WO2015027750A1 - 一种Boost控制器及Boost变换器 - Google Patents

一种Boost控制器及Boost变换器 Download PDF

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Publication number
WO2015027750A1
WO2015027750A1 PCT/CN2014/081302 CN2014081302W WO2015027750A1 WO 2015027750 A1 WO2015027750 A1 WO 2015027750A1 CN 2014081302 W CN2014081302 W CN 2014081302W WO 2015027750 A1 WO2015027750 A1 WO 2015027750A1
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signal
unit
output
voltage
control signal
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PCT/CN2014/081302
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English (en)
French (fr)
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陈松涛
詹昶
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深圳市汇顶科技股份有限公司
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Publication of WO2015027750A1 publication Critical patent/WO2015027750A1/zh

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M3/00Conversion of dc power input into dc power output
    • H02M3/02Conversion of dc power input into dc power output without intermediate conversion into ac
    • H02M3/04Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
    • H02M3/10Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
    • H02M3/145Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
    • H02M3/155Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
    • H02M3/156Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/0003Details of control, feedback or regulation circuits
    • H02M1/0032Control circuits allowing low power mode operation, e.g. in standby mode
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B70/00Technologies for an efficient end-user side electric power management and consumption
    • Y02B70/10Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes

Definitions

  • the invention belongs to the technical field of power sources, and particularly relates to a Boost controller and a Boost converter.
  • Boost converter can realize the conversion from low voltage power supply to high voltage power supply.
  • the converter has the advantages of small size, simple structure and high conversion efficiency, so it has been widely used.
  • the Boost converter consists of two parts: the power stage and the control circuit.
  • the control circuit generally needs to add negative feedback to the Boost converter to form a closed-loop system to improve output accuracy and dynamic response performance. Therefore, the choice and design of the control method is very important for the performance of the switching power supply.
  • the conventional voltage-controlled Boost converter samples the output voltage and implements closed-loop control as a feedback signal. It is a single-loop control system. As shown in FIG. 1, the output voltage vout of the Boost converter is generated by the voltage dividing network formed by the resistors R1 and R2, and then the sampling signal vfb is input to the inverting terminal of the error amplifier, and the difference between the reference voltage vref and the reference voltage vref is passed through the error amplifier. After amplification, the error signal ea is finally generated. When the converter is in steady state, the ea small signal component is proportional to the difference "vref-vfb".
  • the error signal ea is compared with a sawtooth signal to produce a pulse width signal associated with the ea signal level, i.e., the width of the gate drive signal of transistor M is modulated by the level of error signal ea.
  • This feedback mechanism ensures the stability of the converter output voltage vout. It is worth noting that the frequency of the sawtooth signal ramp can be fixed or varied according to the situation, so it corresponds to two control mechanisms, ⁇ or PFM, and even supports switching between PWM and PFM.
  • the control system of the Boost converter is a negative feedback control system
  • the negative feedback circuit requires that the amount of change in the output signal fed back to the input is in phase with the original input signal.
  • the negative feedback becomes positive feedback and the system becomes unstable.
  • the gain and phase change after each component of the noise interference passes through the output filter, the error amplifier, and the drive.
  • the condition that the switching converter operates stably is to avoid oscillation of the circuit, that is, if the additional phase shift is (2 ⁇ +1) ⁇ 180 °, the loop gain is less than 0 dB.
  • the satisfaction of this condition must rely on a well-designed loop compensation circuit.
  • the reactance elements Z 1 and Z2 constitute a compensation link.
  • the determination of the compensation network in practice is more complicated. It is generally completed in two steps: 1) Deriving the transfer function of the control output to the feedback input without the compensation network and drawing the Bode diagram; 2) Determining the type of compensation network and Its parameters, in the end, are verified or corrected by experiments. The above work is complicated and cumbersome. Summary of the invention
  • the purpose of the embodiments of the present invention is to provide a new and simple Boost controller and a Boost converter.
  • the Boost controller dynamically adjusts the modulation type of the loop according to the load variation, and the two modulation modes of pulse width modulation and pulse frequency modulation. Automatic switching between the two, while meeting the corresponding speed requirements of the loop output, while minimizing the overall power consumption level of the converter.
  • a Boost controller includes a first pulse signal generating unit, a first comparing unit, a selecting unit, a soft start unit, a second pulse signal generating unit, a second comparing unit, and a trigger unit.
  • the first pulse signal generating unit outputs a heavy duty lower switching pulse control signal and a light load lower switching pulse control signal to the selection unit according to the internal register setting thereof, and outputs a soft start switch pulse control signal to the soft start unit;
  • the comparing unit controls the selecting unit to selectively output the heavy-duty switching pulse control signal and the light-load lower switching pulse control signal according to the comparison result of the sampling feedback signal of the output voltage and the internal reference voltage;
  • the selecting unit receives the overload of the first signal generating unit output The lower switch pulse control signal and the light load lower switch pulse control signal, and then according to the control signal type outputted by the first comparison unit, corresponding to the output heavy load lower switch pulse control signal or the light load lower switch pulse control signal to the trigger unit;
  • the soft start unit is First signal generation
  • the soft start switch pulse control signal outputted by the unit outputs a soft start control voltage signal to the second comparison unit;
  • the second pulse signal occurs
  • the unit generates a sawtooth wave signal of a preset slope, and then sends
  • the first comparing unit when the amplitude of the sampling feedback signal of the output voltage is greater than the amplitude of the internal reference voltage, the first comparing unit sends the output switching pulse control signal to the selection unit under light load; when the amplitude of the sampling feedback signal of the output voltage When the value is less than the amplitude of the internal reference voltage but greater than the difference between the amplitude of the internal reference voltage minus the preset voltage threshold, the first comparison unit sends an output light switch pulse control signal to the selection unit; when the output voltage is sampled and the feedback signal When the amplitude is less than the difference between the amplitude of the internal reference voltage and the preset voltage threshold, the first comparing unit sends the output switching pulse control signal to the selecting unit under heavy load.
  • the second comparison unit when the amplitude of the sawtooth signal is lower than the soft start control voltage signal, the second comparison unit outputs the pulse signal to a low level, and the reset end signal of the trigger unit is in an inactive state; when the amplitude of the sawtooth signal is higher than When the voltage signal is soft-started, the second comparison unit outputs a pulse signal at a high level, the reset terminal signal of the trigger unit is in an active state, and the output signal of the trigger unit is set to a low level.
  • the soft start unit controls the rising slope of the soft start control voltage signal based on the frequency and duty cycle of the soft start switch pulse control signal.
  • the soft start unit also limits and clamps the maximum amplitude of the soft start control voltage signal.
  • the duty cycle to frequency ratio of the switching pulse control signal under heavy load is greater than the duty cycle to frequency ratio of the switching pulse control signal under light load.
  • the present invention also discloses a Boost converter including a power supply, a Boost controller, a first transistor, a rectifier diode, a first capacitor, a voltage dividing sampling circuit, and an amplitude amplified output of the low voltage signal to the high voltage output signal.
  • the power supply provides power to the Boost controller
  • the input terminal of the Boost controller receives the sampling feedback signal of the output voltage of the Boost converter, and the output end is connected to the base of the first transistor, and the collector and the emitter of the first transistor are connected at the positive and negative ends of the power supply, first
  • the capacitor is connected in parallel with the first transistor, and the rectifier diode is connected between the first capacitor and the collector of the first transistor;
  • the voltage dividing sampling circuit comprises a first resistor and a second resistor connected in series, the first resistor and the second resistor and the first resistor a capacitor is connected in parallel;
  • the output driving circuit is connected in parallel with the voltage dividing sampling circuit, and the output driving circuit comprises a second capacitor, a third resistor, a fourth resistor and a second transistor, wherein one end of the second capacitor is connected to the low voltage signal, and the other end is connected to the second transistor
  • the base is connected, the collector of the second transistor is connected in series with the third resistor and connected to one end
  • a fifth resistor and a third capacitor are connected between the output of the Boost converter and the base of the first transistor, and the third capacitor is connected in parallel with the fifth resistor.
  • a first inductor is further connected between the power source and the first transistor collector.
  • the Boost controller and the Boost converter proposed by the embodiments of the present invention have the following advantages: (1) dynamically adjusting the modulation type of the loop according to the load change condition, and automatically switching between the two modulation modes of pulse width modulation and pulse frequency modulation. It can reduce the overall power consumption level of the converter while satisfying the corresponding speed requirements of the loop output. (2) Adopting a closed-loop structure based on voltage control, but the feedback is loose, no need to introduce loop compensation, simplifying the design The circuit adaptability is enhanced; (3) A unique start-up circuit mechanism is designed to minimize the startup current level and reduce the discharge capacity requirement of the power supply under the premise of taking the startup time. DRAWINGS
  • FIG. 1 is a circuit diagram of a loop structure of a conventional voltage controlled Boost converter
  • FIG. 2 is a circuit diagram of a voltage controlled Boost converter including a compensation network
  • FIG. 3 is a schematic block diagram of a Boost controller according to an embodiment of the present invention
  • FIG. 4 is a circuit diagram of a Boost converter according to an embodiment of the present invention.
  • FIG. 5 is a schematic diagram of an internal structure of a soft start unit according to an embodiment of the present invention.
  • the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
  • FIG. 3 is a Boost controller according to an embodiment of the present invention, including a first pulse signal generating unit, a first comparing unit, a selecting unit, a soft start unit, a second pulse signal generating unit, and a second Comparison unit, trigger unit and buffer unit.
  • the first pulse signal generating unit outputs a reset switch pulse control signal FswHighLoad and a light load switch pulse control signal FswLightLoad to the selection unit according to the internal register setting, and outputs a soft start switch pulse control signal SoftStartCtrl to the soft start unit.
  • a reset switch pulse control signal FswHighLoad and a light load switch pulse control signal FswLightLoad to the selection unit according to the internal register setting
  • a soft start switch pulse control signal SoftStartCtrl to the soft start unit. Only three internal registers register P0, register P1, regi ster DO, and register Dl are shown in FIG. 3, and the specific number depends on actual needs.
  • the switch pulse control signal under heavy load and the switch pulse control signal under light load to the selection unit, and the output soft start switch pulse control signal are all pulse width modulation signals, the difference is only in the difference of frequency and duty ratio,
  • the Boost converter has different working links to achieve effective control of the adjustment loop
  • the first comparing unit controls the selecting unit to selectively output the heavy-duty switching pulse control signal and the light-load lower switching pulse control signal according to the comparison result of the sampling feedback signal FB of the output voltage and the internal reference voltage Vref. Specifically, when the amplitude of the sampling feedback signal of the output voltage is greater than the amplitude of the internal reference voltage, the first comparing unit sends an output light-loading lower switching pulse control signal to the selecting unit. In order to avoid the disturbance caused by the noise, when the amplitude of the sampling feedback signal of the output voltage is smaller than the amplitude of the internal reference voltage but greater than the difference between the amplitude of the internal reference voltage and the preset voltage threshold, the first comparison unit sends the output light.
  • the switch pulse control signal is carried to the selection unit. When the amplitude of the sampling feedback signal of the output voltage is less than the difference between the amplitude of the internal reference voltage minus the preset voltage threshold, the first comparing unit transmits the switching pulse control signal to the selecting unit under the output overload.
  • the selecting unit receives the heavy-duty switching pulse control signal output by the first signal generating unit and The switch pulse control signal is lightly loaded, and then the switch pulse control signal under the heavy load or the switch pulse control signal under the light load is output to the trigger unit according to the type of the control signal output by the first comparison unit.
  • the soft start unit outputs a soft start control voltage signal to the second comparison unit according to the soft start switch pulse control signal output by the first signal generating unit.
  • the input signal of the soft start unit is the soft start switch pulse control signal output by the first pulse signal generating unit, and outputs a monotonically increasing soft start control voltage signal SoftStart.
  • the soft start unit controls the rising slope of the soft start control voltage signal according to the frequency and duty ratio of the soft start switch pulse control signal.
  • the soft start unit also limits and clamps the maximum amplitude of the soft-start control voltage signal.
  • the second pulse signal generating unit generates a sawtooth wave signal of a preset slope and then transmits the signal to the second comparing unit.
  • the second pulse signal generating unit outputs the sawtooth wave oscillating signal ramp, and the capacitor is charged by a fixed current source internally, so the signal slope is fixed, and the charging time is output by the first pulse signal generating unit according to the operating state of the converter.
  • the second comparison unit outputs a pulse signal of a fixed frequency to the trigger unit according to the comparison result of the soft start control voltage signal and the sawtooth wave signal.
  • the selecting unit selects the output switching pulse control signal under light load, and the Boost converter operates at a higher switching frequency, and the driving signal The duty cycle is also large.
  • the output of the first pulse signal generating unit is still a light-loaded switching pulse control signal until the sampling feedback signal of the output voltage continues to fall below the internal reference voltage.
  • the selection unit selects the output switching pulse control signal under heavy load. This process will continue to maintain the stability of the Boost converter output voltage signal.
  • the setting end S of the trigger unit receives the heavy-duty switching pulse control signal or the light-loading lower-switching pulse control signal outputted from the selection unit to the trigger unit, and the reset terminal R receives the fixed-frequency pulse signal output by the second comparison unit.
  • the output signal is sent to the buffer unit.
  • the buffer unit is used to amplify the signal output by the trigger unit and then output.
  • the trigger unit is a typical RS flip-flop
  • the input signal of the set terminal is the output signal of the selection unit
  • the input signal of the reset terminal is the output of the second comparison unit.
  • the working logic of the trigger unit is:
  • the present invention also discloses a Boost converter including a power BAT, a Boost controller, a first transistor Q1, a rectifier diode D, a first capacitor C1, a voltage dividing sampling circuit, and a low voltage signal to a high voltage output.
  • An output drive circuit that amplifies the amplitude of the signal.
  • the power supply BAT provides power supply for the Boost controller
  • the input of the Boost controller receives the sampling feedback signal FB of the output voltage of the Boost converter
  • the output terminal is connected to the base of the first transistor Q1
  • the collector of the first transistor Q1 is
  • the emitter is connected between the positive and negative terminals of the power source BAT
  • the first capacitor C1 is connected in parallel with the first transistor Q1
  • the rectifier diode D is connected between the first capacitor C1 and the collector of the first transistor Q1
  • the first resistor R1 and the second resistor R2 are connected in series, and the first resistor R1 and the second resistor R2 are connected in parallel with the first capacitor C1.
  • the output driving circuit is connected in parallel with the voltage dividing sampling circuit.
  • the output driving circuit comprises a second capacitor C2, a third resistor R3, a fourth resistor R4 and a second transistor Q2.
  • One end of the second capacitor C2 is connected to the low voltage signal, and the other end is connected to the second
  • the base of the transistor Q2 is connected, the collector of the second transistor Q2 is connected in series with the third resistor R3 and connected to one end of the voltage dividing sampling circuit, and the emitter of the second transistor Q2 is connected to the other end of the voltage dividing sampling circuit, the fourth resistor R4 is connected between the base and the collector of the second transistor Q2.
  • the Boost controller adjusts the frequency and duty cycle of the output drive signal DRV by monitoring the sampled feedback signal FB of the output voltage VOUT, thereby finally causing the output voltage VOUT to be in a stable state.
  • a fifth resistor R5 and a third capacitor C3 are connected between the output end of the Boost controller and the base of the first transistor Q1, and the third capacitor C3 is connected in parallel with the fifth resistor R5.
  • the Boost controller will generate the maximum duty cycle switch driving signal DRV to make The loop output rises to a preset value.
  • the power supply BAT is a lithium-ion battery or a lithium-capacitor battery, its power supply capability is limited. Excessive output current will significantly reduce its service life, and will cause a large terminal voltage change, thereby deteriorating the variator output voltage. stability. Therefore, a soft start control mechanism must be added during this process so that the duty cycle of the switch drive signal DRV changes slowly and cannot exceed an upper limit to avoid excessive peak value of the inductor current.
  • FIG. 5 discloses an implementation structure of the soft start function of the embodiment of the present invention.
  • ICHG1 and ICHG2 are preset bias current sources that provide a constant charge current for capacitor Csoftstart and capacitor Cramp.
  • the switch S1 is periodically turned on and off under the control of the signal SoftStartCtrl, and controls the speed at which the current source ICHG1 charges the capacitor Csoftstart, thereby controlling the rising speed of the node voltage SoftStart.
  • the MUX output switches between the signals FSWHighLoad and FSWLightLoad, producing an output signal FswRamp.
  • the switch S2 is periodically turned on and off under the control of the signal FswRamp, and controls the time during which the current source ICHG2 charges the capacitor Cramp, thereby realizing the control of the rising height of the node voltage RAMP.
  • the controller can dynamically switch the switching frequency between FswHighLoad and FswLightLoad according to the output voltage level, thereby switching from PWM modulation mode to fixed conduction. Time Ton's PFM mode.
  • the controller achieves a smaller starting current and a reasonable starting time.
  • the controller in this scheme outputs a higher frequency signal FswRamp; once the output in Figure 4
  • the controller will automatically reduce the operating frequency of the FswRamp.
  • the converter is in no-load state, even if the lower switching drive signal frequency is enough to achieve a stable voltage output; but once the load is increased at this time, the output voltage VOUT may not continue to be maintained, and the sampling voltage FB will follow. The decline.
  • the controller when the FB drops to a level below lv, the controller automatically raises the operating frequency of the signal FswRamp to quickly stabilize the output voltage VOUT.
  • the output voltage ripple of the boost converter of the present invention may be larger, but the advantages are also very obvious.
  • the boost converter of the present invention is simpler, more robust, and Lower consumption.
  • the Boost controller and the Boost converter proposed by the embodiments of the present invention have the following advantages: (1) dynamically adjusting the modulation type of the loop according to the load change condition, and automatically switching between the two modulation modes of pulse width modulation and pulse frequency modulation. It can reduce the overall power consumption level of the converter while satisfying the corresponding speed requirements of the loop output. (2) Adopting a closed-loop structure based on voltage control, but the feedback is loose, no need to introduce loop compensation, simplifying the design The circuit adaptability is enhanced; (3) A unique start-up circuit mechanism is designed to minimize the startup current level and reduce the discharge capacity requirement of the power supply under the premise of taking the startup time.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Dc-Dc Converters (AREA)

Abstract

本发明提供了一种Boost控制器和Boost变换器,属于电源技术领域。其中,Boost控制器包括第一脉冲信号发生单元、第一比较单元、选择单元、软启动单元、第二脉冲信号发生单元、第二比较单元、触发单元和缓冲单元,Boost 控制器根据负载变化情况动态调整环路的调制类型,在脉冲宽度调制和脉冲频率调制这两种调制方式间自动切换;Boost变换器包括Boost控制器、第一晶体管、整流二极管、第一电容、分压采样电路以及完成低压信号到高压输出信号的幅度放大的输出驱动电路,采用本发明,在满足环路输出相应速度要求的同时最大程度降低了变换器整体的功耗水平。

Description

一种 Boost控制器及 Boost变换器 技术领域
本发明属于电源技术领域, 具体涉及一种 Boost控制器及 Boost变换器。
Boost变换器作为基本的 DC/DC变换器之一, 能够实现从低电压电源变换 到高电压电源, 该变换器具有体积小、 结构简单、 变换效率高等优点, 因而得 到广泛的应用。 Boost变换器由开关器件构成的功率级和控制电路两部分组成, 控制电路一般需要在 Boost变换器上增加负反馈构成闭环系统以提高输出精度 和动态响应性能。 所以, 控制方法的选择和设计实现对开关电源的性能十分重 要。
传统的电压控制型 Boost变换器对输出电压进行采样, 并作为反馈信号实 现闭环控制,是一种单环控制系统。如图 1所示, Boost变换器的输出电压 vout 经由电阻 R1和 R2构成的分压网络后生成采样信号 vfb输入到误差放大器的反 相端, 其与参考电压 vref 之间的差值经误差放大器放大后最终产生误差信号 ea, 在变换器处于稳态时, ea小信号分量与差值 " vref-vfb "成正比。 误差信 号 ea和一个锯齿波信号比较后产生与 ea信号电平相关的脉冲宽度信号, 即晶 体管 M的栅极驱动信号的宽度受误差信号 ea的电平调制。该反馈机制保证了变 换器输出电压 vout的稳定。值得注意的是,锯齿波信号 ramp的频率可以固定, 也可以根据情况是变动的, 那么就分别对应着 Ρ^ί或 PFM两种控制机制, 甚至 可以是同时支持在 PWM和 PFM间切换。
从图 1可知, Boost变换器的控制系统是一个负反馈控制系统, 而负反馈 电路要求反馈到输入端的输出信号变化量与原输入信号同相。 但由于开关延迟 和电路中电抗性元件的存在, 不可避免的引入了随频率变化的附加相移, 当这 一相移增大到 180 ° 且此时系统的增益大于 1时负反馈就变成了正反馈, 系统 将变得不稳定。 此外, 噪声干扰下的各分量经过输出滤波器、 误差放大器和驱 动产生等各环节后, 增益和相位都会发生变化。 所以, 开关变换器稳定工作的 条件就是避免电路出现振荡, 即在附加相移为(2η+1 ) Χ 180 ° 的情况下, 满足 环路增益小于 0dB。这一条件的满足必须依赖精心设计的环路补偿电路。如图 2 所示,电抗元件 Z 1和 Z2构成补偿环节。实际中补偿网络的确定是比较复杂的, 一般分两个歩骤完成: 1 )推导出不含补偿网络情况下控制输出到反馈输入的传 递函数并画出 Bode图; 2 ) 确定补偿网络类型及其参数, 最终, 由实验来验证 或者修正该参数。 上述工作复杂繁琐。 发明内容
本发明实施例的目的在于提供一种全新而简洁的 Boost控制器和 Boost变 换器, Boost 控制器根据负载变化情况动态调整环路的调制类型, 在脉冲宽度 调制和脉冲频率调制这两种调制方式间自动切换, 在满足环路输出相应速度要 求的同时最大程度降低了变换器整体的功耗水平。
本发明实施例是这样实现的, 一种 Boost控制器, 包括第一脉冲信号发生 单元、 第一比较单元、 选择单元、 软启动单元、 第二脉冲信号发生单元、 第二 比较单元、 触发单元和缓冲单元, 其中第一脉冲信号发生单元根据自身内部寄 存器设置输出重载下开关脉冲控制信号和轻载下开关脉冲控制信号给选择单元, 以及输出软启动开关脉冲控制信号至软启动单元; 第一比较单元根据输出电压 的采样反馈信号和内部参考电压的比较结果控制选择单元选择性输出重载下开 关脉冲控制信号和轻载下开关脉冲控制信号; 选择单元接收第一信号产生单元 输出的重载下开关脉冲控制信号和轻载下开关脉冲控制信号, 然后根据第一比 较单元输出的控制信号类型对应输出重载下开关脉冲控制信号或者轻载下开关 脉冲控制信号给触发单元; 软启动单元根据第一信号产生单元输出的软启动开 关脉冲控制信号输出软启动控制电压信号给第二比较单元; 第二脉冲信号发生 单元产生预设斜率的锯齿波信号, 然后发送给第二比较单元; 第二比较单元根 据软启动控制电压信号和锯齿波信号的大小比较结果, 输出固定频率的脉冲信 号给触发单元; 触发单元, 其置位端接收选择单元输出的重载下开关脉冲控制 信号或者轻载下开关脉冲控制信号给触发单元, 其复位端接收第二比较单元输 出的固定频率的脉冲信号, 输出信号给缓冲单元; 缓冲单元用于放大触发单元 输出的信号然后输出。
一实施例中, 当输出电压的采样反馈信号的幅值大于内部参考电压的幅值 时, 第一比较单元发送输出轻载下开关脉冲控制信号给选择单元; 当输出电压 的采样反馈信号的幅值小于内部参考电压的幅值但是大于内部参考电压的幅值 减去预设电压阈值之差时, 第一比较单元发送输出轻载下开关脉冲控制信号给 选择单元; 当输出电压的采样反馈信号的幅值小于内部参考电压的幅值减去预 设电压阈值之差时, 第一比较单元发送输出重载下开关脉冲控制信号给选择单 元。
一实施例中, 当锯齿波信号的幅度低于软启动控制电压信号时, 第二比较 单元输出脉冲信号为低电平, 触发单元的复位端信号处于无效状态; 当锯齿波 信号的幅度高于软启动控制电压信号时,第二比较单元输出脉冲信号为高电平, 触发单元的复位端信号处于有效状态, 触发单元的输出信号置为低电平。
一实施例中, 软启动单元根据软启动开关脉冲控制信号的频率和占空比控 制软启动控制电压信号的上升斜率。
一实施例中, 软启动单元还对软启动控制电压信号的幅度最大值进行限制 和钳位。
一实施例中, 重载下开关脉冲控制信号的占空比与频率的比值大于轻载下 开关脉冲控制信号的占空比与频率的比值。
另一方面,本发明还公开了一种 Boost变换器,包括电源、 Boost控制器、 第一晶体管、 整流二极管、 第一电容、 分压采样电路以及完成低压信号到高压 输出信号的幅度放大的输出驱动电路, 其中, 电源为 Boost控制器提供电能电 源, Boost控制器输入端接收 Boost变换器的输出电压的采样反馈信号, 输出 端与第一晶体管的基极连接, 第一晶体管的集电极和发射极连接在电源正负极 两端, 第一电容与第一晶体管并联,整流二极管连接在第一电容与第一晶体管 的集电极之间; 分压采样电路包括之间串联的第一电阻和第二电阻, 第一电阻 和第二电阻与第一电容并联; 输出驱动电路与分压采样电路并联, 输出驱动电 路包括第二电容、 第三电阻、 第四电阻以及第二晶体管, 第二电容的一端接低 压信号, 另一端与第二晶体管的基极连接, 第二晶体管的集电极与第三电阻串 联后连接在分压采样电路的一端, 第二晶体管的发射极与分压采样电路的另一 端连接, 第四电阻连接在第二晶体管的基极和集电极之间。
一实施例中, Boost 变换器的输出端和第一晶体管的基极之间还连接有第 五电阻和第三电容, 第三电容与第五电阻并联。
一实施例中, 电源和第一晶体管集电极之间还连接有第一电感。
本发明实施例提出的 Boost控制器及 Boost变换器, 具有以下优点: (1 ) 根据负载变化情况动态调整环路的调制类型, 在脉冲宽度调制和脉冲频率调制 这两种调制方式间自动切换, 在满足环路输出相应速度要求的同时最大程度降 低了变换器整体的功耗水平; (2 ) 采用基于电压控制型的闭环结构, 但反馈较 为松散, 不需要引入环路补偿, 简化设计的同时增强了电路的适应能力; (3 ) 设计了独特的启动电路机制, 在兼顾启动时间的前提下最大程度降低启动电流 水平, 减小了供电电源的放电能力要求。 附图说明
图 1是现有的一种电压控制型 Boost变换器环路结构电路图;
图 2为现有的一种含有补偿网络的电压控制型 Boost变换器电路图; 图 3为本发明实施例提供的一种 Boost控制器内部原理框图;
图 4为本发明实施例提供的一种 Boost变换器电路图;
图 5为本发明实施例提供的一种软启动单元内部原理图。 为了使本发明的目的、 技术方案及优点更加清楚明白, 以下结合附图及实 施例, 对本发明进行进一歩详细说明。 应当理解, 此处所描述的具体实施例仅 仅用以解释本发明, 并不用于限定本发明。
如图 3所示, 图 3是本发明实施例公开的一种 Boost控制器, 包括第一脉 冲信号发生单元、 第一比较单元、 选择单元、 软启动单元、 第二脉冲信号发生 单元、 第二比较单元、 触发单元和缓冲单元。
其中, 第一脉冲信号发生单元根据自身内部寄存器设置输出重载下开关脉 冲控制信号 FswHighLoad和轻载下开关脉冲控制信号 FswLightLoad给选择单元, 以及输出软启动开关脉冲控制信号 SoftStartCtrl至软启动单元。 图 3中仅仅 示出四个内部寄存器 register P0、 register Pl、 regi ster DO禾口 register Dl, 具体数量根据实际需求而定。 重载下开关脉冲控制信号和轻载下开关脉冲控制 信号给选择单元, 以及输出软启动开关脉冲控制信号三个信号都是脉宽调制信 号, 差别只在于其频率和占空比不同, 应用于 Boost变换器不同工作环节以实 现对调整环路的有效控制。 一实施例中, 重载下开关脉冲控制信号的占空比与 频率的比值大于轻载下开关脉冲控制信号的占空比与频率的比值。
其中,第一比较单元根据输出电压的采样反馈信号 FB和内部参考电压 Vref 的比较结果控制选择单元选择性输出重载下开关脉冲控制信号和轻载下开关脉 冲控制信号。 具体地, 当输出电压的采样反馈信号的幅值大于内部参考电压的 幅值时, 第一比较单元发送输出轻载下开关脉冲控制信号给选择单元。 为了避 免噪声带来的扰动, 当输出电压的采样反馈信号的幅值小于内部参考电压的幅 值但是大于内部参考电压的幅值减去预设电压阈值之差时, 第一比较单元发送 输出轻载下开关脉冲控制信号给选择单元。 当输出电压的采样反馈信号的幅值 小于内部参考电压的幅值减去预设电压阈值之差时, 第一比较单元发送输出重 载下开关脉冲控制信号给选择单元。
其中, 选择单元接收第一信号产生单元输出的重载下开关脉冲控制信号和 轻载下开关脉冲控制信号, 然后根据第一比较单元输出的控制信号类型对应输 出重载下开关脉冲控制信号或者轻载下开关脉冲控制信号给触发单元。
其中, 软启动单元根据第一信号产生单元输出的软启动开关脉冲控制信号 输出软启动控制电压信号给第二比较单元。 软启动单元的输入信号为第一脉冲 信号发生单元输出的软启动开关脉冲控制信号, 输出一个单调增加的软启动控 制电压信号 SoftStart。 软启动单元根据软启动开关脉冲控制信号的频率和占 空比控制软启动控制电压信号的上升斜率。 软启动单元还对软启动控制电压信 号的幅度最大值进行限制和钳位。
其中, 第二脉冲信号发生单元产生预设斜率的锯齿波信号, 然后发送给第 二比较单元。 第二脉冲信号发生单元输出锯齿波振荡信号 ramp , 由内部一个固 定大小的电流源对电容充电, 所以其信号斜率固定, 而充电时间则根据变换器 工作状态由第一脉冲信号发生单元输出的重载下开关脉冲控制信号或轻载下开 关脉冲控制信号控制。
其中, 第二比较单元根据软启动控制电压信号和锯齿波信号的大小比较结 果, 输出固定频率的脉冲信号给触发单元。 具体而言, 当输出电压的采样反馈 信号的幅值大于内部参考电压时,选择单元选择输出轻载下开关脉冲控制信号, 此时 Boost变换器工作在较高的开关频率下, 且驱动信号的占空比也较大。 当 输出电压的采样反馈信号的幅值下降小于内部参考电压时, 第一脉冲信号发生 单元的输出仍为轻载下开关脉冲控制信号, 直到输出电压的采样反馈信号继续 下降到小于内部参考电压之下预设电压阈值的水平时, 选择单元则选择输出重 载下开关脉冲控制信号。 这一过程将一直持续下去以便维持 Boost变换器输出 电压信号的稳定。
其中, 触发单元的置位端 S接收选择单元输出的重载下开关脉冲控制信号 或者轻载下开关脉冲控制信号给触发单元, 其复位端 R接收第二比较单元输出 的固定频率的脉冲信号, 输出信号给缓冲单元。 缓冲单元用于放大触发单元输 出的信号然后输出。一实施例中,优选地,触发单元是一个典型的 R-S触发器, 其置位端输入信号为选择单元的输出信号, 而复位端的输入信号为第二比较单 元的输出。 触发单元的工作逻辑为:
Figure imgf000009_0001
如图 4所示, 本发明还公开了一种 Boost变换器, 包括电源 BAT、 Boost 控制器、 第一晶体管 Ql、 整流二极管 D、 第一电容 Cl、 分压采样电路以及完成 低压信号到高压输出信号的幅度放大的输出驱动电路。其中,电源 BAT为 Boost 控制器提供电能电源, Boost控制器输入端接收 Boost变换器的输出电压的采 样反馈信号 FB, 输出端与第一晶体管 Q1的基极连接, 第一晶体管 Q1的集电极 和发射极连接在电源 BAT正、 负极两端, 第一电容 C1与第一晶体管 Q1并联, 整流二极管 D连接在第一电容 C1与第一晶体管 Q1的集电极之间; 分压采样电 路包括之间串联的第一电阻 R1和第二电阻 R2, 第一电阻 R1和第二电阻 R2与 第一电容 C1并联。
输出驱动电路与分压采样电路并联, 输出驱动电路包括第二电容 C2、 第三 电阻 R3、第四电阻 R4以及第二晶体管 Q2, 第二电容 C2的一端接低压信号, 另 一端接与第二晶体管 Q2 的基极连接, 第二晶体管 Q2 的集电极与第三电阻 R3 串联后连接在分压采样电路的一端,第二晶体管 Q2的发射极与分压采样电路的 另一端连接, 第四电阻 R4连接在第二晶体管 Q2的基极和集电极之间。
Boost控制器通过对输出电压 V0UT的采样反馈信号 FB进行监控, 调整输出驱 动信号 DRV的频率和占空比,从而最终使得输出电压 V0UT处于稳定状态。优选 地, Boost控制器的输出端和第一晶体管 Q1 的基极之间还连接有第五电阻 R5 和第三电容 C3, 第三电容 C3与第五电阻 R5并联。 在整个 Boost变换器启动阶段, 由于第一电容 C1电压为零,所以输出采样 反馈信号 FB也为零,如无特殊处理的话 Boost控制器将产生最大占空比的开关 驱动信号 DRV, 以尽快使环路输出升高到预设值。 通常情况下, 由于电源 BAT 为锂离子电池或者锂电容电池, 其供电能力有限, 输出过大的电流会显著降低 其使用寿命, 并且会造成较大的端电压变化, 从而恶化变化器输出电压的稳定 性。 所以, 在此过程中必须加入软启动控制机制, 使得开关驱动信号 DRV的占 空比缓慢变化, 并且不能超过某个上限, 以免产生过大的电感电流峰值。
如图 5所示, 图 5公开了本发明实施例软启动功能的一种实现结构。 ICHG1 和 ICHG2是预设的偏置电流源,为电容 Csoftstart和电容 Cramp提供恒定的充 电电流。开关 S1在信号 SoftStartCtrl的控制下周期性的导通和断开,控制电 流源 ICHG1对电容 Csoftstart充电的速度, 从而实现对节点电压 SoftStart 上升速度的控制。 根据输出电压的电平和负载情况, MUX 输出在信号 FSWHighLoad和 FSWLightLoad之间切换,产生输出信号 FswRamp。开关 S2在信 号 FswRamp的控制下周期性的导通和断开, 控制电流源 ICHG2对电容 Cramp充 电的时间, 从而实现对节点电压 RAMP上升高度的控制。
显然, 在节点电压 SoftStart上升到模块 Voltage Clamp设定的钳位电平 Vset之前, 比较器输出信号 DRV_RESET的占空比将跟随节点电压 SoftStart的 上升而逐歩减小; 因为 DRV_RESET是图 4中 RS触发器 RS-FF的复位信号,所以 可知, 在节点电压 SoftStart上升到模块 Voltage Clamp设定的钳位电平 Vset 之前, 控制器输出的驱动信号 DRV的占空比将随节点电压 SoftStart的上升而 逐歩增大。 这就避免了启动阶段过大的开关占空比所导致的电感尖峰电流, 也 消除了启动时电源 BAT放电能力不够带来的瓶颈。
当节点电压 SoftStart上升到模块 Voltage Clamp设定的钳位电平 Vset 之后, DRV_RESET的占空比不再减小, 所以控制器输出的驱动信号 DRV的占空 比也不再增大。 但此时控制器可以根据输出电压的高低来动态实现开关频率在 FswHighLoad和 FswLightLoad之间切换, 从而从 PWM调制模式转换到固定导通 时间 Ton的 PFM模式。
一般说来, 在 Boost变换器启动阶段为同时兼顾实现较小的启动电流和较 合理的启动时间, 此阶段时本方案中的控制器会输出较高频率的信号 FswRamp; 一旦图 4中的输出电压采样信号 FB升高到 lv, 控制器就会自动降低 FswRamp 的工作频率。 此时如果变换器处于空载状态, 那么即使较低的开关驱动信号频 率也足以实现稳定的电压输出;但一旦此时负载加重,那么输出电压 V0UT很可 能无法继续维持, 采样电压 FB也会随之下降。 根据图 4, 当 FB下降到 lv下某 个电平时, 控制器会自动提升信号 FswRamp的工作频率, 以便快速实现输出电 压 V0UT的稳定。 相比于传统的电压控制型闭环变换器控制系统, 本发明 Boost 变换器的输出电压纹波可能会更大, 但优点也是非常明显的, 本发明 Boost变 换器更简单、 更鲁棒, 并且功耗更低。
本领域普通技术人员可以理解实现上述实施例方法中的全部或部分歩骤是 可以通过程序来控制相关的硬件完成, 程序可以在存储于一计算机可读取存储 介质中的存储介质, 如 R0M/RAM、 磁盘、 光盘等。
以上所述仅为本发明的较佳实施例而已, 并不用以限制本发明, 凡在本发 明的精神和原则之内所作的任何修改、 等同替换和改进等, 均应包含在本发明 的保护范围之内。 工业实用性
本发明实施例提出的 Boost控制器及 Boost变换器, 具有以下优点: (1 ) 根据负载变化情况动态调整环路的调制类型, 在脉冲宽度调制和脉冲频率调制 这两种调制方式间自动切换, 在满足环路输出相应速度要求的同时最大程度降 低了变换器整体的功耗水平; (2 ) 采用基于电压控制型的闭环结构, 但反馈较 为松散, 不需要引入环路补偿, 简化设计的同时增强了电路的适应能力; (3 ) 设计了独特的启动电路机制, 在兼顾启动时间的前提下最大程度降低启动电流 水平, 减小了供电电源的放电能力要求。

Claims

权 利 要 求 书
1、 一种 Boost控制器, 包括第一脉冲信号发生单元、 第一比较单元、 选择 单元、 软启动单元、 第二脉冲信号发生单元、 第二比较单元、 触发单元和缓冲 单元, 其中:
所述第一脉冲信号发生单元, 根据自身内部寄存器设置输出重载下开关脉 冲控制信号和轻载下开关脉冲控制信号给选择单元, 以及输出软启动开关脉冲 控制信号至所述软启动单元;
所述第一比较单元, 根据输出电压的采样反馈信号和内部参考电压的比较 结果控制选择单元选择性输出重载下开关脉冲控制信号和轻载下开关脉冲控制 信号;
所述选择单元, 接收所述第一信号产生单元输出的重载下开关脉冲控制信 号和轻载下开关脉冲控制信号, 然后根据所述第一比较单元输出的控制信号类 型对应输出重载下开关脉冲控制信号或者轻载下开关脉冲控制信号给所述触发 单元;
所述软启动单元, 根据第一信号产生单元输出的软启动开关脉冲控制信号 输出软启动控制电压信号给所述第二比较单元;
所述第二脉冲信号发生单元, 产生预设斜率的锯齿波信号, 然后发送给所 述第二比较单元;
所述第二比较单元, 根据所述软启动控制电压信号和所述锯齿波信号的大 小比较结果, 输出固定频率的脉冲信号给所述触发单元;
所述触发单元, 其置位端接收选择单元输出的重载下开关脉冲控制信号或 者轻载下开关脉冲控制信号给触发单元, 其复位端接收第二比较单元输出的固 定频率的脉冲信号, 输出信号给所述缓冲单元;
所述缓冲单元, 用于放大所述触发单元输出的信号然后输出。
2、根据权利要求 1所述的 Boost控制器, 其中, 所述第一比较单元具体用 于: 当 Boost变换器输出电压的采样反馈信号的幅值大于内部参考电压的幅值 时, 发送输出轻载下开关脉冲控制信号给所述选择单元; 当输出电压的采样反 馈信号的幅值小于内部参考电压的幅值但是大于内部参考电压的幅值减去预设 电压阈值之差时, 发送输出轻载下开关脉冲控制信号给所述选择单元; 当输出 电压的采样反馈信号的幅值小于内部参考电压的幅值减去预设电压阈值之差时, 发送输出重载下开关脉冲控制信号给所述选择单元。
3、根据权利要求 1所述的 Boost控制器, 其中, 所述第二比较单元具体用 于: 当所述锯齿波信号的幅度低于所述软启动控制电压信号时, 输出脉冲信号 为低电平, 使得所述触发单元的复位端信号处于无效状态; 当所述锯齿波信号 的幅度高于所述软启动控制电压信号时, 输出脉冲信号为高电平, 使得所述触 发单元的复位端信号处于有效状态, 触发单元的输出信号置为低电平。
4、根据权利要求 1所述的 Boost控制器, 其中, 所述软启动单元根据软启 动开关脉冲控制信号的频率和占空比控制所述软启动控制电压信号的上升斜率。
5、根据权利要求 4所述的 Boost控制器, 其中, 所述软启动单元还对软启 动控制电压信号的幅度最大值进行限制和钳位。
6、根据权利要求 1-5任一项所述的 Boost控制器, 其中, 所述重载下开关 脉冲控制信号的占空比与频率的比值大于所述轻载下开关脉冲控制信号的占空 比与频率的比值。
7、 一种 Boost变换器, 其中, 包括电源、 Boost控制器、 第一晶体管、 整 流二极管、 第一电容、 分压采样电路以及完成低压信号到高压输出信号的幅度 放大的输出驱动电路, 其中:
所述电源为 Boost控制器提供电能电源, Boost控制器输入端接收 Boost 变换器的输出电压的采样反馈信号, 输出端与所述第一晶体管的基极连接, 所 述第一晶体管的集电极和发射极连接在所述电源正负极两端, 所述第一电容与 所述第一晶体管并联, 所述整流二极管连接在所述第一电容与所述第一晶体管 的集电极之间; 所述分压采样电路包括之间串联的第一电阻和第二电阻, 所述 第一电阻和第二电阻与所述第一电容并联; 所述输出驱动电路与所述分压采样 电路并联, 所述输出驱动电路包括第二电容、 第三电阻、 第四电阻以及第二晶 体管,所述第二电容的一端接低压信号,另一端与所述第二晶体管的基极连接, 所述第二晶体管的集电极与所述第三电阻串联后连接在所述分压采样电路的一 端, 所述第二晶体管的发射极与所述分压采样电路的另一端连接, 所述第四电 阻连接在所述第二晶体管的基极和集电极之间。
8、根据权利要求 7所述的 Boost变换器, 其中, 所述 Boost变换器的输出 端和所述第一晶体管的基极之间还连接有第五电阻和第三电容, 所述第三电容 与所述第五电阻并联。
9、根据权利要求 7所述的 Boost变换器, 其中, 所述电源和所述第一晶体 管集电极之间还连接有第一电感。
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