore, the voltage at electric capacity 126 places increases (positive slope).At time t2 place, switch 132 disconnects.The electric current at elementary winding 118 places continues to flow with same direction, and is the trend that reduces.Diode 134 makes this electric current continue circulation, is decreased to zero up to electric current during at t3.In the period of t2 to t3, the voltage at 114 places approaches zero obviously.Because electric current flows with same direction, the voltage at electric capacity 126 places still increases.Moment behind t3, because the reverse mmf of elementary winding 118, a little electric current is with reversed flow, diode 136 conductings, and 114 voltage equals the forward pressure drop that VIN adds diode 136.At time t4, switch 112 closures.Voltage 114 drops to and approaches zero, and the electric current of elementary winding 118 is with reverse increase.When electric capacity 124 is recharged, electric capacity 126 discharges.Therefore, the voltage of electric capacity 126 reduces (negative slope).Switch 112 disconnects when time t5, diode 136 conductings, and electric current continues to flow.When the electric current of elementary winding 118 reaches zero, diode 136 stop conductings.Meanwhile, little electric current is with the benchmark forward flow.In other words, because diode 134 conductings, so the voltage at 114 places approaches zero.Working condition continues, and until beginning in time t7 following one-period, and switch 132 is closed once more.Step-up transformer 120 is driven from both direction, has utilized magnetic flux to sweep so substantially, to provide power to the CCFL load.Step-up transformer 120, the stray reactance element that output capacitance 163,164 is relevant with transformer 120 secondary side circuit with all constitutes a groove circuit.This groove circuit is selected the relevant higher harmonics element of square wave that occurs with elementary winding 118 places, and produces a waveform shaping, near sinusoidal at the CCFL162 place.Shown in Fig. 9 (e).Notice that based on the parasitic elements and the load 162 of secondary winding 160, waveform 172 may have different phase shifts with regard to Fig. 9 (a)-9 (d) and the waveform shown in Fig. 9 (f).The voltage at 172 places is by electric capacity 163 and 164 dividing potential drops.Therefore, electric capacity 163 and 164 has two kinds of purposes.A purpose is to be used for voltage detecting 186, and another purpose is the shaping that is used for ripple.
When the CCFL162 conducting, the electric current by CCFL162 is detected by resistance 182.Detected signal 184 is transferred into a current amplifier 230, and this amplifier is exported 260 places at it and linked to each other with building-out capacitor 216.A signal 260 and a signal from oscillator 254 compare, and produce an output, and this output is sent to steering logic 286, with the closure time of determine switch 112 and 132.One a kind of method of regulating the power be sent to load is to provide input 284 to controller 150 with a command signal 168.The signal at 284 places is converted into a low frequency pulse signal by low frequency pulse-width modulation circuit 258, be sent to output control logic 286, use the output 138 and 152 of low frequency pulse signal modulation drive circuit 222 thus, thereby control the energy that is sent to CCFL162 effectively.
During lighting a lamp, CCFL162 is connected to feed circuit 100 as the infinitely-great element of an impedance.Equally, during this period, CCFL162 requires a predetermined forward voltage usually.The feed circuit 100 that comprise electric capacity 163 and 164 detect the voltage of CCFL162.Thus, this predetermined forward voltage determined in proportion at signal 186 places, and is sent to the input 284 of controller 150, is used for voltage-regulation.The identification circuit 250 of turning on light produces a signal 252, and this signal indication CCFL162 does not open.Signal 234 is set up, and starts digital dock timing circuit 236.Equally, signal 252 order oscillators 254 produce the upper frequency that a suitable CCFL162 lights a lamp.During this period, the voltage at CCFL162 place is adjusted to predetermined value.In about one or two second after signal 234 is set up, digital dock timer 236 produces a signal 238.If CCFL162 lit a lamp before signal 238 is set up, as above a paragraph is described works on for CCFL162 so.If CCFL162 is not lit a lamp (damage, do not connect or connect loosening), signalization 238 starts holding circuit 240.The output of holding circuit 240 produces a signal 262, is used for stopping the work of driving circuit 222, so switch 112 and 132 is disconnected.Because CCFL162 is not lit a lamp, do not have power to be sent to CCFL162 during this period, so power control instruction signal 168 natures are inoperative to the work of power supply.In other words, when feed circuit 100 are realized the CCFL162 lighting function, stop brilliance control to the power that is adjusted to CCFL162.Equally, in operate as normal, install 170 reset voltage detection signals 186, so this signal does not influence the brilliance control of CCFL.Therefore, the multiplex technique function has reduced the quantity of pin, like this, has saved the cost of controller 150 and power circuit.
Oscillator 254 is connected to reference circuit ground through electric capacity 278, or be connected to input voltage through resistance 280, and produce pulse signal when pierce circuit 254 when electric capacity 278 is connected to circuit ground, pierce circuit 254 generation electric currents are to electric capacity 278, also absorption comes the electric current of self-capacitance 278.When pierce circuit 254 when resistance 280 is connected to input voltage, pierce circuit 254 absorbs the electric current from voltage input and resistance 280.Absorb and to make to distinguish with the characteristic that produces (sink-and-source) electric current or only absorb (sink-only) electric current and regulate the different control models that are sent to CCFL162 power.For linear model, in order to distinguish low frequency PWM mode as discussed previously, power control instruction signal 168 orders are also regulated the power that is sent to CCFL162, make the transmission of this power need not pass through low frequency pulse-width modulation circuit 258.When pierce circuit 254 is connected to voltage when input through resistance 280, signal 168 284 is flowed through low frequency pulse-width modulation circuit 258 with generation/rewriting one reference signal 212 then, is sent to amplifier 230.The size of command signal 168 thereby direct Control current feedback signal 184 is regulated the electric current by CCFL162.Under this mode of operation, the signal cut low frequency pulse-width modulation circuit 258 at 282 places, and allow signal 284 directly to pass through.Therefore, resistance 280 or electric capacity 278 are connected to pierce circuit 254 not only produce pulse signal, also determined the control model (or under linear mode control, or under the low frequency PWM mode) of CCFL load 162 power adjustments.Such design has reduced controller 150 number of employed element on every side, has but improved deviser's dirigibility greatly.
As mentioned above, first switch 112 and second switch 132 corresponding to feed circuit 100 of the present invention are controlled by controller 150, and be alternately closed, therefore electric current is alternately with first direction and the second direction CCFL162 that flows through, and feed circuit 100 are converted to AC power with direct supply, for CCFL162 provides power.
Therefore, those skilled in the art will be found various modification of the present invention and/or alternate application after reading above-mentioned disclosure, and these modifications and/or alternate application do not break away from the spirit and scope of the present invention situation.So following claim is intended to explain and comprises all modification or alternate application in spirit and scope of the invention.
Other circuit and all such modifications that those skilled in the art will be found are subject in the spirit and scope of the present invention, and are only limited by additional claim.

Claims (29)

1. a liquid crystal display systems comprises:
One LCD panel;
The cold-cathode fluorescence lamp of the described LCD panel of one illumination;
A level Transformer Winding, described secondary transformer winding coupled is to described cold-cathode fluorescence lamp, for described cold-cathode fluorescence lamp provides electric current;
One primary transformers winding, described primary transformers winding coupled is to described secondary transformer winding, for described secondary transformer winding provides magnetic flux;
One switch, described switch are coupled to described primary transformers winding, allow the electric current described primary transformers winding of flowing through; With
One is coupled to the feedback control loop of described cold-cathode fluorescence lamp, described feedback control loop receives the feedback signal that an expression is sent to the power of described cold-cathode fluorescence lamp, when described feedback signal that and if only if was higher than a predetermined threshold, control offered the power of described cold-cathode fluorescence lamp.
2. liquid crystal display systems according to claim 1 also comprises:
One input voltage source, described input voltage source is coupled to described switch, for described switch provides electric current.
3. liquid crystal display systems according to claim 2, wherein said input voltage source are a power supply.
4. liquid crystal display systems according to claim 2 also comprises:
One is coupled to described primary transformers winding and earthy first electric capacity; With
One is coupled to second electric capacity of described primary transformers winding and described input voltage source.
5. liquid crystal display systems according to claim 1, when wherein not being higher than a predetermined threshold as if described feedback signal, described feedback control loop makes described cold-cathode fluorescence lamp keep a predetermined minimum power.
6. liquid crystal display systems according to claim 5 also comprises:
One second switch, described second switch are coupled to described primary transformers winding, allow electric current with reverse direction flow through described primary transformers winding; With
One the 3rd switch, described the 3rd switch are coupled to described primary transformers winding and described first switch, when having an overlap condition between described the 3rd switch and described first switch, for described primary transformers winding provides electric current.
7. liquid crystal display systems according to claim 6, wherein said feedback control loop makes described cold-cathode fluorescence lamp keep described predetermined minimum power by keeping the minimum overlay between described the 3rd switch and described first switch.
8. liquid crystal display systems according to claim 1 also comprises:
One voltage-level detector, described voltage-level detector is coupled to described cold-cathode fluorescence lamp, to detect the voltage of described cold-cathode fluorescence lamp.
9. liquid crystal display systems according to claim 8 also comprises:
One voltage protection circuit, described voltage protection circuit is coupled to described voltage-level detector, when the described voltage of described cold-cathode fluorescence lamp surpasses a predetermined threshold, to reduce to be sent to the power of described cold-cathode fluorescence lamp.
10. liquid crystal display systems according to claim 9 also comprises:
One timer, described timer is coupled to described voltage protection circuit, to produce a timing timing period.
11. a liquid crystal display systems comprises:
One LCD panel;
The cold-cathode fluorescence lamp of the described LCD panel of one illumination;
A level Transformer Winding, described secondary transformer winding coupled is to described cold-cathode fluorescence lamp, for described cold-cathode fluorescence lamp provides electric current;
One primary transformers winding, described primary transformers winding coupled is to described secondary transformer winding, for described secondary transformer winding provides magnetic flux;
One switch, described switch are coupled to described primary transformers winding, allow the electric current described primary transformers winding of flowing through; With
One is coupled to the feedback control loop of described cold-cathode fluorescence lamp, and described feedback control loop receives a feedback signal from described cold-cathode fluorescence lamp, when described feedback signal is represented an open-circuit condition, reduces the power that offers described cold-cathode fluorescence lamp.
12. liquid crystal display systems according to claim 11, wherein said feedback signal is represented the voltage of described cold-cathode fluorescence lamp, and when described voltage surpasses a predetermined threshold, represents described open-circuit condition.
13. liquid crystal display systems according to claim 12, wherein when described voltage surpassed a predetermined threshold, described feedback control loop made described cold-cathode fluorescence lamp keep a predetermined minimum power.
14. liquid crystal display systems according to claim 13 also comprises:
One second switch, described second switch are coupled to described primary transformers winding, allow electric current with reverse direction flow through described primary transformers winding; With
One the 3rd switch, described the 3rd switch are coupled to described primary transformers winding and described first switch, when having an overlap condition between described the 3rd switch and described first switch, for described primary transformers winding provides electric current.
15. liquid crystal display systems according to claim 14, wherein said feedback control loop makes described cold-cathode fluorescence lamp keep described predetermined minimum power by keeping the minimum overlay between described the 3rd switch and described first switch.
16. liquid crystal display systems according to claim 11, wherein said feedback signal is represented the voltage of described cold-cathode fluorescence lamp, and when described voltage reaches a scheduled time slot above a predetermined threshold, represents described open-circuit condition.
17. liquid crystal display systems according to claim 11 also comprises:
One is coupled to described primary transformers winding and earthy first electric capacity; With
One is coupled to second electric capacity of described primary transformers winding and voltage input.
18. liquid crystal display systems according to claim 11 also comprises:
One is coupled to described switch, and the input voltage source of electric current is provided for described switch.
19. liquid crystal display systems according to claim 11, wherein said input voltage source are a power supply.
20. liquid crystal display systems according to claim 11, wherein said feedback signal are represented the electric current of described cold-cathode fluorescence lamp of flowing through, and when described electric current is lower than a predetermined threshold, represent described open-circuit condition.
21. a liquid crystal display systems comprises:
One LCD panel;
The cold-cathode fluorescence lamp of the described LCD panel of one illumination;
A level Transformer Winding, described secondary transformer winding coupled is to described cold-cathode fluorescence lamp, for described cold-cathode fluorescence lamp provides electric current;
One primary transformers winding, described primary transformers winding coupled is to described secondary transformer winding, for described secondary transformer winding provides magnetic flux;
One first switch, described first switch is coupled to described primary transformers winding, allows electric current with a first direction described primary transformers winding of flowing through;
One second switch, described second switch are coupled to described secondary transformer winding, allow electric current with a second direction described primary transformers winding of flowing through;
One the 3rd switch, described the 3rd switch are coupled to described primary transformers winding and described first switch, when having an overlap condition between described the 3rd switch and described first switch, for described primary transformers winding provides electric current; With
One is coupled to the feedback control loop of described cold-cathode fluorescence lamp, described feedback control loop receives a feedback signal from described cold-cathode fluorescence lamp, and, keep a minimum power of being scheduled to of described cold-cathode fluorescence lamp by keeping the minimum overlay between described the 3rd switch and described first switch.
22. liquid crystal display systems according to claim 21 also comprises:
One input voltage source, described input voltage source are coupled to described first switch and described second switch, for described first switch and described second switch provide electric current.
23. liquid crystal display systems according to claim 22, wherein said input voltage source are a power supply.
24. in a liquid crystal display systems, control the method that is sent to a cold-cathode fluorescence lamp power, comprise step for one kind:
Provide a pulse signal to a transistor, as a guiding path of a primary transformers winding;
Produce a feedback signal from a cold-cathode fluorescence lamp, described feedback signal is represented the electricity condition at described cold-cathode tube fluorescent light place, and described cold-cathode fluorescence lamp is coupled to the level Transformer Winding one time;
Acceptance is from the described feedback signal of described cold-cathode fluorescence lamp; With
When described feedback signal that and if only if represents that described cold-cathode fluorescence lamp is lit a lamp, regulate the power that is sent to described cold-cathode fluorescence lamp.
25. method according to claim 24, wherein said feedback signal is represented the voltage of described cold-cathode fluorescence lamp, and when described voltage is lower than a predetermined threshold, represents that described cold-cathode fluorescence lamp lights a lamp.
The electric current of described cold-cathode fluorescence lamp 26. method according to claim 24, wherein said feedback signal are represented to flow through, and when described electric current surpasses a predetermined threshold represents that described cold-cathode fluorescence lamp lights a lamp.
27. method according to claim 24 also comprises step:
When described feedback signal represents that nothing is normally lit a lamp, make described cold-cathode fluorescence lamp keep the power of a predetermined minimum amount.
28. method according to claim 27 also comprises step:
Provide one second pulse signal to a transistor seconds, as one second guiding path of described primary transformers winding;
Provide one the 3rd pulse signal to one the 3rd transistor, as described second guiding path of described primary transformers winding; With
Keep the minimum overlay between described the first transistor and described the 3rd transistor.
29., also comprise step according to claim 24 described methods:
Represent not have when described feedback signal and normally light a lamp when reaching a schedule time, cut off the power that is sent to described cold-cathode fluorescence lamp.
CN 200510008141 2004-02-11 2005-02-08 Liquid crystal display system with lamp feedback Expired - Fee Related CN1667458B (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US10/776,417 US6804129B2 (en) 1999-07-22 2004-02-11 High-efficiency adaptive DC/AC converter
US10/776,417 2004-02-11
US10/870,750 2004-06-16
US10/870,750 US7394209B2 (en) 2004-02-11 2004-06-16 Liquid crystal display system with lamp feedback

Publications (2)

Publication Number Publication Date
CN1667458A true CN1667458A (en) 2005-09-14
CN1667458B CN1667458B (en) 2012-09-26

Family

ID=35038637

Family Applications (1)

Application Number Title Priority Date Filing Date
CN 200510008141 Expired - Fee Related CN1667458B (en) 2004-02-11 2005-02-08 Liquid crystal display system with lamp feedback

Country Status (2)

Country Link
CN (1) CN1667458B (en)
TW (1) TWI270839B (en)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7737642B2 (en) 2004-10-18 2010-06-15 Beyond Innovation Technology Co., Ltd. DC/AC inverter
CN101765266A (en) * 2008-12-26 2010-06-30 立锜科技股份有限公司 Driving control circuit for light-emitting component and method thereof
CN101102632B (en) * 2006-07-07 2011-01-05 三垦电气株式会社 Discharge tube lighting apparatus
US7952296B2 (en) 2004-10-18 2011-05-31 Beyond Innovation Techology Co., Ltd. Feedback circuit for DC/AC inverter
CN101166388B (en) * 2006-10-20 2012-02-08 群康科技(深圳)有限公司 Backlight lamp tube short circuit and open circuit protection circuit
CN102573250A (en) * 2010-10-06 2012-07-11 欧司朗股份有限公司 Circuit and method for driving an exciter lamp
CN101389173B (en) * 2007-09-10 2012-08-15 台达电子工业股份有限公司 Current monitoring system for florescent lamp and controlling method thereof
CN101291117B (en) * 2007-03-26 2012-08-29 三星电子株式会社 Inverter, back light assembly and display device possessing same

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TWI452809B (en) 2011-03-08 2014-09-11 Green Solution Tech Co Ltd Full-bridge driving controller and full-bridge converting circuit
TWI462649B (en) * 2011-07-11 2014-11-21 Beyond Innovation Tech Co Ltd Apparatus for driving fluorescent lamp
US20140016374A1 (en) * 2012-07-16 2014-01-16 System General Corp. Regulation circuit having output cable compensation for power converters and method thereof

Family Cites Families (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5875103A (en) * 1995-12-22 1999-02-23 Electronic Measurements, Inc. Full range soft-switching DC-DC converter
US5930121A (en) * 1997-03-14 1999-07-27 Linfinity Microelectronics Direct drive backlight system
US6114814A (en) * 1998-12-11 2000-09-05 Monolithic Power Systems, Inc. Apparatus for controlling a discharge lamp in a backlighted display
US6320329B1 (en) * 1999-07-30 2001-11-20 Philips Electronics North America Corporation Modular high frequency ballast architecture
JP2002175891A (en) * 2000-12-08 2002-06-21 Advanced Display Inc Multi-lamp type inverter for backlight
KR100451928B1 (en) * 2002-03-08 2004-10-08 삼성전기주식회사 Single stage converter of CCFL inverter

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7737642B2 (en) 2004-10-18 2010-06-15 Beyond Innovation Technology Co., Ltd. DC/AC inverter
US7952296B2 (en) 2004-10-18 2011-05-31 Beyond Innovation Techology Co., Ltd. Feedback circuit for DC/AC inverter
US8143797B2 (en) 2004-10-18 2012-03-27 Beyond Innovation Technology Co., Ltd. DC/AC inverter
US8508145B2 (en) 2004-10-18 2013-08-13 Beyond Innovation Technology Co., Ltd. DC/AC inverter
CN101102632B (en) * 2006-07-07 2011-01-05 三垦电气株式会社 Discharge tube lighting apparatus
CN101166388B (en) * 2006-10-20 2012-02-08 群康科技(深圳)有限公司 Backlight lamp tube short circuit and open circuit protection circuit
CN101291117B (en) * 2007-03-26 2012-08-29 三星电子株式会社 Inverter, back light assembly and display device possessing same
CN101389173B (en) * 2007-09-10 2012-08-15 台达电子工业股份有限公司 Current monitoring system for florescent lamp and controlling method thereof
CN101765266A (en) * 2008-12-26 2010-06-30 立锜科技股份有限公司 Driving control circuit for light-emitting component and method thereof
CN102573250A (en) * 2010-10-06 2012-07-11 欧司朗股份有限公司 Circuit and method for driving an exciter lamp

Also Published As

Publication number Publication date
TWI270839B (en) 2007-01-11
CN1667458B (en) 2012-09-26
TW200537407A (en) 2005-11-16

Similar Documents

Publication Publication Date Title
CN2876828Y (en) Lamp feed back liquid crystal display system
CN1667458B (en) Liquid crystal display system with lamp feedback
US7466566B2 (en) DC-AC converter, controller IC therefor, and electronic apparatus utilizing such DC-AC converter
CN1049317C (en) Zero voltage switching controller of resonance mode converter and electronic ballast using the same
US7312586B2 (en) Ballast power supply
US7589981B2 (en) DC-AC converter and method of supplying AC power
CN102742138B (en) AC-DC converter and AC-DC conversion method
CN1368789A (en) High-effiicent adaptive DC/AC converter
CN100486095C (en) DC-AC converter, controller IC therefor, and electronic apparatus utilizing the DC-AC converter
CN104349550A (en) Solid state lighting control
CN1663103A (en) DC/AC converter and its controller IC
CN104602390B (en) The LED lamp drive circuit of double winding single-stage primary side feedback
CN101719728A (en) Resonance power converter and its control method
CN102594170A (en) Wide-input-voltage power supply converter
CN100463580C (en) Driving circuit of backlight device with the protection module group
CN105934043A (en) Lamp control system
CN106550512A (en) A kind of resonant type soft-switch single stage type LED drive circuit
Cheng et al. A novel high-power-factor AC/DC LED driver with dual flyback converters
CN106304484A (en) Controllable silicon light modulation LED drive power and dimming controlling method thereof
CN1610479A (en) Direct drive CCFL circuit with controlled start-up mode
CN2710247Y (en) High-efficient switch circuit for non-linear load
CN103888011A (en) Controller and controlling system and method for hiccup-mode driving signals
CN109936888B (en) High-frequency driving circuit and lighting device using same
US11304280B2 (en) Drive circuit for flicker-free LED lighting having high power factor
CN100556226C (en) High-effiicent adaptive DC/AC converter

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
REG Reference to a national code

Ref country code: HK

Ref legal event code: DE

Ref document number: 1077881

Country of ref document: HK

ASS Succession or assignment of patent right

Owner name: O2 TECH. INTERNATIONAL LTD.

Free format text: FORMER OWNER: O2 MICRO INC

Effective date: 20101122

C41 Transfer of patent application or patent right or utility model
COR Change of bibliographic data

Free format text: CORRECT: ADDRESS; FROM: CALIFORNIA STATE, AMERICA TO: ENGLISH CAYMAN ISLANDS, ENGLAND

TA01 Transfer of patent application right

Effective date of registration: 20101122

Address after: British Cayman Islands

Applicant after: O2 Tech. International Ltd.

Address before: American California

Applicant before: O2 Micro Inc

C14 Grant of patent or utility model
GR01 Patent grant
REG Reference to a national code

Ref country code: HK

Ref legal event code: GR

Ref document number: 1077881

Country of ref document: HK

CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20120926

Termination date: 20150208

EXPY Termination of patent right or utility model