TWI505611B - Controller, power converter for controlling transformer, and load driving circuit thereof - Google Patents

Controller, power converter for controlling transformer, and load driving circuit thereof Download PDF

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TWI505611B
TWI505611B TW101141638A TW101141638A TWI505611B TW I505611 B TWI505611 B TW I505611B TW 101141638 A TW101141638 A TW 101141638A TW 101141638 A TW101141638 A TW 101141638A TW I505611 B TWI505611 B TW I505611B
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phase
voltage
current
controller
transformer
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TW101141638A
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TW201336213A (en
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Zhimou Ren
Ching Chuan Kuo
Jianlong Gao
Xinmin Yi
Yunning Xie
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O2Micro Int Ltd
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控制變壓器之控制器、電源轉換器及其負載驅動電路Controller for controlling transformer, power converter and load driving circuit thereof

本發明係關於一種控制器,特別是關於一種控制變壓器的控制器以及其電源轉換器及負載驅動電路。The present invention relates to a controller, and more particularly to a controller for controlling a transformer and its power converter and load drive circuit.

反馳式(flyback)轉換器是一種開關模式穩壓電源,可以應用於如交流/直流適配器或電池充電器。圖1所示為一種習知的反馳式轉換器100。該反馳式轉換器100利用控制器120控制一個變壓器。該變壓器包含與直流電源VBB 耦接的初級繞組104、與負載112耦接的次級繞組106以及輔助繞組108。控制器120控制與初級繞組104串聯耦接的開關118。當開關118導通,電流流經初級繞組104,變壓器的磁芯124儲能。當開關118關斷,與次級繞組耦接的二極體110正向偏置,磁芯124中儲存的能量透過次級繞組106釋放至電容122和負載112。誤差放大器114將流經電流監測電阻111的電流和一個參考電流進行比較並產生回授信號FB。回授信號FB透過光耦合器116傳送至控制器120。控制器120根據回授信號FB控制開關118以調整變壓器的輸出電力。該習知反馳式轉換器100的缺點在於其尺寸相對較大。The flyback converter is a switch mode regulated power supply that can be used in applications such as AC/DC adapters or battery chargers. A conventional flyback converter 100 is shown in FIG. The flyback converter 100 controls a transformer using the controller 120. The transformer includes a primary winding 104 coupled to a DC power source V BB , a secondary winding 106 coupled to the load 112 , and an auxiliary winding 108 . Controller 120 controls switch 118 coupled in series with primary winding 104. When the switch 118 is turned on, current flows through the primary winding 104, and the magnetic core 124 of the transformer stores energy. When the switch 118 is turned off, the diode 110 coupled to the secondary winding is forward biased, and the energy stored in the core 124 is discharged through the secondary winding 106 to the capacitor 122 and the load 112. The error amplifier 114 compares the current flowing through the current monitoring resistor 111 with a reference current and generates a feedback signal FB. The feedback signal FB is transmitted to the controller 120 through the optical coupler 116. The controller 120 controls the switch 118 to adjust the output power of the transformer based on the feedback signal FB. A disadvantage of the conventional flyback converter 100 is that it is relatively large in size.

本發明的目的為提供一種負載驅動電路,包括:一變壓器,包括接收一輸入電壓的一初級繞組和連接於一負載 的一次級繞組,該變壓器工作於多個週期,其中,該多個週期中的一個週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流經該初級繞組的一電流增大,在該放電階段,該變壓器放電以對該負載供電,且流過該次級繞組的一電流減小;以及一控制器,耦接至該變壓器,包括一埠,其中,在該充電階段,該埠接收指示該輸入電壓的一第一回授信號,且其中,在該放電階段,該埠接收指示該次級繞組之一電能狀態的一第二回授信號,其中,該控制器根據該第一回授信號產生一第一控制信號,以調節該輸入電壓,且根據該第二回授信號產生一第二控制信號,以調節流經該負載的一電流。It is an object of the present invention to provide a load drive circuit comprising: a transformer comprising a primary winding receiving an input voltage and being coupled to a load a primary winding, the transformer operates in a plurality of cycles, wherein one of the plurality of cycles includes a charging phase and a discharging phase, wherein the transformer is powered by the input voltage and flows through the primary An electric current of the winding is increased, in which the transformer discharges to supply power to the load, and a current flowing through the secondary winding is reduced; and a controller coupled to the transformer, including a turn, wherein Receiving, in the charging phase, a first feedback signal indicating the input voltage, and wherein, in the discharging phase, the chirp receives a second feedback signal indicating a power state of one of the secondary windings, wherein The controller generates a first control signal according to the first feedback signal to adjust the input voltage, and generates a second control signal according to the second feedback signal to adjust a current flowing through the load.

本發明還提供一種電源轉換器,包括:一變壓器,包括接收一輸入電壓的一初級繞組、連接至一負載的一次級繞組,以及一輔助繞組,該變壓器工作於多個週期,其中,該多個週期中的一週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流過該初級繞組的該電流增大,且在該放電階段,該變壓器放電以對該負載供電,且流過該次級繞組的該電流減小;一對相互串聯的電阻,且該對電阻連接至該輔助繞組;以及一控制器,包括一埠,該埠連接於該對電阻之間的一共同節點,在該充電階段,該控制器將該共同節點上的一電壓鉗位在一預設電壓值。The invention also provides a power converter comprising: a transformer comprising a primary winding receiving an input voltage, a primary winding connected to a load, and an auxiliary winding, the transformer operating in a plurality of cycles, wherein the plurality One cycle of the cycle includes a charging phase and a discharging phase, in which the transformer is powered by the input voltage, and the current flowing through the primary winding increases, and in the discharging phase, the transformer discharges Powering the load, and the current flowing through the secondary winding is reduced; a pair of resistors connected in series with each other, and the pair of resistors are coupled to the auxiliary winding; and a controller including a turn connected to the pair A common node between the resistors, the controller clamps a voltage on the common node to a predetermined voltage value during the charging phase.

本發明還提供一種控制器,控制為一負載供電之一變壓器,包括:一第一埠,產生一第一控制信號,以調節該變壓器的一輸入電壓;一第二埠,產生一第二控制信號, 以調節流經該負載的一電流,並使該變壓器工作於多個週期,其中,該多個週期中的一個週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流經該初級繞組的一電流增大;在該放電階段,該變壓器放電以對該負載供電,且流經該次級繞組的一電流減小;以及一第三埠,耦接至該變壓器的一輔助繞組,在該充電階段,該第三埠接收指示該輸入電壓的一第一回授信號;在該放電階段,該第三埠接收指示該次級繞組的一電能狀態的一第二回授信號;其中,該控制器根據該第一回授信號產生該第一控制信號,根據該第二回授信號產生該第二控制信號。The invention also provides a controller for controlling a transformer to supply a load, comprising: a first turn generating a first control signal to adjust an input voltage of the transformer; and a second turn generating a second control signal, Adjusting a current flowing through the load and operating the transformer in a plurality of cycles, wherein one of the plurality of cycles includes a charging phase and a discharging phase, wherein the transformer is subjected to the input voltage Powering, and a current flowing through the primary winding increases; during the discharging phase, the transformer discharges to power the load, and a current flowing through the secondary winding decreases; and a third turn is coupled to An auxiliary winding of the transformer, in the charging phase, the third receiving a first feedback signal indicating the input voltage; and in the discharging phase, the third receiving receives a state indicating a power state of the secondary winding a second feedback signal; wherein the controller generates the first control signal according to the first feedback signal, and generates the second control signal according to the second feedback signal.

以下將對本發明的實施例給出詳細的說明。雖然本發明將結合實施例進行闡述,但應理解這並非意指將本發明限定於這些實施例。相反,本發明意在涵蓋由後附申請專利範圍所界定的本發明精神和範圍內所定義的各種變化、修改和均等物。A detailed description of the embodiments of the present invention will be given below. While the invention will be described in conjunction with the embodiments, it is understood that the invention is not limited to the embodiments. On the contrary, the invention is intended to cover various modifications, modifications and equivalents

此外,在以下對本發明的詳細描述中,為了提供針對本發明的完全的理解,提供了大量的具體細節。然而,於本技術領域中具有通常知識者將理解,沒有這些具體細節,本發明同樣可以實施。在另外的一些實例中,對於大家熟知的方法、程序、元件和電路未作詳細描述,以便於凸顯本發明之主旨。In addition, in the following detailed description of the embodiments of the invention However, it will be understood by those of ordinary skill in the art that the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail in order to facilitate the invention.

圖2所示為根據本發明一實施例的電力轉換器200的 例示性方塊圖。圖4所示為電力轉換器200接收或產生的信號的例示性波形圖。圖2將結合圖4進行描述。2 shows a power converter 200 in accordance with an embodiment of the present invention. An illustrative block diagram. 4 is an illustrative waveform diagram of signals received or generated by power converter 200. Figure 2 will be described in conjunction with Figure 4.

在圖2的實例中,電力轉換器200包含用於控制變壓器202的控制器220。在一實施例中,變壓器202包含初級繞組204、次級繞組206和輔助繞組208。初級繞組204一端與直流輸入電壓VBB 耦接,另一端透過開關218和電阻230耦接到地。次級繞組206透過二極體210連接至負載212。在一實施例中,輔助繞組208位於變壓器202的初級繞組204一側。輔助繞組208一端透過電阻214和電阻216耦接至地,另外一端耦接至地。In the example of FIG. 2, power converter 200 includes a controller 220 for controlling transformer 202. In an embodiment, transformer 202 includes a primary winding 204, a secondary winding 206, and an auxiliary winding 208. One end of primary winding 204 is coupled to DC input voltage V BB and the other end is coupled to ground through switch 218 and resistor 230. Secondary winding 206 is coupled to load 212 through diode 210. In an embodiment, the auxiliary winding 208 is located on the side of the primary winding 204 of the transformer 202. One end of the auxiliary winding 208 is coupled to ground through a resistor 214 and a resistor 216, and the other end is coupled to ground.

控制器220透過控制與初級繞組204串聯耦接的開關218來控制變壓器202。在一實施例中,控制器220由輔助繞組208產生的電壓VDD 供電。電阻230提供回授信號FB1,指示流經初級繞組204的電流IPR 。輔助繞組208提供回授信號FB2,指示輔助繞組208的輸出電壓,而進一步指示次級繞組206的輸出電壓。因此,回授信號FB2能夠反映流經次級繞組206的電流ISE 是否下降到預設的電流值,如0。在一實施例中,回授信號FB2在電阻214和電阻216之間的節點上產生。Controller 220 controls transformer 202 by controlling a switch 218 coupled in series with primary winding 204. In an embodiment, controller 220 is powered by voltage VDD generated by auxiliary winding 208. Resistor 230 provides a feedback signal FB1 indicating the current I PR flowing through primary winding 204. The auxiliary winding 208 provides a feedback signal FB2 indicating the output voltage of the auxiliary winding 208 and further indicating the output voltage of the secondary winding 206. Therefore, the feedback signal FB2 can reflect whether the current I SE flowing through the secondary winding 206 drops to a preset current value, such as zero. In an embodiment, the feedback signal FB2 is generated at a node between the resistor 214 and the resistor 216.

電力轉換器200還包括信號產生器226(如振盪器226)和鉗位電路228。當開關218導通時,鉗位電路228對回授信號FB2的電壓進行鉗位。在一實施例中,控制器220接收參考信號PEAK和參考信號SET。參考信號PEAK決定流經初級繞組204的電流IPR 的最大電流值IPEAK 。參考信號SET具有參考電壓值VSET 。在另一實施例中,參考信 號PEAK和參考信號SET由控制器220產生。Power converter 200 also includes a signal generator 226 (such as oscillator 226) and a clamp circuit 228. When the switch 218 is turned on, the clamp circuit 228 clamps the voltage of the feedback signal FB2. In an embodiment, the controller 220 receives the reference signal PEAK and the reference signal SET. The reference signal PEAK determines the maximum current value I PEAK of the current I PR flowing through the primary winding 204. The reference signal SET has a reference voltage value V SET . In another embodiment, the reference signal PEAK and the reference signal SET are generated by the controller 220.

控制器220接收回授信號FB1和回授信號FB2,並根據回授信號FB1和回授信號FB2產生一個脈衝信號(如脈寬調變信號PWM1)來控制開關218。控制器220透過控制與初級繞組204串聯耦接的開關218,使得變壓器202工作於多個開關週期。在一實施例中,一個開關週期包含充電階段TON 、放電階段TDIS 和調整階段TADJ ,如圖4所示。在充電階段TON ,變壓器202由輸入電壓VBB 供電,流經初級繞組204的電流IPR 增大。在放電階段TDIS ,變壓器202放電對負載212供電,流經次級繞組206的電流ISE 減小。The controller 220 receives the feedback signal FB1 and the feedback signal FB2, and generates a pulse signal (such as the pulse width modulation signal PWM1) according to the feedback signal FB1 and the feedback signal FB2 to control the switch 218. Controller 220 operates transformer 202 for a plurality of switching cycles by controlling switch 218 coupled in series with primary winding 204. In one embodiment, one switching cycle includes a charging phase T ON , a discharging phase T DIS , and an adjustment phase T ADJ , as shown in FIG. 4 . During the charging phase T ON , the transformer 202 is powered by the input voltage V BB and the current I PR flowing through the primary winding 204 is increased. During the discharge phase T DIS , the transformer 202 discharges power to the load 212 and the current I SE flowing through the secondary winding 206 decreases.

更具體而言,在充電階段TON ,控制器220導通開關218,進而使得變壓器202接收輸入電壓VBB 。當開關218導通,與次級繞組206耦接的二極體210反向偏置,沒有電流流經次級繞組206。電流IPR 流經初級繞組204、開關218和電阻230到地。電流IPR 線性增大。因此,在充電階段TON ,變壓器202的磁芯224儲能。鉗位電路228在充電階段TON 對回授信號FB2的電壓進行鉗位,使得回授信號FB2的電壓實質為0。More specifically, during the charging phase T ON , the controller 220 turns on the switch 218, thereby causing the transformer 202 to receive the input voltage V BB . When switch 218 is turned on, diode 210 coupled to secondary winding 206 is reverse biased and no current flows through secondary winding 206. Current I PR flows through primary winding 204, switch 218, and resistor 230 to ground. The current I PR increases linearly. Thus, during the charging phase T ON , the core 224 of the transformer 202 stores energy. The clamp circuit 228 clamps the voltage of the feedback signal FB2 during the charging phase T ON such that the voltage of the feedback signal FB2 is substantially zero.

在放電階段TDIS ,控制器220關關斷關218,透過變壓器202放電對負載212供電。當開關218關斷,與次級繞組206耦接的二極體210正向偏置,儲存在磁芯224的能量透過次級繞組206釋放至電容222和負載212。在放電階段TDIS ,流經次級繞組206的電流ISE 從一個最大電流值ISE-MAX 線性減小至一個預設的電流值(如0)。次級繞組206的最大電流值ISE-MAX 由初級繞組204的最大電流值IPEAK 和變 壓器202的匝數比決定。During the discharge phase T DIS , the controller 220 turns off the shutdown 218 and discharges the load 212 through the transformer 202. When the switch 218 is turned off, the diode 210 coupled to the secondary winding 206 is forward biased, and the energy stored in the core 224 is released through the secondary winding 206 to the capacitor 222 and the load 212. During the discharge phase T DIS , the current I SE flowing through the secondary winding 206 linearly decreases from a maximum current value I SE-MAX to a predetermined current value (eg, 0). The maximum current value I SE-MAX of the secondary winding 206 is determined by the maximum current value I PEAK of the primary winding 204 and the turns ratio of the transformer 202.

在調整階段TADJ ,開關218保持關斷。在一實施例中,在調整階段TADJ ,沒有電流流經初級繞組204或次級繞組206。In the adjustment phase T ADJ , the switch 218 remains off. In an embodiment, no current flows through the primary winding 204 or the secondary winding 206 during the adjustment phase T ADJ .

如圖4中流經次級繞組206的電流ISE 的波形所示,在一個開關週期TS 中次級繞組206輸出的平均電流IOAVG 可以由方程式(1)得到。As shown by the waveform of the current I SE flowing through the secondary winding 206 in FIG. 4, the average current I OAVG output by the secondary winding 206 in one switching period T S can be obtained from equation (1).

其中,TS =TON +TDIS +TADJ Where T S =T ON +T DIS +T ADJ .

在一實施例中,充電階段TON 的時間長度和放電階段TDIS 的時間長度可以由初級繞組204和次級繞組206的電感、輸入電壓VBB 及負載212兩端的輸出電壓VOUT 決定。控制器220決定調整階段TADJ 具有恰當的時間長度進而使得放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數,其中,開關週期TS 的時間長度是充電階段TON 、放電階段TDIS 及調整階段TADJ 的總時間長度。在方程式(1)中,次級繞組206的最大電流值ISE-MAX 由初級繞組204的最大電流值IPEAK 和變壓器202的匝數比決定。在一實施例中,由於初級繞組204的最大電流值IPEAK 為一預設值而變壓器202的匝數比為常數,故次級繞組206的最大電流值ISE-MAX 為常數。因此,根據方程式(1),若放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數(即TS =k* TDIS ,k為常數),則次級繞組206的平均輸出電流IOAVG 也為常數。In an embodiment, the length of time of the charging phase T ON and the length of time of the discharging phase T DIS may be determined by the inductance of the primary winding 204 and the secondary winding 206, the input voltage V BB , and the output voltage V OUT across the load 212. The controller 220 determines that the adjustment phase T ADJ has an appropriate length of time such that the ratio of the length of the discharge phase T DIS to the length of the switching period T S is constant, wherein the length of the switching period T S is the charging phase T ON , The total length of time during the discharge phase T DIS and the adjustment phase T ADJ . In equation (1), the maximum current value I SE-MAX of the secondary winding 206 is determined by the maximum current value I PEAK of the primary winding 204 and the turns ratio of the transformer 202. In one embodiment, since the maximum current value I PEAK of the primary winding 204 is a predetermined value and the turns ratio of the transformer 202 is constant, the maximum current value I SE-MAX of the secondary winding 206 is constant. Therefore, according to equation (1), if the ratio of the length of the discharge phase T DIS to the length of the switching period T S is constant (ie, T S =k* T DIS , k is a constant), the average of the secondary winding 206 The output current I OAVG is also constant.

因此,即便輸入電壓VBB 和輸出電壓VOUT 可能變化,只要放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數,則平均輸出電流IOAVG 也為常數。換言之,透過利用一個濾波器(如與負載212耦接的電容222),電力轉換器200可以為負載212提供實質為恆定的輸出電流。此處”實質恆定”係指輸出電流僅在一範圍內變化,故由電路元件的非理想條件所導致的電流漣波(ripple)可以忽略不計。Therefore, even if the input voltage V BB and the output voltage V OUT may vary, as long as the ratio of the length of the discharge phase T DIS to the length of the switching period T S is constant, the average output current I OAVG is also constant. In other words, by utilizing a filter (such as capacitor 222 coupled to load 212), power converter 200 can provide substantially constant output current to load 212. Here, "substantially constant" means that the output current varies only within a range, so current ripple caused by non-ideal conditions of the circuit components is negligible.

圖3所示為圖2中的控制器220的架構示意圖。圖3將結合圖2和圖4進行描述。控制器220使得調整階段TADJ 具有恰當的時間長度進而使得放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數。因此電力轉換器200可以為負載212提供實質恆定輸出電流。FIG. 3 is a schematic diagram showing the architecture of the controller 220 of FIG. 2. Figure 3 will be described in conjunction with Figures 2 and 4. The controller 220 causes the adjustment phase T ADJ to have an appropriate length of time such that the ratio of the length of the discharge phase T DIS to the length of the switching period T S is constant. Thus power converter 200 can provide a substantially constant output current to load 212.

在一實施例中,控制器220包含一個信號產生器(例如一振盪器226)、比較器314、比較器316和脈衝信號產生器318(例如脈寬調變信號產生器318)。振盪器226根據回授信號FB2產生鋸齒波信號SAW。回授信號FB2指示次級繞組206的輸出電壓。比較器314將鋸齒波信號SAW和參考信號SET進行比較。參考信號SET具有參考電壓位準VSET 。比較器316將回授信號FB1和參考信號PEAK進行比較。回授信號FB1指示流經初級繞組204的電流ISE 。參考信號PEAK決定流經初級繞組204的電流IPR 的最大電流值IPEAK 。脈寬調變信號產生器318與比較器314以及比較器316耦接,並產生一個脈寬調變信號PWM1。來自振盪器226的鋸齒波信號SAW可用來控制脈寬調變信號PWM1的工 作週期。脈寬調變信號PWM1控制開關318的導通狀態進而控制變壓器202的電力。In one embodiment, controller 220 includes a signal generator (e.g., an oscillator 226), a comparator 314, a comparator 316, and a pulse signal generator 318 (e.g., pulse width modulation signal generator 318). The oscillator 226 generates a sawtooth wave signal SAW based on the feedback signal FB2. The feedback signal FB2 indicates the output voltage of the secondary winding 206. The comparator 314 compares the sawtooth wave signal SAW with the reference signal SET. The reference signal SET has a reference voltage level V SET . Comparator 316 compares feedback signal FB1 with reference signal PEAK. The feedback signal FB1 indicates the current I SE flowing through the primary winding 204. The reference signal PEAK determines the maximum current value I PEAK of the current I PR flowing through the primary winding 204. The pulse width modulation signal generator 318 is coupled to the comparator 314 and the comparator 316 and generates a pulse width modulation signal PWM1. The sawtooth signal SAW from the oscillator 226 can be used to control the duty cycle of the pulse width modulation signal PWM1. The pulse width modulation signal PWM1 controls the conduction state of the switch 318 to control the power of the transformer 202.

控制器220還包含控制信號產生器320。控制信號產生器320根據回授信號FB2產生控制信號CTRL。控制信號CTRL施加至振盪器226。在一實施例中,如果回授信號FB2的電壓大於預設臨限值TH(例如TH>0V),則控制信號CTRL為邏輯1,否則控制信號CTRL為邏輯0。在圖3的實例中,振盪器226包含電流源302和304、開關306和308以及電容310。電容310上產生的電壓信號即鋸齒波信號SAW。根據開關306和308的導通狀態,電容310可以在電流源302的作用下充電或在電流源304的作用下放電。Controller 220 also includes a control signal generator 320. The control signal generator 320 generates a control signal CTRL based on the feedback signal FB2. Control signal CTRL is applied to oscillator 226. In an embodiment, if the voltage of the feedback signal FB2 is greater than the preset threshold TH (eg, TH>0V), the control signal CTRL is logic 1, otherwise the control signal CTRL is logic 0. In the example of FIG. 3, oscillator 226 includes current sources 302 and 304, switches 306 and 308, and capacitor 310. The voltage signal generated on the capacitor 310 is the sawtooth signal SAW. Depending on the conduction state of switches 306 and 308, capacitor 310 can be charged by current source 302 or discharged by current source 304.

如果電容310的電壓上升至參考電壓值VSET ,則控制器220產生具有第一位準的脈寬調變信號PWM1以導通開關218(例如,PWM1為邏輯1)。進而使得變壓器202工作於充電階段TON 。在一實施例中鉗位電路228強迫回授信號FB2的電壓實質為0,進而控制信號CTRL具有第一位準(如邏輯0)。控制信號CTRL控制振盪器226中的開關308。控制信號CTRL透過NOT閘312耦接至開關306。在圖3的實例中,當控制信號CTRL為邏輯0時,開關306導通,開關308關斷。電容310由電流源302的電流充電。因此,電容310的電壓(例如鋸齒波信號SAW的電壓)從參考電壓值VSET 開始上升。同時,流經初級繞組204的電流IPR 增大。比較器316將回授信號FB1與參考信號PEAK進行比較。當回授信號FB1的電壓達到參考信號PEAK的電壓時,代表流經初級繞組204的電流IPR 增大至最大電流值IPEAK , 此時控制器220關斷開關318,進而結束充電階段TON 並啟動放電階段TDIS 。具體而言,脈寬調變信號產生器318產生具有第二位準的脈寬調變信號PWM1以關斷開關218(例如,PWM1為邏輯0)。當充電階段TON 結束時,電容310的電壓(例如鋸齒波信號SAW的電壓)上升至第一電壓值V1 ,如圖4所示。換言之,電容310的電壓(例如鋸齒波信號SAW的電壓)從參考電壓值VSET 上升至第一電壓值V1 這段時間內開關218導通。If the voltage of the capacitor 310 rises to the reference voltage value V SET , the controller 220 generates a pulse width modulation signal PWM1 having a first level to turn on the switch 218 (eg, PWM1 is a logic 1). In turn, the transformer 202 is operated in the charging phase T ON . In one embodiment, the clamping circuit 228 forces the voltage of the feedback signal FB2 to be substantially zero, and the control signal CTRL has a first level (eg, a logic zero). Control signal CTRL controls switch 308 in oscillator 226. Control signal CTRL is coupled to switch 306 through NOT gate 312. In the example of FIG. 3, when control signal CTRL is logic 0, switch 306 is turned "on" and switch 308 is turned "off". Capacitor 310 is charged by the current of current source 302. Therefore, the voltage of the capacitor 310 (for example, the voltage of the sawtooth wave signal SAW) rises from the reference voltage value V SET . At the same time, the current I PR flowing through the primary winding 204 increases. Comparator 316 compares feedback signal FB1 with reference signal PEAK. When the voltage of the feedback signal FB1 reaches the voltage of the reference signal PEAK, the current I PR flowing through the primary winding 204 is increased to the maximum current value I PEAK , at which time the controller 220 turns off the switch 318, thereby ending the charging phase T ON . And start the discharge phase T DIS . In particular, pulse width modulation signal generator 318 generates a pulse width modulation signal PWM1 having a second level to turn off switch 218 (eg, PWM1 is a logic 0). When the charging phase T ON ends, the voltage of the capacitor 310 (for example, the voltage of the sawtooth wave signal SAW) rises to the first voltage value V 1 as shown in FIG. In other words, the voltage of the capacitor 310 (for example, the voltage of the sawtooth wave signal SAW) is turned on from the reference voltage value V SET to the first voltage value V 1 .

在放電階段TDIS ,開關218關斷,流經次級繞組206的電流ISE 從最大電流值ISE-MAX 減小。在放電階段TDIS ,輔助繞組208產生實質恆定輸出電壓。該輸出電壓被電阻214和216分壓。因此在放電階段TDIS ,回授信號FB2的電壓(如電阻216兩端的電壓)與輔助繞組208的輸出電壓成比例,進而也是實質恆定。在一實施例中,恰當選擇電阻214和電阻216的阻值,使得在放電階段TDIS ,回授信號FB2的電壓大於預設臨限值TH。當回授信號FB2的電壓大於預設臨限值TH,控制信號CTRL為邏輯1,使開關306關斷而開關308導通。電容310以電流源304的電流放電。因此,電容310的電壓從第一電壓值V1 下降。During the discharge phase T DIS , the switch 218 is turned off and the current I SE flowing through the secondary winding 206 is reduced from the maximum current value I SE-MAX . During the discharge phase T DIS , the auxiliary winding 208 produces a substantially constant output voltage. This output voltage is divided by resistors 214 and 216. Therefore, in the discharge phase T DIS , the voltage of the feedback signal FB2 (such as the voltage across the resistor 216) is proportional to the output voltage of the auxiliary winding 208, and is thus substantially constant. In one embodiment, the resistance of the resistor 214 and the resistor 216 are properly selected such that during the discharge phase T DIS , the voltage of the feedback signal FB2 is greater than the preset threshold TH. When the voltage of the feedback signal FB2 is greater than the preset threshold TH, the control signal CTRL is logic 1, turning the switch 306 off and the switch 308 conducting. Capacitor 310 is discharged at the current of current source 304. Therefore, the voltage of the capacitor 310 drops from the first voltage value V 1 .

當代表次級繞組206的輸出電壓的回授信號FB2的電壓下降至臨限值TH,表示流經次級繞組206的電流ISE 減小到預設的電流值時,控制器220結束放電階段TDIS 並啟動調整階段TADJ 。在一實施例中,當流經次級繞組206的電流ISE 減小到實質為0時,控制器220結束放電階段TDIS 並啟動調整階段TADJ 。當放電階段TDIS 結束時,電容310的 電壓(例如鋸齒波信號SAW的電壓)下降至第二電壓值V2 ,如圖4所示。When the voltage of the feedback signal FB2 representing the output voltage of the secondary winding 206 drops to the threshold value TH, indicating that the current I SE flowing through the secondary winding 206 is reduced to a preset current value, the controller 220 ends the discharge phase. T DIS starts the adjustment phase T ADJ . In an embodiment, when the current I SE flowing through the secondary winding 206 is reduced to substantially zero, the controller 220 ends the discharge phase T DIS and initiates the adjustment phase T ADJ . When the discharge phase T DIS ends, the voltage of the capacitor 310 (for example, the voltage of the sawtooth wave signal SAW) drops to the second voltage value V 2 as shown in FIG.

在調整階段TADJ ,因為回授信號FB2的電壓下降至臨限值TH,控制信號CTRL變為邏輯0。開關306導通,開關308關斷。電容310再次由電流源302的電流充電。電容310的電壓從第二電壓值V2 上升。在調整階段TADJ ,開關218保持關斷,沒有電流流經初級繞組204或次級繞組206。當鋸齒波信號SAW的電壓上升至參考電壓值VSET ,則控制器220結束調整階段TADJ 並導通開關218以啟動下一個開關週期TS 中的充電階段TON 。具體來講,脈寬調變信號產生器318產生具有第一位準的脈寬調變信號PWM1以導通開關218(如,PWM1為邏輯1)。In the adjustment phase T ADJ , since the voltage of the feedback signal FB2 drops to the threshold TH, the control signal CTRL becomes a logic 0. Switch 306 is turned "on" and switch 308 is turned "off". Capacitor 310 is again charged by the current of current source 302. The voltage of the capacitor 310 rises from the second voltage value V 2 . During the adjustment phase T ADJ , the switch 218 remains off and no current flows through the primary winding 204 or the secondary winding 206 . When the voltage of the sawtooth signal SAW rises to the reference voltage value V SET , the controller 220 ends the adjustment phase T ADJ and turns on the switch 218 to initiate the charging phase T ON in the next switching cycle T S . Specifically, the pulse width modulation signal generator 318 generates a pulse width modulation signal PWM1 having a first level to turn on the switch 218 (eg, PWM1 is a logic 1).

假設電容310的電容值為C1 ,電流源302的電流為I1 ,電流源304的電流為I2 。在充電階段TON 結束時,鋸齒波信號SAW的電壓(電容310的電壓)可以表示為: Assume that the capacitance value of the capacitor 310 is C 1 , the current of the current source 302 is I 1 , and the current of the current source 304 is I 2 . At the end of the charging phase T ON , the voltage of the sawtooth signal SAW (the voltage of the capacitor 310) can be expressed as:

在放電階段TDIS 結束時,鋸齒波信號SAW的電壓可以表示為: At the end of the discharge phase T DIS , the voltage of the sawtooth signal SAW can be expressed as:

在調整階段TADJ 結束時,鋸齒波信號SAW的電壓可以表示為: At the end of the adjustment phase T ADJ , the voltage of the sawtooth signal SAW can be expressed as:

因此,調整階段TADJ 的時間長度可以由方程式(2)- (4)推出,即: Therefore, the length of the adjustment phase T ADJ can be derived from equations (2)-(4), namely:

由方程式(5),調整階段TADJ 的時間長度和開關週期TS 的時間長度之間的關係可以表示為: From equation (5), the relationship between the length of the adjustment phase T ADJ and the length of the switching period T S can be expressed as:

根據方程式(6)可以得到,放電階段TDIS 的時間長度與充電階段TON 、放電階段TDIS 及調整階段TADJ 的總的時間長度的比值由電流I1 、I2 決定。如果分別來自電流源302、304的電流I1 、I2 的大小恆定,則放電階段TDIS 的時間長度與開關週期TS 的時間長度成比例。因此,參考方程式(1),次級繞組206的平均輸出電流IOAVG 實質為常數。According to equation (6) can be obtained, the ratio of the length of time the total length of the discharge time period T DIS the charging phase T ON, and the discharging period T DIS adjust the period T ADJ 1, I 2 determined by the current I. If the magnitudes of the currents I 1 , I 2 from the current sources 302, 304, respectively, are constant, the length of time of the discharge phase T DIS is proportional to the length of time of the switching period T S . Therefore, referring to equation (1), the average output current I OAVG of the secondary winding 206 is substantially constant.

圖5所示為根據本發明一實施例的控制變壓器的例示性方法流程圖500。圖5將結合圖2、圖3以及圖4進行描述。FIG. 5 shows a flowchart 500 of an exemplary method of controlling a transformer in accordance with an embodiment of the present invention. FIG. 5 will be described in conjunction with FIGS. 2, 3, and 4.

在步驟502中,變壓器202工作於多個開關週期。一個開關週期包含充電階段TON 、放電階段TDIS 和調整階段TADJIn step 502, transformer 202 operates for a plurality of switching cycles. One switching cycle includes a charging phase T ON , a discharging phase T DIS , and an adjustment phase T ADJ .

在步驟504中,在充電階段TON ,以輸入電源對變壓器202供電。在充電階段TON ,與變壓器202的初級繞組204串聯耦接的開關218導通。在一實施例中,透過監測流經初級繞組204的電流來控制充電階段TON 的時間長度。具體而言,當流經初級繞組204的電流增大至一個預設的最大電流值時,結束充電階段TON (關斷開關218)並啟動放電階段TDISIn step 504, the transformer 202 is powered with an input power source during the charging phase T ON . In the charging phase T ON , the switch 218 coupled in series with the primary winding 204 of the transformer 202 is turned on. In one embodiment, the length of time of the charging phase T ON is controlled by monitoring the current flowing through the primary winding 204. Specifically, when the current flowing through the primary winding 204 increases to a preset maximum current value, the charging phase T ON is ended (turning off the switch 218) and the discharging phase T DIS is started.

在步驟506,在放電階段TDIS ,利用變壓器202對負載供電。在一實施例中,透過監測變壓器202輔助繞組208的輸出電壓來控制放電階段TDIS 的時間長度。輔助繞組208的輸出電壓可以指示流經變壓器202次級繞組206的電流是否下降到一個預設的電流值。具體而言,當流經次級繞組206的電流減小到預設的電流值(如0)時,結束放電階段TDIS 並啟動調整階段TADJ 。在一實施例中。當輔助繞組208的輸出電壓減小至一個預設的電壓值時,說明流經次級繞組206的電流減小至該預設的電流值。At step 506, the load is supplied to the load using transformer 202 during the discharge phase T DIS . In one embodiment, the length of time of the discharge phase T DIS is controlled by monitoring the output voltage of the transformer 202 auxiliary winding 208. The output voltage of the auxiliary winding 208 can indicate whether the current flowing through the secondary winding 206 of the transformer 202 drops to a predetermined current value. Specifically, when the current flowing through the secondary winding 206 is reduced to a preset current value (eg, 0), the discharge phase T DIS is ended and the adjustment phase T ADJ is initiated. In an embodiment. When the output voltage of the auxiliary winding 208 is reduced to a predetermined voltage value, the current flowing through the secondary winding 206 is reduced to the preset current value.

在步驟508中,決定調整階段TADJ 的時間長度,使得放電階段TDIS 的時間長度與充電階段TON 、放電階段TDIS 及調整階段TADJ 的總時間長度之間的比值為常數。在一實施例中,調整階段TADJ 的時間長度由一個振盪器226決定。振盪器226產生鋸齒波信號SAW。在充電階段TON ,鋸齒波信號SAW的電壓從預設的參考電壓值VSET 上升至第一電壓值V1 。在放電階段TDIS ,鋸齒波信號SAW的電壓從第一電壓值V1 下降至第二電壓值V2 。在調整階段TADJ ,鋸齒波信號SAW的電壓從第二電壓值V2 上升至預設的參考電壓值VSET 。當鋸齒波信號SAW的電壓上升至預設的參考電壓值VSET 時,結束調整階段TADJ 並啟動一個新的開關週期TSIn step 508, it determines the length of the time period T ADJ adjusted such that the length of the discharge time period T DIS with the charging phase T ON, the ratio between the total duration of the discharge period T DIS and adjusting period T ADJ is constant. In one embodiment, the length of the adjustment phase T ADJ is determined by an oscillator 226. The oscillator 226 generates a sawtooth wave signal SAW. During the charging phase T ON , the voltage of the sawtooth signal SAW rises from the preset reference voltage value V SET to the first voltage value V 1 . In the discharge phase T DIS , the voltage of the sawtooth wave signal SAW drops from the first voltage value V 1 to the second voltage value V 2 . In the adjustment phase T ADJ , the voltage of the sawtooth signal SAW rises from the second voltage value V 2 to a preset reference voltage value V SET . When the voltage of the sawtooth signal SAW rises to the preset reference voltage value V SET , the adjustment phase T ADJ is ended and a new switching period T S is initiated.

據此,本發明提供一種控制電力轉換器的電路與方法,該電力轉換器可用於對各種負載供電。該電力轉換器包含工作於多個開關週期的變壓器。至少一個開關週期中包含充電階段TON 、放電階段TDIS 和調整階段TADJ 。該電力轉換器可以使得調整階段TADJ 具有合適的時間長度,進而 使放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數。開關週期TS 的時間長度是充電階段TON 、放電階段TDIS 和調整階段TADJ 總的時間長度。因此,每個開關週期輸出平均電流的為實質恆定。Accordingly, the present invention provides a circuit and method for controlling a power converter that can be used to power various loads. The power converter includes a transformer that operates over multiple switching cycles. At least one switching cycle includes a charging phase T ON , a discharging phase T DIS , and an adjustment phase T ADJ . The power converter can have an adjustment phase T ADJ having a suitable length of time, such that the ratio of the length of the discharge phase T DIS to the length of the switching period T S is constant. The length of the switching period T S is the total length of time in the charging phase T ON , the discharging phase T DIS and the tuning phase T ADJ . Therefore, the average current output per switching cycle is substantially constant.

本發明提供的電力轉換器可以應用於多種場合。在一實施例中,該電力轉換器可以提供實質恆定的電流輸出以驅動發光二極體串等光源。在另一實施例中,該電力轉換器可以提供實質恆定的電流以對電池充電。與包含光耦合器和誤差放大器的習知的反馳式轉換器相比,本發明提供的電力轉換器的尺寸相對較小。The power converter provided by the present invention can be applied to various occasions. In an embodiment, the power converter can provide a substantially constant current output to drive a light source such as a light emitting diode string. In another embodiment, the power converter can provide a substantially constant current to charge the battery. The power converter provided by the present invention is relatively small in size compared to conventional flyback converters including optocouplers and error amplifiers.

此外,即便電力轉換器的輸入電壓和輸出電壓的變化可能導致充電階段TON 和放電階段TDIS 的時間長度產生變化,該電力轉換器能自動決定調整階段TADJ 的時間長度以保持放電階段TDIS 的時間長度與開關週期TS 的時間長度的比值為常數。因此,該電力轉換器能夠自動調節而輸出平均值恆定的電流。而且從方程式(1)可以看到,該電力轉換器的輸出電流的平均值不受變壓器繞組電感值的影響,進而能夠更加精確的控制輸出電流。In addition, even if the change of the input voltage and the output voltage of the power converter may cause a change in the length of the charging phase T ON and the discharging phase T DIS , the power converter can automatically determine the length of the adjustment phase T ADJ to maintain the discharging phase T The ratio of the length of the DIS to the length of the switching period T S is constant. Therefore, the power converter can automatically adjust to output a current having a constant average value. Moreover, it can be seen from equation (1) that the average value of the output current of the power converter is not affected by the inductance value of the transformer winding, thereby enabling more precise control of the output current.

圖6所示為根據本發明的一個實施例的用以驅動負載212的負載驅動電路600的示意圖。圖6中與圖2編號相同的元件具有類似的功能。在圖6的例子中,負載驅動電路600與電源602相連,電源602產生一交流輸入電壓VAC (例如,具有正弦波形的交流電壓)。負載驅動電路600作為一個電源轉換器,接收交流輸入電壓VAC 並提供一輸出電壓VOUT 為負載212供電。負載212可為光源(例如,發 光二極體光源),但並不以此為限。FIG. 6 shows a schematic diagram of a load drive circuit 600 for driving a load 212 in accordance with one embodiment of the present invention. Elements in Figure 6 that are numbered the same as in Figure 2 have similar functions. In the example of FIG. 6, load drive circuit 600 is coupled to a power source 602 that produces an AC input voltage V AC (eg, an AC voltage having a sinusoidal waveform). The load drive circuit 600 acts as a power converter that receives the AC input voltage V AC and provides an output voltage V OUT to power the load 212. The load 212 can be a light source (for example, a light emitting diode light source), but is not limited thereto.

在一個實施例中,負載驅動電路600包括整流器603、轉換器604、變壓器202和控制器620。在一個實施例中,控制器620包含埠VDD、埠DRV1、埠CS1、埠DRV2、埠CS2和埠FB。整流器603整流交流輸入電壓VAC ,以提供整流電壓VREC (例如,具有整流後的正弦波形)。電容605作為一濾波器,以平滑整流電壓VREC 。轉換器604連接於整流器603和變壓器202之間,以將整流電壓VREC 轉換成輸入電壓VIN 。在圖6的實施例中,轉換器604為升壓轉換器,包含電感L1、二極體D1、電容C1、電阻R1和開關613。然而,本發明並不局限於此,轉換器604也可以是其他類型,例如降壓轉換器或降壓-升壓轉換器。電阻R1提供指示流經電感L1的電流的監測信號656,控制器620透過埠CS1接收監測信號656。變壓器202由輸入電壓VIN 供電,並產生輸出電壓VOUT 為負載212供電。連接於負載212的電容222,以濾除流經負載212的電流ILOAD 的漣波。控制器620在埠DRV1上產生一開關控制信號654,以調節輸入電壓VIN ,並在埠DRV2上產生一開關控制信號650,以調節流經負載212的電流ILOADIn one embodiment, load drive circuit 600 includes a rectifier 603, a converter 604, a transformer 202, and a controller 620. In one embodiment, controller 620 includes 埠 VDD, 埠 DRV1, 埠 CS1, 埠 DRV2, 埠 CS2, and 埠 FB. The rectifier 603 rectifies the AC input voltage V AC to provide a rectified voltage V REC (eg, having a rectified sinusoidal waveform). Capacitor 605 acts as a filter to smooth the rectified voltage V REC . Converter 604 is coupled between rectifier 603 and transformer 202 to convert rectified voltage V REC to input voltage V IN . In the embodiment of FIG. 6, converter 604 is a boost converter comprising an inductor L1, a diode D1, a capacitor C1, a resistor R1, and a switch 613. However, the present invention is not limited thereto, and the converter 604 may be of other types such as a buck converter or a buck-boost converter. Resistor R1 provides a monitor signal 656 indicative of the current flowing through inductor L1, and controller 620 receives monitor signal 656 via 埠CS1. Transformer 202 is powered by input voltage V IN and produces an output voltage V OUT that powers load 212. A capacitor 222 is coupled to the load 212 to filter out the ripple of the current I LOAD flowing through the load 212. Controller 620 generates a switch control signal 654 on 埠DRV1 to regulate input voltage V IN and a switch control signal 650 on 埠DRV2 to regulate current I LOAD flowing through load 212.

在一個實施例中,變壓器202包含初級繞組204、次級繞組206、輔助繞組208和磁芯224。初級繞組204的一端與轉換器604相連,另一端透過開關218和電阻230連接到地。次級繞組206透過二極體210和電容222連接至負載212。在一個實施例中,輔助繞組208的一端透過電阻614和電阻616連接到地,另一端連接到地。控制器 620的埠FB連接到電阻614和電阻616的共同節點。In one embodiment, transformer 202 includes a primary winding 204, a secondary winding 206, an auxiliary winding 208, and a magnetic core 224. One end of primary winding 204 is coupled to converter 604 and the other end is coupled to ground via switch 218 and resistor 230. Secondary winding 206 is coupled to load 212 through diode 210 and capacitor 222. In one embodiment, one end of the auxiliary winding 208 is connected to ground through a resistor 614 and a resistor 616, and the other end is connected to ground. Controller The 埠FB of 620 is connected to a common node of resistor 614 and resistor 616.

圖7所示為根據本發明的一個實施例示於圖6之負載驅動電路600所接收或產生的信號的波形圖。圖7將結合圖6進行描述。圖7所示的波形依次表示流經初級繞組204的電流IPR 、流經次級繞組206的電流ISE 、輔助繞組208的非同名端的電壓VAUX 、流經控制器620的埠FB的電流IFB 、埠FB處的電壓VFB 和開關控制信號650。Figure 7 is a waveform diagram of signals received or generated by the load drive circuit 600 of Figure 6 in accordance with one embodiment of the present invention. Figure 7 will be described in conjunction with Figure 6. The waveform shown in FIG. 7 sequentially shows the current I PR flowing through the primary winding 204, the current I SE flowing through the secondary winding 206, the voltage V AUX of the non-identical end of the auxiliary winding 208, and the current flowing through the 埠FB of the controller 620. I FB , voltage V FB at 埠 FB, and switch control signal 650.

在一個實施例中,控制器620產生開關控制信號650,以導通或斷開開關218,使變壓器202工作於多個週期。在一個實施例中,一個週期包含充電階段TON 和放電階段TDIS 。或者,如圖7所示的實施例,一個週期包含充電階段TON 、放電階段TDIS 和調整階段TADJ 。在這兩種情況下,開關控制信號650都是在充電階段TON 導通開關218,並在放電階段TDIS 斷開開關218。因此,在充電階段TON ,變壓器202由輸入電壓VIN 供電,流經初級繞組204的電流IPR 增大。在一個實施例中,在充電階段TON ,電阻230產生指示電流IPR 的監測信號652。控制器620的埠CS2接收監測信號652。在放電階段TDIS ,變壓器202放電,以給負載212供電,流經次級繞組206的電流ISE 減小。In one embodiment, controller 620 generates a switch control signal 650 to turn switch 218 on or off to operate transformer 202 for a plurality of cycles. In one embodiment, one cycle includes a charge phase T ON and a discharge phase T DIS . Alternatively, as in the embodiment shown in FIG. 7, one cycle includes a charging phase T ON , a discharging phase T DIS , and an adjustment phase T ADJ . In both cases, the switch control signal 650 turns the switch 218 on during the charging phase T ON and turns off the switch 218 during the discharge phase T DIS . Therefore, during the charging phase T ON , the transformer 202 is powered by the input voltage V IN and the current I PR flowing through the primary winding 204 is increased. In one embodiment, during the charging phase T ON , the resistor 230 generates a monitoring signal 652 indicative of the current I PR . The 埠CS2 of the controller 620 receives the monitoring signal 652. During the discharge phase T DIS , the transformer 202 is discharged to supply the load 212 and the current I SE flowing through the secondary winding 206 is reduced.

在充電階段TON 和放電階段TDIS ,變壓器202為控制器620的埠FB提供不同的回授信號。具體而言,在一個實施例中,在充電階段TON ,電壓VAUX 的電壓值V3 與初級繞組204的電壓VIN 成比例,可由方程式(7)得到:VAUX =V3 =-VIN *(NA /NP ) (7)During the charging phase T ON and the discharging phase T DIS , the transformer 202 provides a different feedback signal for the 埠 FB of the controller 620. Specifically, in one embodiment, during the charging phase T ON , the voltage value V 3 of the voltage V AUX is proportional to the voltage V IN of the primary winding 204, which can be obtained from equation (7): V AUX =V 3 =−V IN *(N A /N P ) (7)

其中,NA 表示輔助繞組208的匝數,NP 表示初級繞組 204的匝數。如方程式(7)所示,電壓VAUX 在充電階段TON 為負的電壓值。在一個實施例中,控制器620將埠FB的電壓VFB 鉗位在預設電壓值(例如,0伏特),以防止電壓VFB 降到0伏特以下。因此,在一個實施例中,在充電階段TON ,電壓VFB 等於0伏特。所以,電流IFB 從埠FB流經電阻614流至輔助繞組208。電流IFB 的電流值I3 可由方程式(8)得到:IFB =I3 =VIN *(NA /NP )/R614 (8)Where N A represents the number of turns of the auxiliary winding 208 and N P represents the number of turns of the primary winding 204. As shown in equation (7), the voltage V AUX is a negative voltage value during the charging phase T ON . In one embodiment, controller 620 clamps voltage FB ofFB to a predetermined voltage value (eg, 0 volts) to prevent voltage V FB from dropping below zero volts. Thus, in one embodiment, during the charging phase T ON , the voltage V FB is equal to 0 volts. Therefore, current I FB flows from 埠FB through resistor 614 to auxiliary winding 208. The current value I 3 of the current I FB can be obtained by the equation (8): I FB = I 3 = V IN * (N A / N P ) / R 614 (8)

其中,R614 表示電阻614的阻值。由於(NA /NP )/R614 是一個基本恒定的常數,電流IFB 的電流值I3 與電壓VIN 成比例。Where R 614 represents the resistance of the resistor 614. Since (N A /N P )/R 614 is a substantially constant constant, the current value I 3 of the current I FB is proportional to the voltage V IN .

在放電階段TDIS ,輔助繞組208感應次級繞組206的電能狀態。具體而言,在一個實施例中,當流經次級繞組206的電流ISE 減小,輔助繞組208上的電壓VAUX 具有正的電壓值V4 (例如,V4 =VOUT *(NA /NS )),其中NS 表示次級繞組206的匝數。當電流ISE 減小到預設電流值(例如,0安培)時,電壓VAUX 產生負緣。電阻614和電阻616對電壓VAUX 進行分壓,以提供與電壓VAUX 成比例的電壓VFB 。因此,在放電階段TDIS ,埠FB的電壓VFB 指示流經次級繞組206的電流ISE 是否減小到預設電流值。During the discharge phase T DIS , the auxiliary winding 208 senses the electrical state of the secondary winding 206. In particular, in one embodiment, when the current I SE flowing through the secondary winding 206 decreases, the voltage V AUX on the auxiliary winding 208 has a positive voltage value V 4 (eg, V 4 =V OUT *(N) A / N S )), where N S represents the number of turns of the secondary winding 206. When the current I SE is reduced to a preset current value (eg, 0 amps), the voltage V AUX produces a negative edge. Resistor 614 and resistor 616 divide voltage V AUX to provide a voltage V FB that is proportional to voltage V AUX . Therefore, at the discharge phase T DIS , the voltage V FB of 埠 FB indicates whether the current I SE flowing through the secondary winding 206 is reduced to a preset current value.

因此,在充電階段TON ,流經埠FB的電流IFB 與輸入電壓VIN 成比例。在放電階段TDIS ,埠FB的電壓VFB 指示電流ISE 是否減小到預設電流值。有利之處在於,控制器620透過同一埠FB接收指示輸入電壓VIN 的第一回授信號IFB 和指示次級繞組206的電能狀態的第二回授信號VFB 。因此,減 少了控制器620的埠數目,進而減小了負載驅動電路600的尺寸和成本。Therefore, during the charging phase T ON , the current I FB flowing through the 埠FB is proportional to the input voltage V IN . In the discharge phase T DIS , the voltage V FB of 埠 FB indicates whether the current I SE is reduced to a preset current value. Advantageously, the controller 620 receives the first feedback signal I FB indicating the input voltage V IN and the second feedback signal V FB indicating the power state of the secondary winding 206 through the same FB . Therefore, the number of turns of the controller 620 is reduced, thereby reducing the size and cost of the load drive circuit 600.

在一個實施例中,控制器620根據第一回授信號控制埠DRV1的開關控制信號654,以調節電壓VIN (例如,將電壓VIN 調節到目標電壓值)。此外,控制器620根據第二回授信號控制埠DRV2的開關控制信號650,以調節電流ILOAD (例如,將電流ILOAD 保持在恒定電流值)。控制器620的工作原理將在圖8中進一步描述。In one embodiment, the controller 620 according to the switch control signal 654 to control first port DRV1 feedback signal to regulate the voltage V IN (e.g., the voltage V IN is adjusted to the target voltage). In addition, controller 620 controls switch control signal 650 of 埠DRV2 based on the second feedback signal to adjust current I LOAD (eg, to maintain current I LOAD at a constant current value). The operation of controller 620 will be further described in FIG.

在一個實施例中,電容605具有較小的電容值(例如,小於0.5微法拉),以幫助消除或減小整流電壓VREC 的波形失真(以校正負載驅動電路600的功率因數)。透過連接在整流器603和變壓器202之間的轉換器604使輸入電壓VIN 具有基本恒定的電壓值。由於電壓VIN 相對穩定,進而減小了電流ILOAD 的漣波。In one embodiment, capacitor 605 has a smaller capacitance value (eg, less than 0.5 microfarads) to help eliminate or reduce waveform distortion of rectified voltage V REC (to correct the power factor of load drive circuit 600). The input voltage V IN has a substantially constant voltage value through a converter 604 connected between the rectifier 603 and the transformer 202. Since the voltage V IN is relatively stable, the ripple of the current I LOAD is reduced.

圖8所示為根據本發明的一個實施例的控制器620的結構示意圖。圖8與圖2、圖3和圖6中有相同標號的元件具有類似的功能。圖8將結合圖3、圖4、圖6和圖7進行描述。如圖8所示,控制器620包含電壓控制單元802和電流控制單元804。電壓控制單元802監測流經埠FB的電流IFB ,並在埠DRV1產生開關控制信號654,以調節輸入電壓VIN 。電流控制單元804監測埠FB上的電壓VFB ,並在埠DRV2產生開關控制信號650,以調節輸出電流IOUTFIG. 8 is a block diagram showing the structure of a controller 620 according to an embodiment of the present invention. Elements of the same reference numerals in Fig. 8 and Figs. 2, 3 and 6 have similar functions. FIG. 8 will be described in conjunction with FIGS. 3, 4, 6, and 7. As shown in FIG. 8, the controller 620 includes a voltage control unit 802 and a current control unit 804. The voltage control unit 802 monitors the current I FB flowing through the 埠FB and generates a switch control signal 654 at the 埠DRV1 to regulate the input voltage V IN . The current control unit 804 monitors the voltage V FB on the 埠FB and generates a switch control signal 650 at 埠 DRV 2 to regulate the output current I OUT .

在一個實施例中,電流控制單元804具有與圖3中控制器220相似的結構。電流控制單元804包含控制信號產生器320、振盪器226、比較器314、比較器316和脈寬調 變信號產生器318。控制信號產生器320根據第二回授信號VFB 產生控制信號CTRL。振盪器226接收控制信號CTRL,並由此產生鋸齒波信號SAW。比較器314將鋸齒波信號SAW和參考信號SET進行比較。比較器316將指示充電階段TON 的電流IPR 的監測信號652和參考信號PEAK1進行比較。參考信號PEAK1決定流經初級繞組204的峰值電流IPEAK1 。脈衝寬度調製信號產生器318與比較器314和比較器316相連,並產生開關控制信號650(例如,脈衝寬度調製信號),以控制開關218。In one embodiment, current control unit 804 has a similar structure to controller 220 of FIG. The current control unit 804 includes a control signal generator 320, an oscillator 226, a comparator 314, a comparator 316, and a pulse width modulation signal generator 318. The control signal generator 320 generates a control signal CTRL based on the second feedback signal V FB . The oscillator 226 receives the control signal CTRL and thereby generates a sawtooth wave signal SAW. The comparator 314 compares the sawtooth wave signal SAW with the reference signal SET. The comparator 316 compares the monitor signal 652 indicating the current I PR of the charging phase T ON with the reference signal PEAK1. The reference signal PEAK1 determines the peak current I PEAK1 flowing through the primary winding 204. Pulse width modulated signal generator 318 is coupled to comparator 314 and comparator 316 and produces a switch control signal 650 (e.g., a pulse width modulated signal) to control switch 218.

與控制器220的工作原理類似,鋸齒波信號SAW控制脈寬調變信號650的責任週期。具體而言,結合如圖3和圖4所述,在充電階段TON ,鋸齒波信號SAW從參考信號SET的電壓值VSET 開始增加,此時,流經初級繞組204的電流IPR 增大。當監測信號652的電壓指示電流IPR 達到峰值電流IPEAK1 時(例如,當鋸齒波信號SAW達到電壓值V1時),開關控制信號650斷開開關218,以結束充電階段TON 並啟動放電階段TDIS 。在放電階段TDIS ,流經次級繞組206的電流ISE 減小,鋸齒波信號SAW從電壓值V1開始下降。當電流ISE 減小到預設電流值(例如,0安培)時(即當電壓VFB 產生一個負緣時),鋸齒波信號SAW降到電壓值V2。由此,電流控制單元804結束放電階段TDIS 並啟動調整階段TADJ 。在調整階段TADJ ,鋸齒波信號SAW從電壓值V2開始上升。當鋸齒波信號SAW上升到電壓值VSET 時,電流控制單元804導通開關218,進而開始一個新的週期。Similar to the operation of controller 220, sawtooth signal SAW controls the duty cycle of pulse width modulation signal 650. Specifically, in conjunction with FIG. 3 and FIG. 4, in the charging phase T ON , the sawtooth wave signal SAW increases from the voltage value V SET of the reference signal SET, at which time the current I PR flowing through the primary winding 204 increases. . When the voltage of the monitor signal 652 indicates that the current I PR reaches the peak current I PEAK1 (eg, when the sawtooth signal SAW reaches the voltage value V1), the switch control signal 650 turns off the switch 218 to end the charging phase T ON and initiate the discharge phase. T DIS . During the discharge phase T DIS , the current I SE flowing through the secondary winding 206 decreases, and the sawtooth wave signal SAW starts to decrease from the voltage value V1. When the current I SE is reduced to a preset current value (eg, 0 amps) (ie, when the voltage V FB produces a negative edge), the sawtooth signal SAW drops to a voltage value of V2. Thereby, the current control unit 804 ends the discharge phase T DIS and starts the adjustment phase T ADJ . In the adjustment phase T ADJ , the sawtooth signal SAW rises from the voltage value V2. When the sawtooth signal SAW rises to the voltage value V SET , the current control unit 804 turns on the switch 218 to start a new cycle.

有利之處在於,根據方程式(6),電流控制單元804 使得放電階段TDIS 的時間長度與充電階段TON 、放電階段TDIS 及調整階段TADJ 的總的時間長度之間的比值基本保持恒定,因此,流經負載212的電流ILOAD 基本保持恒定。電流控制單元804可以具有其他的結構而不局限於圖8所示的實施例。Advantageous in that, according to equation (6), the current control unit 804 so that the length of the discharge time period T DIS the charging phase T ON, the ratio between the total length of the discharge time period T DIS and adjusting period T ADJ remains substantially constant Therefore, the current I LOAD flowing through the load 212 remains substantially constant. The current control unit 804 can have other configurations and is not limited to the embodiment shown in FIG.

在一個實施例中,電壓控制單元802包含鉗位電路810、電流檢測器808和電壓調節器818。結合圖6所述,當開關218閉合時,輔助繞組208的電壓VAUX 為負值。鉗位電路810與埠FB連接,檢測埠FB的電壓VFB ,並在充電階段TON 將電壓VFB 鉗位在預設電壓值(例如,0伏特),以防止電壓VFB 降到0伏特以下。由此,電流IFB 從電流檢測器808流經鉗位電路810流至埠FB。In one embodiment, voltage control unit 802 includes clamp circuit 810, current detector 808, and voltage regulator 818. As described in connection with FIG. 6, when switch 218 is closed, voltage V AUX of auxiliary winding 208 is negative. The clamp circuit 810 is connected to the 埠FB, detects the voltage V FB of the 埠FB , and clamps the voltage V FB to a preset voltage value (for example, 0 volt) during the charging phase T ON to prevent the voltage V FB from dropping to 0 volts. the following. Thereby, the current I FB flows from the current detector 808 through the clamp circuit 810 to the 埠FB.

在一個實施例中,電流檢測器808包含電流鏡812、電阻814和採樣保持電路816。電流鏡812鏡像電流IFB ,以產生與電流IFB 相等或成比例的電流IM 。電流IM 流經電阻814,因此,電阻814上的電壓VM 也與電流IFB 成比例。根據方程式(8),在充電階段TON ,電流IFB 與輸入電壓VIN 成比例。所以,電壓VM 與輸入電壓VIN 成比例。採樣保持電路816在充電階段TON 對電壓VM 進行採樣,並保持在充電階段TON 的電壓VM 的採樣值以產生保持電壓VH 。因此,在放電階段TDIS 和調整階段TADJ ,儘管電流IFB 降到0安培,保持電壓VH 仍然指示輸入電壓VIN 的值。In one embodiment, current detector 808 includes current mirror 812, resistor 814, and sample and hold circuit 816. Current mirror 812 mirrors current I FB to produce a current I M that is equal or proportional to current I FB . Current I M flows through resistor 814, so voltage V M across resistor 814 is also proportional to current I FB . According to equation (8), during the charging phase T ON , the current I FB is proportional to the input voltage V IN . Therefore, the voltage V M is proportional to the input voltage V IN . Sample and hold circuit 816 samples the voltage V M at the charging period T ON, and the holding voltage V H to produce the holding sampled values of the charging period T ON of the voltage V M. Therefore, during the discharge phase T DIS and the adjustment phase T ADJ , although the current I FB drops to 0 amps, the hold voltage V H still indicates the value of the input voltage V IN .

舉例來說,電壓調節器818包括誤差放大器820、比較器822、比較器823、或閘828、振盪器824和脈寬調變信號產生器826。振盪器824產生鋸齒波信號VSAW 和時脈信 號850(例如,脈衝信號)。誤差放大器820的一個輸入端接收指示輸入電壓VIN 目標值的參考信號VREF ,另一個輸入端接收保持電壓VH 。誤差放大器820放大保持電壓VH 和參考信號VREF 的差值,以產生放大電壓VAMP 。比較器822比較鋸齒波電壓VSAW 和放大電壓VAMP ,產生比較電壓VC1 。比較器823將指示流經電感L1的電流IIND 的監測信號656和指示電流IIND 的峰值的參考信號VPEAK 進行比較,以產生比較電壓VC2 。或閘828接收比較電壓VC1 和比較電壓VC2 ,並由此產生控制信號852。For example, voltage regulator 818 includes error amplifier 820, comparator 822, comparator 823, or gate 828, oscillator 824, and pulse width modulation signal generator 826. The oscillator 824 generates a sawtooth signal V SAW and a clock signal 850 (eg, a pulse signal). One input of the error amplifier 820 receives the reference signal V REF indicating the target value of the input voltage V IN , and the other input receives the hold voltage V H . The error amplifier 820 amplifies the difference between the hold voltage V H and the reference signal V REF to generate an amplified voltage V AMP . The comparator 822 compares the sawtooth wave voltage V SAW with the amplification voltage V AMP to generate a comparison voltage V C1 . Comparator 823 will indicate the peak 656 and the monitoring current I IND signal indicating a reference signal V PEAK current flowing through the inductor L1 I IND compared to generate comparison voltage V C2. The OR gate 828 receives the comparison voltage V C1 and the comparison voltage V C2 and thereby generates a control signal 852.

脈寬調變信號產生器826根據時脈信號850和控制信號852,產生開關控制信號654,以控制開關613,進而調節輸入電壓VIN 。在一個實施例中,脈寬調變信號產生器826根據時脈信號850導通開關613,根據控制信號852斷開開關613。具體而言,在一個實施例中,時脈信號850是頻率基本恒定的脈衝信號。因此,開關613的導通時間和關斷時間也是基本恒定的。此外,指示輸入電壓VIN 的保持電壓VH 決定了開關613的導通時間。因此,開關控制信號654的責任週期由保持電壓VH 決定。例如,若保持電壓VH 大於參考電壓VREF ,則表明輸入電壓VIN 大於目標電壓值(該目標電壓值由參考電壓VREF 指示),開關控制信號654的責任週期減小,以減小輸入電壓VIN 。反之,當保持電壓VH 小於參考電壓VREF ,則表明輸入電壓VIN 小於目標電壓值,開關控制信號654的責任週期增大,以增大輸入電壓VIN 。因此,將輸入電壓VIN 調整到目標電壓值。The pulse width modulation signal generator 826 generates a switch control signal 654 based on the clock signal 850 and the control signal 852 to control the switch 613 to adjust the input voltage V IN . In one embodiment, pulse width modulation signal generator 826 turns on switch 613 based on clock signal 850 and opens switch 613 in accordance with control signal 852. In particular, in one embodiment, the clock signal 850 is a pulse signal having a substantially constant frequency. Therefore, the on-time and off-time of the switch 613 are also substantially constant. Further, the hold voltage V H indicating the input voltage V IN determines the on-time of the switch 613. Therefore, the duty cycle of the switch control signal 654 is determined by the hold voltage V H . For example, if the hold voltage V H is greater than the reference voltage V REF , it indicates that the input voltage V IN is greater than the target voltage value (the target voltage value is indicated by the reference voltage V REF ), and the duty cycle of the switch control signal 654 is reduced to reduce the input. Voltage V IN . Conversely, when the hold voltage V H is less than the reference voltage V REF , it indicates that the input voltage V IN is less than the target voltage value, and the duty cycle of the switch control signal 654 is increased to increase the input voltage V IN . Therefore, the input voltage V IN is adjusted to the target voltage value.

在一個實施例中,流經轉換器604的電感L1的電流 IIND 具有過流保護的功能。例如,如果監測信號656大於參考電壓VPEAK ,則表明電流IIND 大於峰值電流,開關控制信號654斷開開關613。電壓控制單元802可以具有其他的結構,並不局限於圖8所示的實施例。In one embodiment, the current I IND flowing through the inductor L1 of the converter 604 has the function of overcurrent protection. For example, if the monitor signal 656 is greater than the reference voltage V PEAK , then the current I IND is greater than the peak current and the switch control signal 654 is turned off the switch 613. The voltage control unit 802 can have other configurations and is not limited to the embodiment shown in FIG.

圖9所示為根據本發明的一個實施例的負載驅動電路(例如,負載驅動電路600)的操作流程圖900。圖9將結合圖6-圖8進行描述。雖然圖9揭示了具體的步驟,但是這些步驟僅作示例性說明,本發明同樣適用於其他步驟或如圖9所述步驟的一些變化步驟。FIG. 9 shows an operational flow diagram 900 of a load drive circuit (e.g., load drive circuit 600) in accordance with one embodiment of the present invention. Figure 9 will be described in conjunction with Figures 6-8. Although FIG. 9 discloses specific steps, these steps are merely illustrative, and the present invention is equally applicable to other steps or to some of the steps of the steps illustrated in FIG.

在步驟902中,變壓器(例如,變壓器202)工作於多個週期。在一個實施例中,一個週期包含充電階段和放電階段。在另一個實施例中,一個週期包含充電階段、放電階段和調整階段。In step 902, the transformer (e.g., transformer 202) operates for a plurality of cycles. In one embodiment, one cycle includes a charge phase and a discharge phase. In another embodiment, one cycle includes a charge phase, a discharge phase, and an adjustment phase.

在步驟904中,在充電階段,變壓器由輸入電壓供電,流經變壓器初級繞組的電流增大。In step 904, during the charging phase, the transformer is powered by the input voltage and the current flowing through the primary winding of the transformer increases.

在步驟906中,在放電階段,變壓器放電以給負載供電,流經變壓器次級繞組的電流減小。In step 906, during the discharge phase, the transformer discharges to supply power to the load, and the current flowing through the secondary winding of the transformer decreases.

在步驟908中,在充電階段,將與變壓器的輔助繞組連接的控制器埠(例如,埠FB)的電壓鉗位在預設電壓值(例如,0伏特)。In step 908, during the charging phase, the voltage of the controller 埠 (eg, 埠FB) connected to the auxiliary winding of the transformer is clamped at a preset voltage value (eg, 0 volts).

在步驟910中,在充電階段,埠FB接收指示輸入電壓的第一回授信號。在一個實施例中,第一回授信號包含流經埠FB的電流(例如,流經埠FB的電流IFB )。In step 910, during the charging phase, the 埠FB receives a first feedback signal indicative of the input voltage. In one embodiment, the first feedback signal includes a current flowing through 埠FB (eg, current I FB flowing through 埠FB ).

在步驟912中,埠FB接收指示次級繞組電能狀態的第二回授信號。在一個實施例中,第二回授信號包含埠FB 的電壓(例如,埠FB的電壓VFB )。In step 912, the 埠FB receives a second feedback signal indicative of the secondary winding power state. In one embodiment, the second feedback signal includes the voltage of 埠FB (eg, voltage V FB of 埠FB ).

上文具體實施方式和附圖僅為本發明之常用實施例。顯然,在不脫離權利要求書所界定的本發明精神和發明範圍的前提下可以有各種增補、修改和替換。本領域技術人員應該理解,本發明在實際應用中可根據具體的環境和工作要求在不背離發明準則的前提下在形式、結構、佈局、比例、材料、元素、元件及其它方面有所變化。因此,在此披露之實施例僅用於說明而非限制,本發明之範圍由後附權利要求及其合法等同物界定,而不限於此前之描述。The above detailed description and the accompanying drawings are only typical embodiments of the invention. It is apparent that various additions, modifications and substitutions are possible without departing from the spirit and scope of the invention as defined by the appended claims. It should be understood by those skilled in the art that the present invention may be changed in form, structure, arrangement, ratio, material, element, element, and other aspects without departing from the scope of the invention. Therefore, the embodiments disclosed herein are intended to be illustrative and not restrictive, and the scope of the invention is defined by the appended claims

100‧‧‧反馳式轉換器100‧‧‧Reverse converter

104‧‧‧初級繞組104‧‧‧Primary winding

106‧‧‧次級繞組106‧‧‧Secondary winding

108‧‧‧輔助繞組108‧‧‧Auxiliary winding

110‧‧‧二極體110‧‧‧ diode

112‧‧‧負載112‧‧‧load

114‧‧‧誤差放大器114‧‧‧Error amplifier

116‧‧‧光耦合器116‧‧‧Optocoupler

111‧‧‧電流監測電阻111‧‧‧current monitoring resistor

118‧‧‧開關118‧‧‧ switch

120‧‧‧控制器120‧‧‧ Controller

122‧‧‧電容122‧‧‧ Capacitance

124‧‧‧磁芯124‧‧‧ magnetic core

200‧‧‧電力轉換器200‧‧‧Power Converter

202‧‧‧變壓器202‧‧‧Transformer

204‧‧‧初級繞組204‧‧‧Primary winding

206‧‧‧次級繞組206‧‧‧Secondary winding

208‧‧‧輔助繞組208‧‧‧Auxiliary winding

210‧‧‧二極體210‧‧‧ diode

212‧‧‧負載212‧‧‧load

214、216‧‧‧電阻214, 216‧‧‧ resistance

218‧‧‧開關218‧‧‧ switch

220‧‧‧控制器220‧‧‧ Controller

222‧‧‧電容222‧‧‧ Capacitance

224‧‧‧磁芯224‧‧‧ magnetic core

226‧‧‧信號產生器/振盪器226‧‧‧Signal Generator/Oscillator

228‧‧‧鉗位電路228‧‧‧Clamp circuit

230‧‧‧電阻230‧‧‧resistance

302、304‧‧‧電流源302, 304‧‧‧ Current source

306、308‧‧‧開關306, 308‧‧ ‧ switch

310‧‧‧電容310‧‧‧ Capacitance

312‧‧‧NOT閘312‧‧‧NOT gate

314、316‧‧‧比較器314, 316‧‧‧ comparator

318‧‧‧脈衝信號產生器/脈寬調變信號產生器318‧‧‧Pulse signal generator / pulse width modulation signal generator

320‧‧‧控制信號產生器320‧‧‧Control signal generator

500‧‧‧流程圖500‧‧‧flow chart

502、504、506、508‧‧‧步驟502, 504, 506, 508‧ ‧ steps

600‧‧‧負載驅動電路600‧‧‧Load Drive Circuit

602‧‧‧電源602‧‧‧Power supply

603‧‧‧整流器603‧‧‧Rectifier

604‧‧‧轉換器604‧‧‧ converter

605‧‧‧電容605‧‧‧ Capacitance

613‧‧‧開關613‧‧‧ switch

614‧‧‧電阻614‧‧‧resistance

616‧‧‧電阻616‧‧‧resistance

620‧‧‧控制器620‧‧‧ Controller

650‧‧‧開關控制信號650‧‧‧Switch control signal

652‧‧‧監測信號652‧‧‧Monitoring signal

654‧‧‧開關控制信號654‧‧‧Switch control signal

656‧‧‧監測信號656‧‧‧Monitoring signal

802‧‧‧電壓控制單元802‧‧‧Voltage Control Unit

804‧‧‧電流控制單元804‧‧‧ Current Control Unit

808‧‧‧電流檢測器808‧‧‧current detector

810‧‧‧鉗位電路810‧‧‧Clamp circuit

812‧‧‧電流鏡812‧‧‧current mirror

814‧‧‧電阻814‧‧‧resistance

816‧‧‧採樣保持電路816‧‧‧Sampling and holding circuit

818‧‧‧電壓調節器818‧‧‧Voltage regulator

820‧‧‧誤差放大器820‧‧‧Error amplifier

822‧‧‧比較器822‧‧‧ comparator

823‧‧‧比較器823‧‧‧ comparator

824‧‧‧振盪器824‧‧‧Oscillator

826‧‧‧脈寬調變信號產生器826‧‧‧ Pulse width modulation signal generator

828‧‧‧或閘828‧‧‧ or gate

850‧‧‧時脈信號850‧‧‧ clock signal

852‧‧‧控制信號852‧‧‧Control signal

900‧‧‧流程圖900‧‧‧Flowchart

902、904、906、908、910、912‧‧‧步驟902, 904, 906, 908, 910, 912 ‧ ‧ steps

VDD、DRV1、CS1、DRV2、CS2、FB‧‧‧埠VDD, DRV1, CS1, DRV2, CS2, FB‧‧‧埠

以下結合附圖和具體實施例對本發明的技術方法進行詳細的描述,以使本發明的特徵和優點更為明顯。其中:圖1所示為一種習知反馳式轉換器的方塊圖。The technical method of the present invention will be described in detail below in conjunction with the accompanying drawings and specific embodiments to make the features and advantages of the present invention more obvious. Wherein: Figure 1 shows a block diagram of a conventional flyback converter.

圖2所示為根據本發明一實施例的電力轉換器的例示性方塊圖。2 is an illustrative block diagram of a power converter in accordance with an embodiment of the present invention.

圖3所示為圖2中的控制器的架構示意圖。FIG. 3 is a schematic diagram showing the architecture of the controller in FIG. 2.

圖4所示為根據本發明一實施例的電力轉換器接收或產生的信號的例示性波形圖。4 is an illustrative waveform diagram of signals received or generated by a power converter in accordance with an embodiment of the present invention.

圖5示為根據本發明一實施例的控制變壓器的例示性方法流程圖。FIG. 5 is a flow chart showing an exemplary method of controlling a transformer in accordance with an embodiment of the present invention.

圖6所示為根據本發明的一個實施例的負載驅動電路的示意圖。Figure 6 is a schematic illustration of a load drive circuit in accordance with one embodiment of the present invention.

圖7所示為根據本發明的一個實施例示於圖6之負載 驅動電路所接收或產生的信號的波形圖。Figure 7 shows the load shown in Figure 6 in accordance with one embodiment of the present invention. A waveform diagram of a signal received or generated by a driver circuit.

圖8所示為根據本發明的一個實施例的控制器的結構示意圖。Figure 8 is a block diagram showing the structure of a controller in accordance with one embodiment of the present invention.

圖9所示為根據本發明的一個實施例的負載驅動電路的操作流程圖。Figure 9 is a flow chart showing the operation of a load driving circuit in accordance with one embodiment of the present invention.

600‧‧‧負載驅動電路600‧‧‧Load Drive Circuit

602‧‧‧電源602‧‧‧Power supply

603‧‧‧整流器603‧‧‧Rectifier

604‧‧‧轉換器604‧‧‧ converter

605‧‧‧電容605‧‧‧ Capacitance

613‧‧‧開關613‧‧‧ switch

614‧‧‧電阻614‧‧‧resistance

616‧‧‧電阻616‧‧‧resistance

620‧‧‧控制器620‧‧‧ Controller

650‧‧‧開關控制信號650‧‧‧Switch control signal

652‧‧‧監測信號652‧‧‧Monitoring signal

654‧‧‧開關控制信號654‧‧‧Switch control signal

656‧‧‧監測信號656‧‧‧Monitoring signal

Claims (24)

一種負載驅動電路,包括:一變壓器,包括接收一輸入電壓的一初級繞組與連接於一負載的一次級繞組,該變壓器工作於多個週期,其中,該多個週期中的一個週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流經該初級繞組的一電流增大,在該放電階段,該變壓器放電以對該負載供電,且流過該次級繞組的一電流減小;以及一控制器,耦接至該變壓器,包括一埠,其中,在該充電階段,該埠接收指示該輸入電壓的一第一回授信號,且其中,在該放電階段,該埠接收指示該次級繞組之一電能狀態的一第二回授信號,其中,該控制器根據該第一回授信號產生一第一控制信號,以調節該輸入電壓,且根據該第二回授信號產生一第二控制信號,以調節流經該負載的一電流。 A load driving circuit comprising: a transformer comprising a primary winding receiving an input voltage and a primary winding connected to a load, the transformer operating in a plurality of cycles, wherein one of the plurality of cycles comprises a charging a phase and a discharge phase, in which the transformer is powered by the input voltage, and a current flowing through the primary winding is increased, during which the transformer discharges to supply power to the load, and flows through the current a current reduction of the stage winding; and a controller coupled to the transformer, including a turn, wherein the pick-up receives a first feedback signal indicative of the input voltage during the charging phase, and wherein a second feedback signal indicating a power state of the one of the secondary windings, wherein the controller generates a first control signal according to the first feedback signal to adjust the input voltage, and The second feedback signal generates a second control signal to regulate a current flowing through the load. 如申請專利範圍第1項的負載驅動電路,進一步包括:一轉換器,耦接於一電源和該初級繞組之間,該轉換器將該電源所產生的一輸入交流電壓轉換成該輸入電壓,並根據該第一控制信號調節該輸入電壓。 The load driving circuit of claim 1, further comprising: a converter coupled between a power source and the primary winding, the converter converting an input AC voltage generated by the power source into the input voltage, And adjusting the input voltage according to the first control signal. 如申請專利範圍第1項的負載驅動電路,其中,該變壓器進一步包括: 一輔助繞組,耦接至該埠,在該充電階段,該輔助繞組上的一電壓與該初級繞組上的該輸入電壓成比例。 The load driving circuit of claim 1, wherein the transformer further comprises: An auxiliary winding coupled to the turns, a voltage on the auxiliary winding being proportional to the input voltage on the primary winding during the charging phase. 如申請專利範圍第3項的負載驅動電路,進一步包括:一電阻,耦接於該輔助繞組和該埠之間,在該充電階段,該控制器將該埠的一電壓鉗位在一預設電壓值,並且在該充電階段,流經該電阻的一電流值與該輸入電壓成比例。 The load driving circuit of claim 3, further comprising: a resistor coupled between the auxiliary winding and the crucible, wherein the controller clamps a voltage of the crucible to a preset during the charging phase A voltage value, and during the charging phase, a current value flowing through the resistor is proportional to the input voltage. 如申請專利範圍第1項的負載驅動電路,其中,該變壓器還包括:一輔助繞組,耦接至該埠,在該放電階段,該輔助繞組的一電壓指示流過該次級繞組的該電流是否降到一預設值。 The load drive circuit of claim 1, wherein the transformer further comprises: an auxiliary winding coupled to the 埠, during the discharge phase, a voltage of the auxiliary winding indicates the current flowing through the secondary winding Whether it falls to a preset value. 如申請專利範圍第1項的負載驅動電路,其中,該第一回授信號包括流經該埠的一電流,該第二回授信號包括該埠上的一電壓。 The load driving circuit of claim 1, wherein the first feedback signal comprises a current flowing through the crucible, and the second feedback signal comprises a voltage on the crucible. 如申請專利範圍第1項的負載驅動電路,其中,該控制器進一步包括:一電流鏡,耦接至該埠,在該充電階段鏡像流經該埠的一電流,以提供流經一電阻的一電流;以及 一採樣保持電路,耦接至該電流鏡,採樣並保持該電阻上的電壓,以產生指示該輸入電壓的一保持信號。 The load driving circuit of claim 1, wherein the controller further comprises: a current mirror coupled to the cymbal, wherein a current flowing through the cymbal is mirrored during the charging phase to provide a current flowing through the resistor a current; A sample and hold circuit is coupled to the current mirror to sample and maintain a voltage across the resistor to generate a hold signal indicative of the input voltage. 如申請專利範圍第1項的負載驅動電路,其中,該一個週期還包括一調整階段,該第二控制信號使該放電階段的一時間長度與該充電階段、該放電階段和該調整階段的一總時間長度之間的一比值保持恒定,以調整流經該負載的該電流。 The load driving circuit of claim 1, wherein the one cycle further comprises an adjustment phase, the second control signal causing a length of the discharge phase and the charging phase, the discharging phase, and the adjusting phase A ratio between the total length of time remains constant to adjust the current flowing through the load. 如申請專利範圍第8項的負載驅動電路,其中,該控制器進一步包括:一電流控制單元,當該第二回授信號指示流經該次級繞組的該電流降到一預設電流值時,該電流控制單元結束該放電階段並啟動該調整階段。 The load drive circuit of claim 8, wherein the controller further comprises: a current control unit, when the second feedback signal indicates that the current flowing through the secondary winding drops to a predetermined current value The current control unit ends the discharge phase and initiates the adjustment phase. 如申請專利範圍第8項的負載驅動電路,其中,該控制器進一步包括:一信號產生器,產生一鋸齒波信號,其中,在該充電階段,該鋸齒波信號從一預設參考電壓值上升到一第一電壓值,且在該放電階段,該鋸齒波信號從該第一電壓值下降到一第二電壓值,且在該調整階段,該鋸齒波信號從該第二電壓值上升到該預設參考電壓值。 The load driving circuit of claim 8, wherein the controller further comprises: a signal generator for generating a sawtooth wave signal, wherein the sawtooth wave signal rises from a predetermined reference voltage value during the charging phase Go to a first voltage value, and in the discharging phase, the sawtooth wave signal drops from the first voltage value to a second voltage value, and in the adjusting phase, the sawtooth wave signal rises from the second voltage value to the The preset reference voltage value. 如申請專利範圍第10項的負載驅動電路,進一步包括:一開關,串聯耦接至該初級繞組,其中,在該鋸齒波信號從該預設參考電壓值上升到該第一電壓值的過程中,該控制器導通該開關,且其中,當流經該初級繞組的該電流增大到一預設峰值電流時,該控制器斷開該開關。 The load driving circuit of claim 10, further comprising: a switch coupled in series to the primary winding, wherein the sawtooth wave signal rises from the preset reference voltage value to the first voltage value The controller turns on the switch, and wherein the controller turns off the switch when the current flowing through the primary winding increases to a predetermined peak current. 如申請專利範圍第8項的負載驅動電路,進一步包括:一開關,串聯耦接至該初級繞組,其中,該控制器在該充電階段導通該開關,在該放電階段和該調節階段斷開該開關。 The load driving circuit of claim 8 , further comprising: a switch coupled in series to the primary winding, wherein the controller turns on the switch during the charging phase, and disconnects the discharging phase and the adjusting phase switch. 一種電源轉換器,包括:一變壓器,包括接收一輸入電壓的一初級繞組、連接至一負載的一次級繞組,以及一輔助繞組,該變壓器工作於多個週期,其中,該多個週期中的一個週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流過該初級繞組的一電流增大,且在該放電階段,該變壓器放電以對該負載供電,且流過該次級繞組的一電流減小;一對電阻,相互串聯且該對電阻連接至該輔助繞組;以及一控制器,包括一埠,該埠連接於該對電阻之間的一共同節點,在該充電階段,該控制器將該共同節點上 的一電壓鉗位在一預設電壓值,其中,在該充電階段,流經該埠的一電流與該輸入電壓成比例;在該放電階段,該埠的一電壓指示流經該次級繞組的該電流是否下降到一預設值,該控制器進一步包括:一電流檢測器,耦接至該埠,在該充電階段,該電流檢測器鏡像流經該埠的該電流,以提供流經一第三電阻的一電流,該電流檢測器透過採樣保持該第三電阻上的一電壓來提供一保持信號,其中,該控制器基於該保持信號產生一控制信號,以調節該輸入電壓。 A power converter comprising: a transformer comprising a primary winding receiving an input voltage, a primary winding connected to a load, and an auxiliary winding, the transformer operating in a plurality of cycles, wherein the plurality of cycles One cycle includes a charging phase and a discharging phase, in which the transformer is powered by the input voltage, and a current flowing through the primary winding increases, and during the discharging phase, the transformer discharges to power the load And a current flowing through the secondary winding is reduced; a pair of resistors connected in series with each other and the pair of resistors connected to the auxiliary winding; and a controller including a turn connected to the pair of resistors a common node, in the charging phase, the controller is on the common node a voltage clamped to a predetermined voltage value, wherein during the charging phase, a current flowing through the chirp is proportional to the input voltage; during the discharging phase, a voltage indicative of the chirp flows through the secondary winding Whether the current drops to a predetermined value, the controller further includes: a current detector coupled to the 埠, during the charging phase, the current detector mirrors the current flowing through the , to provide flow through A current of a third resistor, the current detector provides a hold signal by sampling and maintaining a voltage on the third resistor, wherein the controller generates a control signal based on the hold signal to adjust the input voltage. 如申請專利範圍第13項的電源轉換器,其中,在該放電階段,該對電阻將該輔助繞組上的一電壓分壓,以將該分壓電壓提供給該埠。 The power converter of claim 13, wherein in the discharging phase, the pair of resistors divides a voltage on the auxiliary winding to supply the divided voltage to the 埠. 如申請專利範圍第13項的電源轉換器,其中,該對電阻包括連接於該輔助繞組的一第一電阻和連接於具有一參考電壓的一節點的一第二電阻,且流經該埠的該電流還流經該次級繞組和該第一電阻。 The power converter of claim 13, wherein the pair of resistors comprises a first resistor connected to the auxiliary winding and a second resistor connected to a node having a reference voltage, and flowing through the anode The current also flows through the secondary winding and the first resistor. 如申請專利範圍第13項的電源轉換器,其中,該一個週期還包括一調整階段,該控制器使該放電階段的一時間長度與該充電階段、該放電階段和該調整階段的一總時間長度之間的一比值保持恒定,以調整流經該負載的一電流。 The power converter of claim 13, wherein the one cycle further comprises an adjustment phase, the controller causing a length of the discharge phase and the charging phase, the discharging phase, and a total time of the adjusting phase A ratio between the lengths is held constant to adjust a current flowing through the load. 如申請專利範圍第16項的電源轉換器,其中,控制器進一步包括:一信號產生器,產生一鋸齒波信號,其中,在該充電階段,該鋸齒波信號從一預設參考電壓值上升到一第 一電壓值,且在該放電階段,該鋸齒波信號從該第一電壓值下降到一第二電壓值,且在該調整階段,該鋸齒波信號從該第二電壓值上升到該預設參考電壓值。 The power converter of claim 16, wherein the controller further comprises: a signal generator for generating a sawtooth wave signal, wherein during the charging phase, the sawtooth wave signal rises from a predetermined reference voltage value to One a voltage value, and in the discharging phase, the sawtooth wave signal drops from the first voltage value to a second voltage value, and in the adjusting phase, the sawtooth wave signal rises from the second voltage value to the preset reference Voltage value. 如申請專利範圍第17項的電源轉換器,進一步包括:一開關,串聯耦接至該初級繞組,其中,在該鋸齒波信號從該預設參考電壓值上升到該第一電壓值的過程中,該控制器導通該開關,當流經該初級繞組的該電流增加到一預設峰值電流時,該控制器斷開該開關。 The power converter of claim 17, further comprising: a switch coupled in series to the primary winding, wherein the sawtooth signal rises from the predetermined reference voltage value to the first voltage value The controller turns on the switch, and when the current flowing through the primary winding increases to a predetermined peak current, the controller turns off the switch. 如申請專利範圍第16項的電源轉換器,進一步包括:一開關,串聯耦接至該初級繞組,其中,在該充電階段,該控制器導通該開關,且其中,在該放電階段和該調整階段,該控制器斷開該開關。 The power converter of claim 16, further comprising: a switch coupled in series to the primary winding, wherein in the charging phase, the controller turns on the switch, and wherein, in the discharging phase and the adjusting At the stage, the controller turns off the switch. 一種控制器,控制為一負載供電之一變壓器,包括:一第一埠,產生一第一控制信號,以調節該變壓器的一輸入電壓;一第二埠,產生一第二控制信號,以調節流經該負載的一電流,並使該變壓器工作於多個週期,其中,該多個週期中的一個週期包括一充電階段和一放電階段,在該充電階段,該變壓器由該輸入電壓供電,且流經該初級繞組的一電流增大;在該放電階段,該變壓器放電以對該負載供電,且流經該次級繞組的一電流減小;以及一第三埠,耦接至該變壓器的一輔助繞組,在該充電階段,該第三埠接收指示該輸入電壓的一第一回授信 號;在該放電階段,該第三埠接收指示該次級繞組的一電能狀態的一第二回授信號;其中,該控制器根據該第一回授信號產生該第一控制信號,根據該第二回授信號產生該第二控制信號,且其中,該控制器進一步包括:一電流鏡,耦接至該第三埠,在該充電階段,該電流鏡鏡像流經該第三埠的一電流,以提供流經一電阻的一電流;以及一採樣保持電路,耦接至該電流鏡,採樣並保持該電阻上的一電壓,以產生指示該輸入電壓的一保持信號。 A controller for controlling a load to supply a load, comprising: a first turn generating a first control signal to adjust an input voltage of the transformer; and a second turn generating a second control signal to adjust a current flowing through the load and operating the transformer in a plurality of cycles, wherein one of the plurality of cycles includes a charging phase and a discharging phase, wherein the transformer is powered by the input voltage And a current flowing through the primary winding increases; during the discharging phase, the transformer discharges to supply power to the load, and a current flowing through the secondary winding decreases; and a third turn is coupled to the transformer An auxiliary winding, in the charging phase, the third chirp receives a first backhaul indicating the input voltage a third feedback signal indicating a power state of the secondary winding during the discharging phase; wherein the controller generates the first control signal according to the first feedback signal, according to the The second feedback signal generates the second control signal, and wherein the controller further comprises: a current mirror coupled to the third port, wherein the current mirror image flows through the third port during the charging phase a current to provide a current through a resistor; and a sample and hold circuit coupled to the current mirror to sample and maintain a voltage across the resistor to generate a hold signal indicative of the input voltage. 如申請專利範圍第20項的控制器,其中,該第一回授信號包括流經該第三埠的該電流,該第二回授信號包括該第三埠上的一電壓。 The controller of claim 20, wherein the first feedback signal comprises the current flowing through the third turn, and the second feedback signal comprises a voltage on the third turn. 如申請專利範圍第20項的控制器,其中,該一個週期還包括一調整階段,該控制器使該放電階段的一時間長度與該充電階段、該放電階段和該調整階段的一總時間長度之間的一比值保持恒定,以調整流經該負載的該電流。 The controller of claim 20, wherein the one cycle further comprises an adjustment phase, the controller causing a length of the discharge phase and the total duration of the charging phase, the discharging phase, and the adjusting phase A ratio between them remains constant to adjust the current flowing through the load. 如申請專利範圍第22項的控制器,進一步包括:一信號產生器,產生一鋸齒波信號,其中,在該充電階段,該鋸齒波信號從一預設參考電壓值上升到一第一電壓值,且在該放電階段,該鋸齒波信號從該第一電壓值下降到一第二電壓值,且在該調整階段,該鋸齒波信號從該第二電壓值上升到該預設參考電壓值。 The controller of claim 22, further comprising: a signal generator for generating a sawtooth wave signal, wherein the sawtooth wave signal rises from a predetermined reference voltage value to a first voltage value during the charging phase And in the discharging phase, the sawtooth wave signal is decreased from the first voltage value to a second voltage value, and in the adjusting phase, the sawtooth wave signal is raised from the second voltage value to the preset reference voltage value. 如申請專利範圍第20項的控制器,進一步包括:一鉗位電路,在該充電階段,該鉗位電路將該第三埠上的一電壓鉗位在一預設電壓值。The controller of claim 20, further comprising: a clamp circuit, wherein the clamp circuit clamps a voltage on the third turn to a predetermined voltage value.
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