Patent Application
20210296994
The present disclosure relates to a controller, a power converter including the controller, and a method for controlling the power converter.
A power converter converts an input voltage into an output voltage and provides an output signal to a load. For example, the power converter may provide an output current to one or more light emitting diode (LED) strings each including a plurality of LEDs and adjust a magnitude of a current flowing through the LEDs to obtain a desirable level of brightness. When an overshoot of the current flowing through the LEDs occurs, the overshoot may produce a brief interval during which light emitted from the LEDs is undesirably bright, such as by producing a flash of light. Subsequently, when the current flowing through the LEDs decreases at a rate greater than a certain value, this change may produce a flickering of light.
Embodiments of the present application relate to a controller, a power converter including the controller, and a method for controlling the power converter.
In an embodiment, a controller for a power converter includes a first input node receiving a sensing signal that indicates an output signal of the power converter, a second input node receiving an external signal that indicates a target value for a load, and a feedback signal generator generating a first feedback signal in response to the sensing signal and the external signal. The feedback signal generator uses a first feedback path with a first gain value when the power converter operates in a first mode and uses a second feedback path when the power converter operates in a second mode. The feedback signal generator includes a gain adjusting circuit configured to decrease a gain value of the second feedback path from the first gain value to a second gain value at a plurality of times when the power converter operates in the second mode.
In an embodiment, a power converter includes a first side including a first controller and a first portion of an opto-coupler, the first controller controlling a switching operation of a switching device, and a second side including a second controller and a second portion of the opto-coupler. The second controller includes a feedback signal generator configured to generate a first feedback signal in response to a sensing signal and an external signal, the sensing signal indicting an output signal of the power converter, the external signal indicating a target value for a load. The feedback signal generator uses a first feedback path with a first gain value when the power converter operates in a first mode and uses a second feedback path when the power converter operates in a second mode. The feedback signal generator includes a gain adjusting circuit configured to decrease a gain value of the second feedback path from the first gain value to a second gain value at a plurality of times when the power converter operates in the second mode. The second controller further includes a buffer configured to generate an opto-coupler signal in response to the first feedback signal and provide the opto-coupler signal to the second portion of the opto-coupler.
In an embodiment, a method for controlling a power converter includes generating a first feedback signal in response to a sensing signal and an external signal by a feedback signal generator, the feedback signal generator using a first feedback path with a first gain value when the power converter operates in a first mode and using a second feedback path when the power converter operates in a second mode. The sensing signal indicates an output signal of the power converter, and the external signal indicates a target value for a load. The method further includes decreasing a gain value of the second feedback path from the first gain value to a second gain value at a plurality of times when the power converter operates in the second mode.
Embodiments of the present application relate to a controller for controlling a power converter, a power converter including the controller, and a method for controlling the power converter.
In an embodiment, a controller includes a feedback signal generator using a first feedback path with a first gain value when the power converter operates in a first mode (e.g., a startup mode or a low-gain mode) and using a second feedback path when the power converter operates in a second mode (e.g., a gain adjusting mode). The feedback signal generator includes a gain adjusting circuit that decreases a gain value of the second feedback path from the first gain value to a second gain value at a plurality of times when the power converter operates in the gain adjusting mode. As a result, a power converter including the controller according to an embodiment may prevent an overshoot of a string current, or a flickering, or both when the power converter operates in the gain adjusting mode.
In an embodiment, the feedback signal generator further includes a voltage copier circuit that is coupled to the gain adjusting circuit at a specific node. The voltage copier circuit generates a second feedback signal in response to the first feedback signal and provide the second feedback signal to the node when the power converter operates in the gain adjusting mode. As a result, a power converter including the controller according to an embodiment may suppress fluctuations in the first feedback signal when the gain value of the second feedback path decreases at the plurality of times.
In an embodiment, the first feedback path of the feedback signal generator includes an amplifier and a capacitor having a relatively small capacitance value when the power operates in the startup mode. As a result, the first feedback path has a relatively high gain value and a relatively high response speed. Accordingly, a power converter including the controller according to an embodiment may prevent an overshoot of a string current, or a flickering, or both when the power converter operates in the startup mode.
A detailed description of embodiments is provided below along with accompanying figures. The scope of this disclosure is limited only by the claims and encompasses numerous alternatives, modifications and equivalents. Although steps of various processes are presented in a given order, embodiments are not necessarily limited to being performed in the listed order. In some embodiments, certain operations may be performed simultaneously, in an order other than the described order, or not performed at all.
Numerous specific details are set forth in the following description. These details are provided to promote a thorough understanding of the scope of this disclosure by way of specific examples, and embodiments may be practiced according to the claims without some of these specific details. Accordingly, the specific embodiments of this disclosure are illustrative, and are not intended to be exclusive or limiting. For the purpose of clarity, technical material that is known in the technical fields related to this disclosure has not been described in detail so that the disclosure is not unnecessarily obscured.
The power converter 100 may adjust a value of the output signal OS using a feedback control based on information on the output signal OS and a target value for the load 160. In an embodiment, the power converter 100 may be a flyback converter.
The power converter 100 may be controlled by one or more controllers 120. In an embodiment, a first one of the controllers 120 is disposed on a first side (e.g., a primary side) and controls a switching operation of a switching device. In such an embodiment, a second one of the controllers 120 is disposed on a second side (e.g., a secondary side) and performs a feedback operation in response to a sensing signal (e.g., a sensing signal VCS in
The controllers 120 may be integrated in one or more semiconductor chips. These semiconductor chips may be packaged by themselves or together with one or more other semiconductor chips.
The load 160 may include one or more integrated chips (ICs). In an embodiment, the output signal OS is used to supply power to one or more of a Central Processing Unit (CPU), a Graphics Processing Unit (GPU), an integrated memory circuit, a battery charger, a light emitting diode (LED), or other types of electrical load.
A first side (e.g., a primary side) of the flyback converter 200 includes a first controller (e.g., a primary side controller) 210, a first capacitor 204, a primary coil 206, a second capacitor 272, and a first portion of an opto-coupler 218. In an embodiment, the first controller 210 includes a switch device (not shown) and generates a drive signal (not shown) to turn on or off the switch device. For example, during a first portion (e.g., an on-time duration) of a cycle of the drive signal, the first controller 210 turns on the switch device. This causes energy to be supplied from the input voltage VIN to the primary coil 206, where it is stored as a magnetic flux. During the remaining portion (e.g., an off-time duration) of the cycle of the drive signal, the first controller 210 turns off the switch device. In response, the energy stored in the primary coil 206 is transferred into a secondary coil 208, causing a current to flow in the secondary coil 208 and a voltage to develop across end terminals of the secondary coil 208. In the above-described embodiment, the first controller 210 includes the switch device, but embodiments of the present disclosure are not limited thereto. For example, the switch device may be disposed outside the first controller 210.
The primary side controller 210 may further include a Power Factor Correction (PFC) circuit (not shown), which performs a PFC operation to present a PF close to 1 (e.g., 0.98) to the AC power supply by keeping the phase of a current drawn from the AC power supply close to the phase of the voltage of the AC power supply.
The second capacitor 272 has a first end coupled to a first node NFB and a second end coupled to a ground. The first portion of the opto-coupler 218 is coupled to the second capacitor 272 in parallel.
A second side (e.g., a secondary side) of the flyback converter 200 includes the secondary coil 208, a diode 212, an output capacitor 214, a sensing resistor 202, a second controller (e.g., a secondary side controller) 220, a second portion of the opto-coupler 218, and a third capacitor 216.
The diode 212 has a cathode coupled to a first end of the output capacitor 214 at an output node No. A second end of the output capacitor 214 is coupled to a ground.
The LED string 260 is coupled between the output node No and the sensing resistor 202. The LED string 260 includes one or more LEDs coupled to together either in series, in parallel, or in combinations thereof. Each of the plurality of LEDs converts a current passing the LED into light. A brightness of light emitted by the LEDs varies with a magnitude of the current flowing through the LED string 260. Although the LED string 260 shown in
The sensing resistor 202 generates a sensing signal VCS based on a string current ILED flowing through the LED string 260. For example, the sensing resistor 202 may have a first end coupled to the LED string 260 and a second end coupled to the ground, and generate the sensing signal VCS having a value proportional to the magnitude of the string current ILED flowing through the LED string 260.
The secondary side controller 220 receives the sensing signal VCS and an external dimming signal VDIM_EXT and provides a feedback detection signal (e.g., an opto-coupler signal) VPC to the second portion of the opto-coupler 218. The second portion of the opto-coupler 218 recieves the opto-coupler signal VPC and converts the received opto-coupler signal VPC into light. For example, the second portion of the opto-coupler 218 includes a light-emitting diode (LED).
The first portion of the opto-coupler 218, which is included in the primary side of the flyback converter 200, detects the converted light and adjusts an amount of a feedback current IFB flowing through the first portion of the opto-coupler 218 in response to the detected light. For example, when a value of the opto-coupler signal VPC decreases, the amount of light converted by the second portion of the opto-coupler 218 is reduced to decrese the mangitude of the feedback current IFB. Because a substantially constant current flows from the primary side controller 210 into the first node NFB, when the feedback current IFB flowing from the first node NFB into the first portion of the opto-coupler 218 decreases, a current flowing from the first node NFB into the second capacitor 272 increases. As a result, a feedback voltage VFB at the first end of the second capacitor 272 increases, and the primary side controller 210 may adjust a duty cycle of the switching device based on the feedback voltage VFB.
The secondary side controller (SSC) 220 includes a gain adjusting circuit 230 that gradually adjusts its gain value when the power converter 200 operates in a specific mode. In an embodiment, the gain adjusting circuit 230 adjusts a gain value of a feedback path included in the SSC 220 from a first value to a second value at a plurality of times, rather than changing the gain value from the first value to the second value at once, when the power converter 200 operates in a gain adjusting mode.
The secondary side controller (SSC) 220 generates a reference signal (e.g., a reference signal VCS_REF in
The timer circuit 322 generates a soft-start end signal SSEND and provides the soft-start end signal SSEND to the first switching device 342. In an embodiment, the timer circuit 322 asserts the soft-start end signal SSEND a given time interval (e.g., a few hundred milliseconds) after a power converter including the SSC 320 has started to operate in a start-up mode, and provides the asserted soft-start end signal SSEND to turn on the first switching device 342. For example, the timer circuit 322 includes a counter circuit including a T Flip-flop, the counter circuit starting to increase its value when the power converter starts to operate in the start-up mode and asserting the soft-start end signal SSEND at a specific time (e.g., a third time t3 in
When the first switching device 342 is turned on in response to the asserted soft-start end signal SSEND, the soft-input generator 324 receives an external dimming signal VDIM_EXT through a first input node (e.g., a dimming pin) Ext_DIM and generates an output signal in response to the external dimming signal VDIM_EXT. In an embodiment, the soft-input generator 324 gradually increases a value of the output signal until the value of the output signal reaches a given value corresponding to that of the external dimming signal VDIM_INT. For example, the soft-input generator 324 includes a resistor and a capacitor coupled in series to each other and generates the output signal at a node between the resistor and the capacitor.
The arithmetic circuit 326 receives the external dimming signal VDIM_EXT and an internal dimming signal VDIM_INT and performs an arithmetic operation to generate a reference signal VCS_REF. In an embodiment the arithmetic circuit 326 is an adder circuit.
The feedback signal generator 380 generates the first feedback signal VCOMP_INT in response to the reference signal (e.g., a reference voltage) VCS_REF and a sensing signal (e.g., a sensing voltage) VCS. The feedback signal generator 380 uses a first feedback path 382 when the power converter operates in a first mode (e.g., a startup mode or a low-gain mode), the first feedback path 382 including the amplifier 328 and the first capacitor 332. The feedback signal generator 380 uses a second feedback path 384 when the power converter operates in a second mode (e.g., a gain adjusting mode), the second feedback path 384 including the amplifier 328, the first capacitor 332, the gain adjusting circuit 330, the voltage copier circuit 340, and a second node N2 coupled to the second capacitor 316. The feedback signal generator 380 uses a third feedback path 386 when the power converter operates in a third mode (e.g., a high-gain mode), the third feedback path 386 including the amplifier 328, the first capacitor 332, the gain adjusting circuit 330, and the second node N2 coupled to the second capacitor 316.
The amplifier 328 of the feedback signal generator 380 receives the reference signal VCS_REF and the sensing signal VCS and generates a first feedback signal VCOMP_INT indicating a difference between values of the reference signal VCS_REF and the sensing signal VCS. For example, the amplifier 328 receives the sensing signal VCS through a second input node (e.g., a sensing pin) CS. In an embodiment, the amplifier 328 is a transconductance amplifier and generates a current having a magnitude that is proportional to a difference between levels of the reference voltage VCS_REF and the sensing voltage VCS.
The gain adjusting circuit 330 adjusts a gain value of the second feedback path 384 of the SSC 320 at a plurality of times when the power converter operates in the gain adjusting mode. In an embodiment, the gain adjusting circuit 330 decreases its total resistance value a given number of times to decrease the gain value of the second feedback path 384. For example, the gain adjusting circuit 330 may include a plurality of parallel paths, one of the plurality of paths including a first switching element, the remaining ones of the plurality of paths including a second plurality of switching elements and a plurality of resistors, each of the second plurality of switching elements being coupled to a respective one of the plurality of resistors in series, and the second plurality of switching elements and the first switching element of the gain adjusting circuit 330 may be sequentially turned on to decrease a total resistance value of the gain adjusting circuit 330.
The voltage copier circuit 340 receives the first feedback signal VCOMP_INT and generates a second feedback signal VCOMP in response to the first feedback signal VCOMP_INT. In an embodiment, the voltage copier circuit 340 copies the first feedback signal VCOMP_INT and provides an averaged version of the first feedback signal VCOMP_INT to a second node N2 as the second feedback signal VCOMP, when the power converter operates in the gain adjusting mode. For example, the voltage copier circuit 340 includes a second switching device 344, a second buffer 338 and a filter 336.
The first capacitor 332 has a capacitance value that is relatively small. In an embodiment, the capacitance value of the first capacitor 332 is equal to or less than 10 pF. As a result, the first feedback path 382 including the transconductance amplifier 328 and the first capacitor 332 may have a relatively high gain value, leading to a relatively fast response speed.
The second capacitor 316 has a capacitance value that is significantly greater than that of the first capacitor 332. In an embodiment, the capacitance value of the second capacitor 316 is at least 10000 times greater than that of the first capacitor 332. For example, the capacitance value of the second capacitor 316 is in a range from 100 nF to 5 μf. As a result, the third feedback path 386 including the transconductance amplifier 328, the first capacitor 332, the gain adjusting circuit 330, and the second node N2 coupled to the second capacitor 316 may have a relatively low gain value, leading to a relatively low response speed suitable for performing power factor correction.
The first buffer 334 generates a feedback detection signal (e.g., an opto-coupler signal) VPC in response to the first feedback signal VCOMP_INT. In an embodiment, the first buffer 334 has a unity gain and generates the opto-coupler signal VPC having substantially the same value as that of the first feedback signal VCOMP_INT.
The portion of the opto-coupler 318 receives the opto-coupler signal VPC and converts the received opto-coupler signal VPC into light. In an embodiment, the first portion of the opto-coupler 318 includes light-emitting diode (LED).
The gain adjusting circuit 430 includes a plurality of parallel paths 442-1 to 442-n. First to (n−1)th paths 442-1 to 442-(n−1) include a plurality of resistors R1 to Rn-1 and first to (n−1)th switching elements 446-1 to 446-(n−1), respectively, and an nth path 442-n includes an nth switching element 446-n. In an embodiment, the number of the plurality of parallel paths 442-1 to 442-n are in a range from 4 to 40, or from 12 to 32. For example, the number n of the plurality of parallel paths 442-1 to 442-n is twelve, and the resistance values of the plurality of resistors R1 to R11 are 10 MΩ, 1 MΩ, 500 KΩ, 300 KΩ, 100 KΩ, 50 KΩ, 30 KΩ, 10 KΩ, 3 KΩ, 1 KΩ, and 500Ω, respectively.
The plurality of switching elements 446-1 to 446-n may be turned on sequentially in response to the plurality of switching signals S1 to Sn, thereby decreasing the total resistance value of the gain adjusting circuit 430. In an embodiment, a demultiplexer (not shown) provides the plurality of switching signals S1 to Sn to the switching elements 446-1 to 446-n, respectively, at regular time intervals when a power converter (e.g., the flyback converter 200 in
An operation of the SSC 320 in
Referring to
A string current (e.g., the string current ILED in
When the power converter including the SSC 320 operates in the startup mode during a first time interval T1 between the first time t1 and a second time t2, the soft-input generator 324, the gain adjusting circuit 330, and the voltage copier circuit 340 are disabled. As a result, the SSC 320 uses the first feedback path 382 including the transconductance amplifier 328 and the first capacitor 332. The capacitance value of the first capacitor 332 is relatively small, and thus the first feedback path 382 of the SSC 320 may have a relatively high gain value, leading to a relatively high bandwidth of a feedback loop of the power converter that includes the first feedback path 382 of the SSC 320, the feedback loop performing current regulation and power factor correction (PFC). For example, the capacitance value of the first capacitor 332 may be equal to or less than 10 pF. In an embodiment, the feedback loop speed or the bandwidth of the feedback loop may be sufficiently high to prevent an overshoot of the string current and a flickering during the first time interval T1. For example, the bandwidth of the feedback loop may be higher than 10 kHz.
At the second time t2, the power converter including the SSC 320 starts to operate in a second mode (e.g., a gain adjusting mode), and the gain adjusting circuit 330 and the voltage copier circuit 340 are activated in response to a gain control signal GC. In an embodiment, a timer circuit (not shown) in the SSC 320 includes a counter circuit that starts to increase its value at the first time t1 when the power converter starts to operate in the start-up mode and asserts the gain control signal GC at the second time t2 when the value reaches a first given value. The counter circuit further increases the value and de-asserts the gain control signal GC at a third time t3 when the value reaches a second given value greater than the first given value. As a result, the SSC 320 uses the second feedback path 384 including the transconductance amplifier 328, the first capacitor 332, the gain adjusting circuit 330, the voltage copier circuit 340, and the second node N2 coupled to the second capacitor 316.
When the power converter including the SSC 320 operates in the gain adjusting mode during a second time interval T2 between the second time t2 and the third time t3, the gain adjusting circuit 330 decreases the gain value of the second feedback path 384 at a plurality of times. In an embodiment, the gain adjusting circuit 330 includes a plurality of resistors coupled in parallel, and a total resistance value of the gain adjusting circuit 330 decreases from a maximum value to a minimum value. As the total resistance value of the gain adjusting circuit 330 decreases during the second time interval T2, an amount of a first portion of the output current from the transconductance amplifier 328 flowing into the second capacitor 316 increases whereas an amount of a second portion of the output current from the transconductance amplifier 328 flowing into the first capacitor 332 decreases. Because the capacitance value of the second capacitor 316 is significantly greater than that of the first capacitor 332, the gain value of the second feedback path 384 of the SSC 320 may gradually decrease during the second time interval T2. As a result, an overshoot of the string current, or a flickering, or both may not occur during the second time interval T2.
In an embodiment, the gain adjusting circuit 330 decreases the gain value of the second feedback path 384 at a predetermined number of times during the second time interval T2. For example, referring to
In an embodiment, the gain adjusting circuit 330 may decrease the total resistance value at regular time intervals. For example, the second time interval T2 between the second time t2 and the third time t3 may have a duration of 500 ms, and the total resistance values of the gain adjusting circuit 430 in
In an embodiment, the gain adjusting circuit 330 may substantially exponentially decrease its total resistance value during the second time interval T2. For example, the total resistance values of the gain adjusting circuit 430 in
When the power converter including the SSC 320 operates in the gain adjusting mode during the second time interval T2, the voltage copier circuit 340 copies the first feedback signal VCOMP_INT and provides an averaged version of the first feedback signal VCOMP_INT to the second node N2 as the second feedback signal VCOMP. As a result, one or more fluctuations in the first feedback signal VCOMP_INT when the gain adjusting circuit 330 decreases the gain value of the second feedback path 384 at a plurality of times during the second time interval T2 may be suppressed. For example, when each of the switches S1 to S12 of the gain adjusting circuit 430 in
At the third time t3, the power converter including the SSC 320 starts to operate in a third mode (e.g., a low-gain mode). The timer circuit 322 asserts the soft-start end signal SSEND at the third time t3 to turn on the first switching device 342. In the embodiment shown in
After the third time t3, the first switching device 342 is turned on and the soft-input generator 324 receives the external dimming signal VDIM_EXT through the dimming pin Ext_DIM and generates an output signal in response to the external dimming signal VDIM_INT. In an embodiment, the soft-input generator 324 gradually increases a value of the output signal until the value reaches a given value corresponding to that of the external dimming signal VDIM_INT. As a result, the arithmetic circuit 326 gradually increases a value of the reference signal VCS_REF in response to the output signal of the soft-input generator 324 and the internal dimming signal VDIM_INT, rather than instantaneously increasing the value of reference signal VCS_REF from a value of the internal dimming signal VDIM_INT to the sum of the value of the internal dimming signal VDIM_INT and the given value corresponding to the external dimming signal VDIM_INT. As a result, an overshoot of the string current, or a flickering, or both may be suppressed after the third time t3 when the timer circuit 322 asserts the soft-start end signal SSEND to turn on the first switching device 342. According to the embodiment shown in
During the third time interval T3 between the third time t3 and a the fourth time t4, the transconductance amplifier 328 generates the first feedback signal VCOMP_INT having a value less than that during the second time interval T2 between the second time t2 and the third time t3. In the embodiment shown in
At the fourth time t4, the sensing signal VCS reaches to a second value V2 corresponding to the value of the external dimming signal VDIM_INT. As a result, the string current also reaches to a magnitude corresponding to the value of the external dimming signal VDIM_INT.
When the power converter including the SSC 320 operates in the low-gain mode after the third time t3, the SSC 320 uses the third feedback path 386 including the transconductance amplifier 328, the first capacitor 332, the gain adjusting circuit 330, and the second node N2 coupled to the second capacitor 316. The capacitance value of the second capacitor 316 is significantly greater than that of the first capacitor 332, and thus the gain value of the third feedback path 386 may be determined predominantly according to the capacitance value of the second capacitor 316 and substantially independently of the capacitance value of the first capacitor 332. The capacitance value of the second capacitor 316 is relatively large, and thus the third feedback path 386 of the SSC 320 may have a relatively low gain value suitable for performing Power Factor Correction (PFC). In an embodiment, the gain value of the third feedback path 386 be sufficiently low to make the bandwidth of the feedback loop of the power converter including the SSC 320 lower than a line frequency (e.g., 60 Hz), the feedback loop including the third feedback path 386 and performing current regulation and power factor correction (PFC).
As described above, when a power converter including the SSC 320 according to an embodiment of the present disclosure operates in the high-gain mode (or the startup mode) during the first time interval T1, the SSC 320 uses the first feedback path 382 with a relatively high gain value, thereby preventing an overshoot of the string current, or a flickering, or both during the first time interval T1. When such a power converter operates in the gain adjusting mode during the second time interval T2, the gain adjusting circuit 330 gradually decreases the gain value of the second feedback path 384, thereby preventing an overshoot of the string current, or a flickering, or both during the second time interval T2. In addition, the voltage copier circuit 340 provides the second feedback signal VCOMP by copying the first feedback signal VCOMP_INT, thereby suppressing fluctuations in the feedback signal VCOMP_INT when the gain value of the second feedback path 384 decreases at a plurality of times during the second time interval T2. When the power converter operates in the low-gain mode, the soft-input generator 324 receives the external dimming signal VDIM_INT, and then gradually increases a value of its output signal in response to the received external dimming signal VDIM_INT, thereby suppressing an overshoot of the string current, or a flickering, or both. As a result, an overshoot of the string current, or a flickering, or both may be substantially prevented when the power converter including the SSC 320 operates in the high-gain mode, the gain adjusting mode, and the low-gain mode.
At S620, the controller generates a first feedback signal (e.g., the first feedback signal VCOMP_INT) in response to a sensing signal (e.g., the sensing signal VCS in
At S640, the controller decreases a gain value of a second feedback path from the first gain value to a second gain value at a plurality of times when the power converter operates in the gain adjusting mode, the second feedback path including the amplifier, the first capacitor, the gain adjusting circuit, the voltage copier circuit, and the second node coupled to the second capacitor. In an embodiment, the controller decreases a resistance value between the first node and the second node at a plurality of times when the power converter operates in the gain adjusting mode, thereby increasing an amount of a first portion of an output current from the amplifier flowing into the second capacitor while decreasing an amount of a second portion of the output current from the amplifier flowing into the first capacitor. A capacitance value of the second capacitor may be greater than that of the first capacitor, and thus the gain value of the second feedback path may decrease when the power converter operates in the gain adjusting mode. In an embodiment, the controller further includes a voltage copier circuit (e.g., the voltage copier circuit 340 in
At S660, the controller generates the first feedback signal in response to the sensing signal and the external dimming signal using a third feedback path (e.g., the third feedback path 386 in
Aspects of the present disclosure have been described in conjunction with the specific embodiments thereof that are proposed as examples. Numerous alternatives, modifications, and variations to the embodiments as set forth herein may be made without departing from the scope of the claims set forth below. Accordingly, embodiments as set forth herein are intended to be illustrative and not limiting.
