CN201352762Y - Multi-level impulse sequence control device for switch power supply in pseudo continuous work mode - Google Patents

Abstract

A multi-level impulse sequence control device for a switch power supply operated in a pseudo continuous work mode is structurally characterized in that a voltage detecting circuit, an error amplifier, an error burst judging device, a multi-level impulse generator and a driving circuit are sequentially connected, a clock signal generator and the error burst judging device are connected with the multi-level impulse generator, and the current detecting circuit is connected with the multi-level impulse generator. The multi-level impulse sequence control device can realize multi-level impulse sequence control of the switch power supply in a pseudo continuous work mode. By utilizing the control device, output power of a converter is not limited by current critical conditions. Further, the multi-level impulse sequence control device is relatively low in output voltage ripples, fine in dynamic response and strong in anti-interference ability, and is adaptable to converters of various topological structures.

Description

The multi-stage pulse sequence control device of pseudo-continuous working mode

Technical field

The utility model relates to a kind of control device of Switching Power Supply.

Background technology

In recent years, power electronic technology develops rapidly, becomes the focus of application and research as the power technology of field of power electronics important component part.Along with the progress of manufacture technique of power electronic device and Semiconductor Converting Technology, Switching Power Supply has been established its dominant position in dc-dc conversion.Computer, communication apparatus, electron detection device, control appliance etc. all extensively adopt Switching Power Supply as electric supply installation.Switching Power Supply mainly is made of converter and controller two parts.Converter is called power circuit again, mainly comprises switching device, device for transformer and current rectifying and wave filtering circuit; Converter has Buck, Boost, normal shock, anti-various topological structures such as swashs.Controller is used to detect the operating state of converter circuit, and produces control wave control switch device, regulates the electric weight that passes to load and exports with stable.The control method decision that the structure of controller and operation principle are adopted by power supply.The converter technology is comparatively ripe at present, and the control circuit that control method and control method relate to becomes the key factor that influences the Switching Power Supply performance.Existing control method has traditional PWM control such as voltage-type, current mode, and the new type of control method such as pulse train control that occur are in recent years also arranged.

Pulse sequence control method is with controller generation high-energy control impuls or low-yield control impuls switching tube to be controlled.Its concrete control method is: judge output voltage V in the initial moment of each switch periods _oWith reference voltage V _RefBetween relation, if output voltage V _oBe lower than reference voltage V _Ref, controller will be selected the control signal of the big high-energy control impuls of duty ratio as converter, make the ON time of switching tube long, and inductive current rises to behind the corresponding current peak switching tube and turn-offs and finish this cycle, and output voltage raises; Otherwise will select the little low-yield control impuls of duty ratio, its working condition is to above-mentioned similar.The pulse train technology is selected high-energy or low-yield control impuls according to the relative size of output voltage instantaneous value, has capability of fast response preferably.Its weak point is: only can be used for the switch converters of Control work at inductive current discontinuous mode (DCM), working range is subjected to the restriction of inductive current critical condition, therefore is not suitable for large-power occasions; Converter output voltage fluctuating range is bigger during steady operation.Another kind of novel multi-stage pulse sequence control method has solved the bigger problem of ripple preferably, but also is to be used for the DCM converter.

For this reason, the applicant develops a kind of multi-stage pulse sequence control method (in the separate case patent application) of pseudo-continuous working mode, adopt this method to can be used for the high power switch converter of Control work in the pseudo continuous mode formula, and its dynamic response is good, antijamming capability is strong, is applicable to the converter of various topological structures.Its concrete practice is: voltage detecting circuit detects the output voltage V of converter ₀Send error amplifier, error amplifier is used output reference voltage V in the initial moment of each switch periods _RefWith output voltage V ₀Compare and produce error voltage value Δ V; The error burst determining device is to the error burst value δ of the individual output voltage of N (N 〉=1) of this error voltage value Δ V and setting _n, n=1,2 ... N, compare, select signal according to comparative result to multistage pulses generator output control pulse, it relatively with the rule of selecting is: as Δ V＞δ ₁The time, control impuls selects signal to make the multistage pulses generator produce switching tube S ₁Control impuls P ₁₁And S ₂Control impuls P ₁₂Work as δ _N-1〉=Δ V＞δ _n, N 〉=n＞1 o'clock, control impuls selects signal to make the multistage pulses generator produce switching tube S ₁Control impuls P _N1And S ₂Control impuls P _N2As Δ V≤δ _NThe time, control impuls selects signal to make the multistage pulses generator produce switching tube S ₁Control impuls P _N+11And S ₂Control impuls P _N+12The control impuls P that produces by multistage pulses generator MPG again _N1And P _N2Respectively by drive circuit DR ₁And DR ₂Switching tube S to converter TD ₁And S ₂Control.

The utility model content

The purpose of utility model provides a kind of device of realizing the multi-stage pulse sequence control method of pseudo-continuous working mode, form by converter and controller, controller comprises voltage detecting circuit, current detection circuit, drive circuit, clock signal generator, and its design feature is: voltage detecting circuit, error amplifier, error burst determining device, multistage pulses generator, drive circuit link to each other successively; Clock signal generator links to each other with error burst determining device and multistage pulses generator; Current detection circuit links to each other with the multistage pulses generator.

Compared with prior art, the beneficial effects of the utility model are:

One, the utility model is used for the switch converters of Control work in inductive current pseudo continuous mode formula (PCCM).Controller is by peak value and valley (or each switch periods switching tube S of each switch periods inductive current of control ₁ON time and inductive current valley, or each switch periods V _ESRPeak value and valley) realize to regulate, Control Parameter can be provided with according to the working range of converter.When keeping pulse train control and multi-stage pulse sequence control advantage, this control method can make the working range of controlled converter not be subjected to the restriction of inductive current critical condition, thereby has widened range of application.

Two, the initial moment reference voltage V of switch periods _RefWith the converter output voltage V ₀Difference DELTA V determine this periodic transformation device to what of load transfer energy.In the initial moment in switch periods, between Δ V is greater than highest region, be worth δ ₁The time, show output voltage V this moment ₀It is very big to fall amplitude, need make its rise as early as possible, and the utility model is selected control impuls P for use ₁₁And P ₁₂Switching tube S to converter ₁And S ₂Control, make switching tube S ₁ON time the longest, to transmit energy as much as possible, output voltage can be gone up as early as possible; On the contrary, when Δ V less than minimum interval value δ _NThe time, show output voltage V this moment ₀Be higher than reference voltage V _RefAnd amplitude is very big, need make its falling as early as possible, and the utility model is selected control impuls P for use _N+11And P _N+12To switching tube S ₁And S ₂Control, make switching tube S ₁ON time the shortest, to transmit the least possible energy, output voltage can be fallen after rise as early as possible.As seen the utility model control can readjust output voltage rapidly near reference voltage when converter is subjected to disturbance greatly, and the response time is short, and antijamming capability is strong.

When three, output voltage fluctuates near reference voltage, the utility model will adopt the intergrade control impuls P of corresponding suitable duty ratio _N1And P _N2Switching tube is controlled, the transmission energy is suitable, make output voltage remain near the interior among a small circle fluctuation of reference voltage when the steady operation state, most of operating times of the utility model will be selected the less intergrade control impuls P of the suitable and mutual difference of duty ratio _N1And P _N2The state of control switch pipe, each switch periods is less to the capacity volume variance of load transfer, makes output voltage remain near the interior among a small circle fluctuation of reference voltage, and promptly voltage ripple is less.

Above-mentioned multistage pulses generator produces control impuls P _N1And P _N2, n=1,2 ... the method for N+1 is: the multistage pulses generator is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the inductive current I in the converter _LBegin to rise; Current detection circuit is synchronous detecting inductive current I then _L, the multistage pulses generator is with this current signal I _LControl impuls P with this cycle _N1, n=1,2 ... N+1, pairing inductive current peak I _n, n=1,2 ... N+1, compare, work as electric current I _LRise to corresponding peak I _nThe time, control impuls P _N1Become low level by high level; Electric current I _LBegin immediately to descend, work as I _LDrop to until electric current valley I _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until this switch periods.

When disturbance occurred, inductor current signal can be affected, so inductive current I _LRise to current control impuls P _N1Pairing current peak I _nThe used time also can prolong or shorten accordingly, makes this switch periods P _N1The duty ratio of signal raises or reduces with the influence of disturbance suppression to converter.Similarly also can be to P _N2The duty ratio of signal exerts an influence.As seen, this mode is except that selecting appropriate this approach disturbance suppression of pulse by the switch periods after disturbance occurs, can also be by the feedback inhibition disturbance of switch periods internal inductance current signal, therefore the disturbance that the converter input is occurred has very fast response speed.Flow equalizing function when this mode has also realized the overcurrent protection of converter and a plurality of power supply parallel operation simultaneously.

Above-mentioned multistage pulses generator produces control impuls P _N1And P _N2, n=1,2 ... the another kind of method of N+1 is: the multistage pulses generator is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the inductive current I in the converter _LBegin to rise; P _N1Continue the high level fix time D _nBecome low level behind the T; Electric current I _LBegin immediately to descend, work as I _LDrop to until electric current valley I _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until switch periods.

The control impuls P of Chan Shenging like this _N1Duty ratio be default fixed value, can utilize existing any circuit that can produce a plurality of fixed duty cycle pulses to realize control.Fixing duty ratio also makes system's anti-interference stronger.

Above-mentioned multistage pulses generator produces control impuls P _N1And P _N2, n=1,2 ... the third method of N+1 is: the multistage pulses generator is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the voltage V in the converter on the equivalent series resistance of electric capacity (ESR) _ESRBegin to rise; Voltage detecting circuit is synchronous detecting voltage V then _ESR, the multistage pulses generator is with this voltage signal V _ESRControl impuls P with this cycle _N1, n=1,2 ... N+1, pairing voltage peak V _n, n=1,2 ... N+1 compares, as voltage V _ESRRise to corresponding voltage peak V _nThe time, control impuls P _N1Become low level by high level; Voltage V _ESRBegin immediately to descend, work as V _ESRDrop to until voltage valley V _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until this switch periods.

The production method of this multistage pulses, the duty ratio of multistage pulses is by the equivalent series resistance voltage and the preset reference value decision thereof of output filter capacitor.In each switch periods to the ripple voltage V on the output filter capacitor equivalent series resistance _ESRDetect, when disturbance appearred in the converter load end, this disturbance meeting had influence on ripple voltage V _ESRSo, V _ESRRise to current control impuls P _nThe equivalent series resistance voltage reference value K of pairing output filter capacitor _n ³The used time also can prolong or shorten accordingly, makes the duty ratio of this switch periods raise or reduces with the influence of disturbance suppression to converter.Therefore utilize the utility model to produce the Multistage Control pulse, except that selecting appropriate this approach disturbance suppression of pulse by the switch periods after disturbance occurs, can also be by the feedback inhibition disturbance of the ripple voltage signal on the output filter capacitor equivalent series resistance, therefore the disturbance that the converter load end is occurred has very fast response speed.

The course of work and the principle of this device are:

Output voltage detecting circuit detects the output voltage V of converter ₀, error amplifier is used output reference voltage V in the initial moment of each switch periods _RefWith output voltage V ₀Compare and produce error voltage value Δ V; The error burst determining device is to the error burst value δ of N output voltage of this error voltage value Δ V and setting _n, n=1,2 ... N, compare, export the control corresponding pulse selecting signal according to comparative result to the multistage pulses generator; Produce control impuls P by the multistage pulses generator again _N1And Pn ₂To converter switches pipe S ₁, S ₂Control.

As seen, adopt the utility model can realize above method easily and reliably.

Specifically consisting of of above-mentioned error burst determining device: by N comparator DC _nN=1,2 ... N and N trigger D _nN=1,2 ... N forms; Comparator DC _nPositive ends all link to each other with the output of error amplifier, the negative polarity end meets corresponding error burst value δ respectively _nSignal, output and trigger D _nData input pin link to each other; Trigger D _nInput end of clock link to each other trigger D with clock signal generator _nOutput link to each other with the multistage pulses generator.

Above error burst determining device and multistage pulses generator simple structure, stable performance can realize the function of error judgment and Multistage Control pulse generation in the utility model reliably.

Specifically consisting of of above-mentioned multistage pulses generator: produce P _N1The circuit of pulse is by N+1 comparator PC _nN=1,2 ... N+1 and N+1 trigger RS _n, n=1,2 ... N+1 and N+1 select 1 data selector (DS) to form; Comparator PC _nPositive ends all link to each other comparator PC with the output of converter inductive current testing circuit (IC) _nThe converter inductive current fiducial value K of negative polarity termination correspondence _n ¹, its output meets trigger RS _nReset terminal (R), trigger RS _nSet end (S) link to each other with clock signal generator (CPG), its output (Q) connects the data input pin that N+1 selects 1 data selector (DS), N+1 selects 1 data selector (DS) output termination switching tube S ₁Drive circuit (DR ₁).Produce P _N2The circuit of pulse is by 1 comparator PC _VWith 1 trigger RS _VForm; Comparator PC _VThe negative polarity end link to each other comparator PC with the output of converter inductive current testing circuit (IC) _VPositive polarity termination inductive current valley K _V, its output meets trigger RS _VReset terminal (R), trigger RS _nSet end (S) select 1 data selector (DS) output to link to each other trigger RS with above-mentioned N+1 _nOutput (Q) meet switching tube S ₂Drive circuit (DR ₂).

Like this, the multistage pulses generator is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the inductive current I in the converter _LBegin to rise; Current detection circuit is synchronous detecting inductive current I then _L, the multistage pulses generator is with this current signal I _LControl impuls P with this cycle _N1, n=1,2 ... N+1, pairing inductive current peak I _n, n=1,2 ... N+1, compare, work as electric current I _LRise to corresponding peak I _nThe time, control impuls P _N1Become low level by high level; Electric current I _LBegin immediately to descend, work as I _LDrop to until electric current valley I _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until this switch periods.

Like this, the duty ratio of control signal is determined by inductive current.The control device of this structure, except that selecting this approach disturbance suppression of pulse of appropriate duty ratio by the switch periods after disturbance occurs, can also be by the inductor current signal disturbance suppression of switch periods internal feedback, therefore the disturbance that the converter input is occurred has very fast response speed.Flow equalizing function when this mode has also realized the overcurrent protection of converter and a plurality of power supply parallel operation simultaneously.

The control device of this structure can also be used for second method and the third method that above-mentioned multistage pulses generator produces control impuls through simple change.

Below in conjunction with the drawings and specific embodiments the utility model is described in further detail.

Description of drawings

Fig. 1 is the signal flow graph of the utility model embodiment.

Fig. 2 is the circuit structure block diagram of the utility model embodiment one.

Fig. 3 is the circuit structure diagram of the error burst determining device of the utility model embodiment one.

Fig. 4 is the circuit structure diagram of the multistage pulses generator of the utility model embodiment one.

Fig. 5 a is the utility model embodiment one a certain period control impuls P under limit _N1The time-domain-simulation oscillogram.

Fig. 5 b is and Fig. 5 a control impuls P of same period _N2The time-domain-simulation oscillogram.

Fig. 5 c is the time-domain-simulation oscillogram with the same period converter inductive current of Fig. 5 a.

Fig. 5 d is the time-domain-simulation oscillogram with Fig. 5 a converter output voltage of same period.

Fig. 5 simulated conditions is as follows: input voltage V _In=15V, output voltage reference value V _Ref=8V, inductance L=100uH, capacitor C=1410uF, load resistance R=5 Ω, switch periods T=50 μ s, P ₁₁Corresponding inductive current peak is 3.8A, P ₂₁Corresponding inductive current peak is 3.55A, P ₃₁Corresponding inductive current peak is 2.9A, P ₄₁Corresponding inductive current peak is that 2.5A, inductive current valley are three grades of error voltage interval value δ of 2A, setting ₁=20mV, δ ₂=0mV, δ ₃=-20mV.

Fig. 6 a is the simulation waveform figure of embodiment one converter output voltage when load variations (load on 20ms constantly by 8W transition to 20W).

Fig. 6 b be prior PWM control change device when same load variations, the simulation waveform figure of output voltage.Fig. 6 simulated conditions is identical with Fig. 5.

Fig. 7 a is the simulation waveform figure of embodiment one converter output voltage when load variations (load on 20ms constantly by 6.4W transition to 12.8W).

Fig. 7 b is that existing pulse train is controlled the DCM converter when same load variations, the simulation waveform figure of output voltage.Fig. 7 simulated conditions is identical with Fig. 5.

Fig. 8 is the circuit structure block diagram of the utility model embodiment two.

Fig. 9 is the circuit structure block diagram of the utility model embodiment three.

Embodiment

Embodiment one

Fig. 1 illustrates, a kind of embodiment of the present utility model:

Voltage detecting circuit VCC detects the output voltage V of converter TD ₀, error amplifier VA uses output reference voltage V in the initial moment of each switch periods _RefWith output voltage V ₀Compare and produce error voltage value Δ V; Error burst determining device VC is to the error burst value δ of N=3 output voltage of this error voltage value Δ V and setting _n, n=1,2,3, compare, to multistage pulses generator MPG output control corresponding pulse selecting signal, it relatively with the rule of selecting is: as Δ V＞δ according to comparative result ₁The time, the output signal of error burst determining device VC makes multistage pulses generator MPG produce control impuls P ₁₁And P ₁₂Work as δ ₁〉=Δ V＞δ ₂The time, output signal makes multistage pulses generator MPG produce control impuls P ₂₁And P ₂₂Work as δ ₂〉=Δ V＞δ ₃The time, output signal makes multistage pulses generator MPG produce control impuls P ₃₁And P ₃₂As Δ V≤δ ₃The time, output signal makes multistage pulses generator MPG produce control impuls P ₄₁And P ₄₂The control impuls P that produces by multistage pulses generator MPG again _N1And P _N2, n=1,2,3,4 respectively by drive circuit DR ₁And DR ₂Switching tube S to converter TD ₁And S ₂Control.

Fig. 1 also illustrates, Multistage Control pulse P _N1And P _N2Concrete producing method be: multistage pulses generator MPG is in the initial moment of each switch periods, output P _N1Be high level, P _N2Be low level, the inductive current I among the converter TD _LBegin to rise; Current detection circuit IC is synchronous detecting converter current I then _L, multistage pulses generator MPG is with this electric current I _LThe control impuls P in signal and this cycle _N1Pairing inductive current peak I _n, n=1,2,3,4, compare, work as electric current I _LRise to corresponding peak I _nThe time, control impuls P _N1Become low level by high level; Electric current I _LBegin immediately to descend, work as I _LDrop to until electric current valley I _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until switch periods.

This example adopts following device, and above-mentioned control method is realized quickly and easily.Fig. 2 illustrates, and the device of the control method of the Switching Power Supply that this is routine is made up of converter TD and controller, and controller comprises voltage detecting circuit VCC, current detection circuit IC, drive circuit DR, clock signal generator CPG.Voltage detecting circuit VCC, error amplifier VA, error burst determining device VC, multistage pulses generator MPG, drive circuit DR link to each other successively; Clock signal generator CPG links to each other with error burst determining device VC and multistage pulses generator MPG; Current detection circuit IC links to each other with multistage pulses generator MPG.

Fig. 3 illustrates, and the error burst determining device VC that this is routine specifically consists of: by N=3 comparator DC _nN=1,2,3 and N=3 trigger D _nN=1,2,3 form; 3 comparator DC _nPositive ends all link to each other with the output of error amplifier VA, the negative polarity end is set at corresponding error burst value δ respectively _n, output and relative trigger device D _nData input pin link to each other; Trigger D _nInput end of clock link to each other trigger D with clock signal generator CPG _nOutput Q _n/ Q _nMPG links to each other with the multistage pulses generator.

Fig. 4 illustrates, and this routine multistage pulses generator MPG is the level Four pulse generator, and it specifically consists of: by N+1=4 comparator PC _n, n=1,2,3,4 and N+1=4 trigger RS _nN=1,2,3,4 and 4 select 1 data selector DS to form; Comparator PC _nPositive ends all link to each other comparator PC with the output of current detection circuit IC _nThe negative polarity end meet corresponding inductive current peak I respectively _n(be PC ₁Negative pole termination current peak I ₁, PC ₂Negative pole termination current peak I ₂); Its output meets trigger RS _nReset terminal R; Trigger RS _nSet end S link to each other with clock signal generator CPG, output Q connects 4 data input pins that select 1 data selector DS, data selector DS output termination drive circuit DR ₁

4 of this example selects 1 data selector to be made up of the two-level logic door, the first order be four with door G1, a G2, G3, G4, the second level be or a G5.Four trigger RS among the multistage pulses generator MPG ₁, RS ₂, RS ₃, RS ₄Output Q, respectively correspondingly link to each other the output Q of error burst determining device VC with G1, G2, G 3, G4 door ₁, Q ₂, Q ₃Link to each other Q with the G1 door ₁, Q ₂, Q ₃Link to each other Q with the G2 door ₁, Q ₂, Q ₃Link to each other Q with the G3 door ₁, Q ₂, Q ₃Link to each other with the G4 door.The output Q of error burst determining device VC ₁, Q ₂, Q ₃, Q ₁, Q ₂, Q ₃, three trigger D in fact just ₁, D ₂, D ₃Corresponding output Q, Q.Four with the door output all connect or the door G5 input, or the door G5 output link to each other with drive circuit DR.When reality is implemented, also can select other any existing data selector for use.More than produce P among the multistage pulses generator MPG _N1Circuit.

Fig. 4 also illustrates among the multistage pulses generator MPG and produces P _N2Circuit: comparator PC ₅The negative polarity end all link to each other positive polarity termination inductive current valley I with the output of current detection circuit IC _VIts output meets trigger RS _nReset terminal R; Trigger RS _nSet end S link to each other with data selector DS output, output Q meets drive circuit DR ₂

Its course of work of the device of this example and principle are:

Fig. 1-4 illustrates, and 4 grades of pulse generators all produce N+1=4 the control impuls P that duty ratio descends successively that sets in each switch periods _N1, n=1,2,3,4, its producing method is: in the initial moment of each switch periods, the clock signal that the clock signal generator CPG of controller produces makes each control impuls P _N1Be high level; Current detection circuit IC is the inductive current I among the synchronous detecting converter TD then _L, this electric current I _LEnter four comparator PC in 4 grades of pulse generators _n, by PC _nWith this electric current I _LWith the control impuls P that sets respectively _N1Pairing inductive current peak I _n, n=1,2,3,4 (I ₁, I ₂, I ₃, I ₄) compare; Detailed process relatively is: work as I _LRise to peak I _nThe time, corresponding control impuls P _N1Become low level by high level, finish until switch periods.Like this, promptly at 4 RS of multistage pulses generator _nN=1, the output Q of 2,3,4 triggers export four (level Four) control impuls P that duty ratio corresponding is successively decreased successively respectively ₁₁, P ₂₁, P ₃₁, P ₄₁

Control impuls P _N1Selection: Fig. 2-4 illustrates, and in the initial moment of arbitrary switch periods, voltage detecting circuit VCC detects the output voltage V of converter TD ₀, error amplifier VA reference voltage V _RefWith output voltage V ₀Compare and produce error voltage value Δ V.Error burst determining device VC is to the error burst value δ of N=3 output voltage of this error voltage value and setting _n, n=1,2,3, compare the trigger D of error burst determining device VC _nThe output output control pulse is selected signal Q _n/ Q _n, select 1 data selector DS to select corresponding control impuls P by 4 _N1In this example, it selects control impuls P _nThe more detailed course of work is: as Δ V＞δ ₁The time, the output signal Q of error burst determining device VC then ₁, Q ₂, Q ₃Be high level, select all being blocked with door G2, G3, G4 of 1 data selector this moment 4, only has G1 open-minded, the trigger RS that links to each other with G1 ₁Control impuls P on the output Q ₁₁A warp or a door G5 export drive circuit DR to ₁As Δ V＜δ ₃The time, Q ₁, Q ₂, Q ₃All be output as low level, G1, G2, G3 all are blocked, and only have G4 open-minded, the trigger RS that links to each other with G4 ₄Control impuls P on the output Q ₄₁A warp or a door G5 export drive circuit DR to ₁In like manner, work as δ ₁〉=Δ V＞δ ₂Perhaps δ ₂〉=Δ V＞δ ₃The time, select signal Q by control impuls _n/ Q _nGating control impuls P ₂₁Or P ₃₁Like this, multistage pulses generator MPG has promptly finished and has produced corresponding control impuls P _N1The process of control change device work.

Control impuls P _N2Producing method be: at the initial moment of each switch periods, P _N1Be high level, trigger RS ₅Be set, output Q is a low level; Work as P _N1After becoming low level, inductive current I _LBegin to descend, simultaneously PC ₅Output signal can pass through trigger RS ₅Export drive circuit DR to ₂Work as I _LDrop to valley I _VThe time, P _N2Become high level by low level, finish until switch periods.Like this, trigger RS ₅Output Q output control pulse P _N2

This routine converter is the Buck converter.

With Matlab/Simulink software this example is carried out the time-domain-simulation analysis, the result is as follows.

Fig. 5 a, Fig. 5 b, Fig. 5 c and Fig. 5 d are respectively the control wave P that emulation obtains _N1, control wave P _N2, inductive current I _LAnd output voltage V ₀Waveform.As can be seen from Figure 5,3 switch periods are formed cycle period, P _N1The control impuls sequence is: P ₂₁-P ₃₁-P ₃₁

Fig. 6 a is the simulation waveform figure of embodiment one converter output voltage when load changing (load on 20ms constantly by 8W transition to 20W).Fig. 6 b be prior PWM control change device when same load variations, the simulation waveform figure of output voltage.As seen, pwm controlled converter is after disturbance occurs, and through recovering stable state substantially behind about 1.5ms, output voltage falls nearly 0.2V; And under the same condition, when adopting the utility model to control, Switching Power Supply can enter new stable state rapidly, tangible electric voltage dropping do not occur.So transient response ability of the present utility model is much better than PWM control.

Fig. 7 a is the simulation waveform figure of embodiment one converter output voltage when load changing (load on 20ms constantly by 6.4W transition to 12.8W).Fig. 7 b is that existing pulse train is controlled the DCM converter when same load variations, the simulation waveform figure of output voltage.As seen, load the back converter with load surpassed the load upper limit of pulse train control change device, output voltage occurs continuing to descend, converter can't operate as normal; And under the same condition, when adopting the utility model to control, converter still can steady operation.So the switch converters working range of the utility model control is bigger.

Embodiment two

Fig. 8 illustrates, and this example is basic identical with embodiment one, and difference is: the number N of the error burst value of the output voltage of setting is 4, δ _n, n=1,2,3,4, control corresponding pulse P _N1Be five, i.e. P ₁₁, P ₂₁, P ₃₁, P ₄₁, P ₅₁Multistage pulses generator MPG produces control impuls P _n, n=1,2,3,4,5 method is: multistage pulses generator (MPG) is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the inductive current I in the converter (TD) _LBegin to rise; P _N1Continue the high level fix time D _nBecome low level behind the T; Electric current I _LBegin immediately to descend, work as I _LDrop to until electric current valley I _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until switch periods.

The converter TD of the Switching Power Supply of this example control is the Boost converter, as shown in Figure 8.

Embodiment three

Fig. 9 illustrates, and this example is basic identical with embodiment one, and difference is: the number N of the error burst value of the output voltage of setting is 5, δ _n, n=1,2,3,4,5, control corresponding pulse P _N1Be six, i.e. P ₁₁, P ₂₁, P ₃₁, P ₄₁, P ₅₁, P ₆₁Multistage pulses generator MPG produces control impuls P _n, n=1,2,3,4,5,6 method is: multistage pulses generator (MPG) is exported P in the initial moment of each switch periods _N1Be high level, P _N2Be low level, the voltage V in the converter (TD) on the equivalent series resistance (ESR) of electric capacity _ESRBegin to rise; Voltage detecting circuit (VCC ') is synchronous detecting voltage V then _ESR, multistage pulses generator (MPG) is with this voltage signal V _ESRControl impuls P with this cycle _N1, n=1,2 ... N+1, pairing voltage peak V _n, n=1,2 ... N+1 compares, as voltage V _ESRRise to corresponding peak value V _nThe time, control impuls P _N1Become low level by high level; Voltage V _ESRBegin immediately to descend, work as V _ESRDrop to until electric current valley V _VThe time, control impuls P _N2Become high level by low level, diode turn-offs, and inductive current is by switching tube S ₂Afterflow finishes until this switch periods.

The converter TD of the Switching Power Supply of this example control is the Buck-Boost converter, as shown in Figure 9.

Obviously, the utility model can be provided with other quantity of control impuls level according to the actual working state and the performance requirement of Switching Power Supply when implementing.More alternative control impuls ranks are set, generally can obtain better to control effect, but can increase the complexity of controller simultaneously to a certain extent.

The utility model is a kind of audio-frequency control device of deciding, and the switching frequency of Switching Power Supply is determined by external clock pulse.It can be realized with analogue device or digital device easily; The Switching Power Supply that converter in can be used for above embodiment is formed, also can be used for multiple power circuit such as Cuk converter, BIFRED converter, anti exciting converter, half-bridge converter, full-bridge converter and form Switching Power Supply.

Claims (3)

1, a kind of multi-stage pulse sequence control device of pseudo-continuous working mode, form by converter TD and controller, controller comprises voltage detecting circuit VCC, current detection circuit IC, drive circuit DR, clock signal generator CPG, it is characterized in that: described voltage detecting circuit VCC, error amplifier VA, error burst determining device VC, multistage pulses generator MPG, drive circuit DR link to each other successively; Clock signal generator CPG links to each other with error burst determining device VC and multistage pulses generator MPG; Current detection circuit IC links to each other with multistage pulses generator MPG.

2, the multi-stage pulse sequence control device of pseudo-continuous working mode according to claim 1, it is characterized in that: described error burst determining device VC specifically consists of: by N comparator DC _n, n=1,2 ... N and N trigger D _nN=1,2 ... N forms; Comparator DC _nPositive ends all link to each other with the output of error amplifier VA, the negative polarity end meets corresponding error burst value δ respectively _nSignal, output and trigger D _nData input pin link to each other; Trigger D _nInput end of clock link to each other trigger D with clock signal generator CPG _nOutput link to each other with multistage pulses generator MPG.

3, the multi-stage pulse sequence control device of pseudo-continuous working mode according to claim 1, it is characterized in that: described multistage pulses generator MPG specifically consists of: produce P _N1The circuit of pulse is by N+1 comparator PC _nN=1,2 ... N+1 and N+1 trigger RS _nN=1,2 ... N+1 and N+1 select 1 data selector DS to form; Comparator PC _nPositive ends all link to each other comparator PC with the output of converter inductive current testing circuit IC _nThe converter inductive current reference value I of negative polarity termination correspondence _n, its output meets trigger RS _nReset terminal R, trigger RS _nSet end S link to each other with clock signal generator CPG, its output Q connects the data input pin that N+1 selects 1 data selector DS, N+1 selects 1 data selector DS output termination switching tube S ₁Drive circuit DR ₁Produce P _N2The circuit of pulse is by 1 comparator PC _VWith 1 trigger RS _VForm; Comparator PC _VThe negative polarity end link to each other comparator PC with the output of converter inductive current testing circuit IC _VPositive polarity termination inductive current valley I _V, its output meets trigger RS _VReset terminal R, trigger RS _nSet end S select 1 data selector DS output to link to each other trigger RS with above-mentioned N+1 _nOutput Q meet switching tube S ₂Drive circuit DR ₂

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