CN1392659A - DC-DC conversion integrated circuit - Google Patents

Abstract

A DC-DC conversion integrated circuit is to apply channel D or channel N power switch tube separately to voltage increasing or reducing conversion to cut-in/out the input voltage according to control signals. A comparator compares a compared voltage from the feedback outpt voltage with the reference voltage. PWM oscillator provides a switch clock of adjustable pulse width to the power switch tubes and PFM controller input is the output of the oscillator and the comparator, which is the said control signal. The adjustable feedback shunt resistance circuit is used to solve the problem of unstable product performance due to the technical shortcomings to reduce ripples of output voltage.

Description

DC-DC conversion integrated circuit

Technical field:

The present invention relates to a kind of DC-DC conversion integrated circuit, be a kind of Switching Power Supply integrated circuit of (or step-down) type dc-dc conversion that is used to boost, be widely used in the portable electric appts such as notebook computer, mobile phone, PDA, GPS receiver, pen input device, digital camera, beep-pager, handheld terminal, senior toy.

Background technology:

DC-to-DC (being called for short DC-DC) conversion integrated circuit is the core that is described as the Switching Power Supply of energy-efficient power supply, and its volume is little, and price is low, the efficient height.External many major companies as Linear Technology, Maxim, Analog Devices, National Semiconductor and Ricoh etc., all have a large amount of outstanding DC-DC conversion chips to sell on worldwide market.Yet because this class chip needs the analog IC designing technique, development difficulty is big, so the domestic blank that is almost in this respect, the overwhelming majority is dependence on import all.

Chinese invention patent: switching regulator (publication number: CN 1282137A) introduced two kinds of step-up DCs-DC converter, step-up DC-DC the converter of PWM (pulse width modulation) working method wherein, input links to each other with the drain electrode of N channel power switching transistor by a coil, connects with the lead-out terminal that is connected load by a diode from this tie point.At the two ends of load, filter capacitor in parallel.This output signal is by two electric resistance partial pressures, and the signal of this dividing point is amplified by error amplifier with the voltage of reference voltage source.The output voltage of the output signal of this error amplifier and the triangular-wave generator that repeats by certain frequency compares in comparator, and the output of this comparator is connected to the grid of described power switch transistor.According to the duty ratio of the output waveform that changes described comparator, the conduction and cut-off of the described switching transistor of may command, thus can obtain the little voltage output of ripple on the lead-out terminal of accurate control.

In the step-up DC-DC converter of another kind of PFM (pulse frequency modulated) working method, identical with described PWM working method converter is, input links to each other with the drain electrode of N channel power switching transistor by a coil, connects with the lead-out terminal that is connected load by a diode from this tie point.At the two ends of load, filter capacitor in parallel.Different with described PWM working method converter is, removed error amplifier, increased the AND circuit, and replaced triangular-wave generator with oscillator, again the AND circuit is imported in the output of this oscillator and the output of comparator together, control described power switch transistor by the umber of pulse of its output, thus control output voltage.

The pulsation of the converter output voltage of PWM working method less (about 1mV) just often adopts PWM mode efficient higher in load.But; because triangular-wave generator and error amplifier must be arranged; and; because the protective circuit of output potential under situation beyond the comparison range to the output potential and the described comparator of this triangular-wave generator must be arranged; and the control logic circuit that makes the DC-DC converter reach certain performance index and increase must be arranged; thereby make its circuit scale big and complicated, be unfavorable for realizing with integrated circuit.

In the converter of PFM working method, during its all course of work, its pulse duration is all fixed, the conduction and cut-off of coming the power controlling switching tube by the umber of pulse of AND circuit output, thereby circuit form is simple, be easy to come with silicon chip integrated, and load adopts the power consumption of PFM mode less when light.But the pulsation of its output voltage wants big with comparing mutually of PWM mode.

Above-mentioned two kinds of step-up DCs-DC converter is not all made integrated circuit, fails further reduced volume, reduces the cost, to satisfy the demand of portable set.

Summary of the invention:

The objective of the invention is at the deficiencies in the prior art, a kind of high efficiency (or step-down) type DC-to-DC (DC-DC) conversion integrated circuit that boosts is provided, both had the advantage that described PFM working method converter is easy to realize, the characteristic that has described PWM working method converter again, key parameter in the circuit is optimized, thereby improves conversion efficiency and reduce the ripple of output voltage.

For realizing such purpose, DC-DC conversion integrated circuit of the present invention comprises: power switch MOSFET, turn-off/the conducting input voltage according to control signal; Comparator will feed back that output voltage is resulting to be compared voltage and reference potential compares; Oscillator provides suitable switch clock to described power switch MOSFET; Controller, it is input as the output of described oscillator and the output of described comparator, and it is output as described control signal.

The oscillator that the present invention adopts is the PWM type, the pulse duration that is the switch clock can be regulated, the controller that adopts is the PFM type, circuit structure adopts better simply PFM working method, the AND circuit is become the PFM type controller, be convenient to power switch MOSFET more accurately be controlled, to improve the performance of whole boost-voltage regulator according to the output of oscillator.Overriding feedback divider resistance circuit adopts normal state current fusing adjustment technology, with caused reference potential deviations of variations such as technology deviation and temperature by transferring to compensate to feeding back repairing of divider resistance.

Integrated circuit available standards N trap of the present invention (or P trap) CMOS technology is integrated on silicon chip.By connecting an inductance coil, a diode and an electric capacity in the integrated circuit outside, can constitute complete DC-DC converter, be the purpose of stable output voltage to finish input voltage is boosted (or step-down), to satisfy the demand of portable type electronic product.

The present invention combines traditional PFM working method converter and PWM working method converter, has had the advantage of the two on performance concurrently: adopt PFM type circuit structure and control mode, and simple and reliable, be easy on silicon chip, carry out integrated; Adopt overriding feedback bleeder circuit,, the pulsation peak value of VOUT is controlled in tens mV, thereby obtain the output voltage ripple value better than PFM mode by the position of current fusing point suitably is set.Adopt the oscillator of PWM type,,, and therefore improved the operating efficiency of chip for Circuit Optimization provides the space because pulse duration is adjustable.

DC-DC converter of the present invention can also have other circuit topology form, as external diode being changed to power switch MOSFET and being integrated in the chip etc.

The drawing explanation:

Fig. 1 is the circuit diagram of step-up DC of the present invention-DC converter embodiment.

As shown in Figure 1, shown in the square frame is step-up DC-DC conversion integrated circuit, an input f point of comparator 12 connects reference voltage source 14, another input d point connects overriding divider resistance 7 and 8, the other end ground connection of overriding resistance 8, the other end of overriding resistance 7 are output 2.An output c point that is input as comparator 12 of PFM type controller 11; Another is input as the b point, output 1 point of b point and PWM type oscillator 13, m point, in the p point one and can only be connected with one of them, the output a point of controller 11 is connected to the grid of N channel power switch MOS FET 9, thereby controls its shutoff/conducting.The source ground of power switch MOSFET 9.Described integrated circuit can constitute complete step-up DC-DC converter by following connected mode: the drain electrode k point of power switch 9 links to each other with input 1 by inductance coil 5, and be connected with output 2 by diode 6, between output 2 and ground, be parallel with filter capacitor 4 and load 3.

Fig. 2 is Fig. 1 circuit output voltage oscillogram.

Visible output voltage is divided into ascent stage and voltage stabilizing stage among Fig. 2.

Fig. 3 is an each point oscillogram in Fig. 1 circuit.

Fig. 3 has provided the waveform of the current i/PLUS of output VOUT, input VIN, a point, b point, c point, k point and inductance coil 5.

Fig. 4 is the partial enlarged drawing of each point waveform among Fig. 3.

Fig. 5 is that normal state current fusing of the present invention is adjusted schematic diagram.

Fig. 5 has provided the specific implementation situation of overriding resistance 7 and 8 in chip in the feedback divider resistance circuit.Among the figure, R0 is a square resistance, resistance 7=R3+R4+R5+R6+R7+R8+R9, resistance 8=R1+R2, all available short circuit current fusing of the every adjacent point-to-point transmission of A, B, C, D, E, F, G and H.By the position of current fusing point suitably is set, determine overriding resistance 7 and 8, proofread and correct because the variation that VOUT appears in the change of technological parameter.

Fig. 6 is the circuit diagram of buck DC-DC converter embodiment of the present invention.

What Fig. 6 was different with step-up DC shown in Figure 1-DC converter is, power switch pipe 10 is P channel mosfets, and be connected in the major loop that constitutes by it and inductance coil 5, diode 6, filter capacitor 4 and load 3, its source electrode links to each other with input, drain electrode is by diode ground connection, simultaneously through inductance coil and filter capacitor and load ground connection in parallel.

Embodiment:

Below in conjunction with accompanying drawing and specific embodiment technical scheme of the present invention is further described.Embodiment 1: step-up DC-DC converter

The circuit of present embodiment step-up DC-DC converter as shown in Figure 1.

Be depicted as step-up DC-DC conversion integrated circuit in Fig. 1 square frame, an input of comparator 12 is applied the reference voltage of reference voltage source 14 by tie point f, and its another input is compared voltage from tie point d input, the d point connects two overriding feedback divider resistances 7 and 8, the other end ground connection of overriding resistance 8, another termination output voltage of overriding resistance 7.

An output (c point) that is input as comparator 12 of PFM type controller 11, it another is input as the b point, according to the requirement of entire circuit optimization in Properties, output 1 point of b point and PWM type oscillator 13, the m point ..., in the p point one and can only be connected with one of them, the output a point of controller 11 is connected to the grid of N channel power switching tube 9, thereby controls its shutoff/conducting.The source ground of power switch MOSFET 9.

Input 1 connects power supplys such as battery, and by inductance coil 5, is connected with the drain electrode of switching tube 9 by PAD (pressure welding point) the k point of DC-DC chip, and the k point passes through diode 6 and is connected with output 2, between output 2 and ground, is parallel with filter capacitor 4 and load 3.Via the PAD of output 2, output voltage VO UT links to each other with an end of overriding resistance 7.

The inductance coil 5 of power switch MOSFET 9, storage power, fly-wheel diode 6, filter capacitor 4 and load 3 have constituted major loop, it mainly act as power conversion, wherein power switch MOSFET 9 is attempted by in the major loop.PFM type controller 11 is according to the output (c point current potential) and the b point current potential of comparator 12, conducting/shutoff that output control signal (a point current potential) is come power controlling switching tube 9, finish from intake to the conversion of exporting energy by major loop again, its circuit topology guarantees VOUT＞VIN, thereby finishes the function of boosting.

The output voltage (3V) of expectation is higher than input voltage VIN (1.5V) on the boost converter output 2, and its course of work can be divided into two stages, (Step-Up) and the voltage stabilizing output (VoltageStabilization) of promptly progressively boosting.From the waveform of Fig. 2 VOUT as can be seen, approximately 1.1ms was boost phase progressively in the past, was later on the voltage stabilizing output stage at 1.1ms.

At boost phase progressively, because VOUT is all the time less than 3V, so the output of comparator 12 (c point current potential) is always high level, at this moment, inoperative by overriding resistance 7 and 8 negative-feedback circuits of forming, the DC-DC converter boosts at full speed with a certain fixed pulse duty ratio fixed pulse frequency.Whether is zero by the current i that flows through inductance coil 5 when the pulse period begins, and can be divided into continuous conduction mode (CCM) and two kinds of working methods of DCM (DCM).From the local waveform amplification of Fig. 4 circuit each point as can be seen, in this stage, the DC-DC converter is operated in the CCM state, because i is all non-vanishing when each pulse period begins.When the output (a point current potential) of PFM controller 11 when being high level, switching tube 9 conductings, electric energy is stored in the inductance coil 5 with the magnetic energy form, and electric capacity 4 is by load 3 discharges.Because connecing the negative pole of VIN, ends on the anode of diode 6, so electric capacity 4 can not be by diode 6 discharges.When the output (a point current potential) of PFM controller when being low level, switching tube 9 ends, and the polarity of voltage at inductance coil 5 two ends changes, like this, voltage that magnetic energy in the inductance coil 5 changes into and power supply VIN series connection are powered to electric capacity 4 and load 3 with the voltage that is higher than VOUT.So constantly repeatedly, inductance coil 5 is the storage magnetic energy constantly, and are translated into electric energy and supply with electric capacity 4 and load 3, and this electric energy can not pass through diode 6 playback, thus VOUT progressively rise, so be called Step-Up again.

At the voltage stabilizing output stage, because VOUT has been raised to 3V when progressively boost phase finishes, and as can be seen from Fig. 2 to Fig. 4, it is central value and constantly fluctuation up and down that VOUT is actually with 3V, the output of comparator 12 (c point current potential) is irregular impulse waveform, and this impulse waveform is mainly relevant with the variation of the caused VOUT of variation of load 3.In this stage, play important effect by overriding resistance 7 and 8 negative-feedback circuits of forming.As can be seen from Figure 4, at the voltage stabilizing output stage, the DC-DC converter is operated in the DCM state, is zero when some pulse period begins because flow through the current i of inductance coil 5.Suppose since certain variations of load 3 grades make VOUT exceed 3V and reach a certain value (suppose=V+), the reference potential that ordered by the output (d point current potential) and the f of 7 and 8 negative-feedback circuits of forming this moment compares in comparator 12, its output (c point current potential) is low level, pass through the effect of controller 11 again, consequently disconnected oscillator 13, this moment, the output (a point current potential) of controller 11 was low level, switching tube 9 disconnects, the magnetic energy that is stored in the inductance coil 5 constantly is converted into electric energy, like this, the current i that flows through wherein drops to zero gradually.And VOUT begins to drop to 3V by V+ and continue to drop to a certain value and (suppose=V-, obviously V-＜3V＜V+).At this moment, described d point current potential and f point current potential result relatively makes the output of comparator 12 be reversed high level, thus this DC-DC converter work by the mode identical with described progressively boost phase, VOUT progressively rises to 3V again and continues to rise to V+.Different with described progressively boost phase is that this process of boosting is very short, generally has only the time of several pulse periods.After VOUT was raised to V+, the output of comparator 12 became low level again, and VOUT begins to descend again, and is continuous so repeatedly, and VOUT then is constantly fluctuation up and down of center with 3V.As can be seen, this turn-offs during clock pulse in stage, the time and the effect of PFM control has been played in conducting.

It should be noted that Fig. 2 to Fig. 4 obtains at a certain fixing load 3, when load 3 changed in a certain scope, the waveform of Fig. 2 to Fig. 4 also can be done corresponding variation, can change as the umber of pulse of clock conducting, but described overall rule can not change.

The present invention has adopted normal state current fusing adjustment technology, overriding resistance 7=R3+R4+R5+R6+R7+R8+R9, and overriding resistance 8=R1+R2 fetches between the ratio by overriding resistance 7 and 8 and adjusts f point current potential, and its principle is as shown in Figure 5.With the mathematic expectaion of the corresponding normal distribution of the process for stabilizing value of Foundry, corresponding here R9 and these two resistance values of R1, promptly overriding resistance 7 is R9, overriding resistance 8 is R1.At this moment, VOUT/d point current potential=(R9+R1)/and R1=29R0/11R0 (R0 is a square resistance), do not need any adjustment.

As because of the isoparametric change of technology, f point current potential departs from its desired value, make VOUT undesirable variation occur, make the just above-mentioned variation of recoverable of VOUT/d point current potential=33R0/11R0, then make E, the fusing of F point-to-point transmission with short circuit current, thereby VOUT/d point current potential=(11R0+18R0+4R0)/11R0, other situation is analogized.

PWM type oscillator 13 is that pulse duration is adjustable, for the optimal design of entire circuit provides the space.After the optimization, efficient can be improved (for example 3-6%).In addition, progressively the speed of boost phase, VOUT overshoot, carrying load ability etc. all can be optimized.

PFM type controller 11 has two effects: the first, and at clock pulse 1 point of the different duty of PWM type oscillator output, the m point ..., select and only select one to link to each other according to certain performance index is preferential in the p point waveform with the b point.As the highest optional 1 point of an efficiency of selection (is 79% as duty ratio); As should the efficient height, the fast optional m point of the process of progressively boosting again (is 86% as duty ratio).The second, the computing of logical AND is carried out in the output (c point current potential) of b point current potential and comparator 12, its result gives a point current potential, the conduction and cut-off of removing power controlling switching tube 9.Embodiment 2: buck DC-DC converter

The circuit of present embodiment buck DC-DC converter as shown in Figure 6.

Be depicted as the buck DC-DC conversion integrated circuit in Fig. 6 square frame, what the DC-DC converter of voltage-dropping type was different with step-up DC shown in Figure 1-DC converter is, power switch pipe 10 is MOSFET of P raceway groove, and is connected in the major loop that is made of it and inductance coil 5, diode 6, filter capacitor 4 and load 3.The source electrode of P channel power switching tube 10 links to each other with input 1, and drain electrode is by diode 6 ground connection, simultaneously through inductance coil 5 and filter capacitor 4 and load 3 ground connection in parallel.Such circuit topology guarantees VOUT＜VIN, thereby finishes the function of step-down.

Claims (4)

1, a kind of DC-DC conversion integrated circuit, an input that it is characterized in that comparator (12) connects reference voltage source (14), another input connects overriding divider resistance (7,8), the other end ground connection of overriding resistance (8), the other end of overriding resistance (7) is output (2), an output that is input as comparator (12) of PFM type controller (11), another is input as in the output of PWM type oscillator (13) one, the output of controller (11) is connected to the grid of N channel power switching tube (9), the source ground of power switch pipe (9), drain electrode is drawn.

2, as the said DC-DC conversion integrated circuit of claim 1, it is characterized in that the output of its middle controller (11) is connected to the grid of P channel power switching tube (10), the source electrode of power switch pipe (10) and drain electrode are drawn simultaneously.

3, as the said DC-DC conversion integrated circuit of claim 1, the drain electrode that it is characterized in that N channel power switch (9) links to each other with input (1) by inductance coil (5), and be connected with output (2) by diode (6), between output (2) and ground, be parallel with filter capacitor (4) and load (3).

4, as the said DC-DC conversion integrated circuit of claim 2, the source electrode that it is characterized in that P channel power switching tube (10) links to each other with input (1), drain electrode is by diode (6) ground connection, simultaneously through inductance coil (5) and filter capacitor (4) and load (3) ground connection in parallel.

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