JP2014026954A - Circuit and method for driving light source - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a circuit and a method for driving a light source.SOLUTION: A dimming controller can operate in a first mode or a second mode to control dimming of a light-emitting diode (LED) light source. The dimming controller can include a voltage control terminal and a current control terminal. The voltage control terminal provides a pulse signal to operate a control switch in either a first state or a second state when the dimming controller operates in the first mode. A first current flowing through the LED light source increases when the control switch is in the first state and decreases when the control switch is in the second state. The voltage control terminal provides a control signal to the control switch to cut off the first current when the dimming controller operates in the second mode. The current control terminal conducts a second current through the LED light source when the dimming controller operates in the second mode.

Description

This application is a continuation-in-part of co-pending U.S. Patent Application No. 13 / 100,434 entitled `` Circuits And Methods For Driving Light Sources '' filed May 4, 2011, as such, A continuation-in-part of U.S. Patent Application No. 12 / 415,028 entitled `` Driving Circuit with Continuous Dimming Function for Driving Light sources '' filed on March 31, 2009 (currently U.S. Pat.No. 8,076,867). As such, it is a partial continuation application of U.S. patent application 12 / 316,480 entitled `` Driving Circuit with Dimming Controller for Driving Light Sources '' filed on December 12, 2008 (currently U.S. Pat.No. 8,044,608), All of which are incorporated herein by reference, all of which are incorporated herein by reference in their entirety.

  In recent years, light sources such as light emitting diodes (LEDs) have been improved due to technological advances in materials and manufacturing processes. LEDs have relatively high efficiency, long life, and vivid colors and can be used in various industries including automobiles, computers, telecommunications, military, consumer goods and the like. One example is an LED lamp that uses LEDs to replace conventional light sources such as electrical filaments.

  FIG. 1 shows a schematic diagram of a conventional LED driving circuit 100. The LED drive circuit 100 uses the LED array 106 as a light source. LED string 106 includes a group of LEDs connected in series. The power converter 102 converts the input voltage Vin into a desired output DC voltage Vout in order to supply power to the LED string 106. A switch 104 coupled to the LED drive circuit 100 can enable or disable the input voltage Vin to the LED string 106 and thus can turn on or off the LED lamp. The power converter 102 receives the feedback signal from the current sensing resistor Rsen and adjusts the output voltage Vout to cause the LED string 106 to generate a desired light output. One drawback of this solution is that the desired light output is predetermined. During operation, the light output of the LED string 106 is set to a predetermined level and cannot be adjusted by the user.

  FIG. 2 shows a schematic diagram of another conventional LED driving circuit 200. The power converter 102 converts the input voltage Vin into a desired output DC voltage Vout in order to supply power to the LED string 106. A switch 104 coupled to the LED drive circuit 200 can enable or disable the input voltage Vin to the LED string 106, and thus can turn on or off the LED lamp. The LED string 106 is coupled to a linear LED current regulator 208. The operational amplifier 210 in the linear LED current regulator 208 compares the reference signal REF with the current monitoring signal from the current sensing resistor Rsen, generates a control signal, and adjusts the resistance value of transistor Q1 in linear mode To do. Accordingly, the LED current passing through the LED string 106 can be adjusted accordingly. In this solution, in order to control the light output of the LED string 106, the user can use a dedicated device, such as a specially designed switch to adjust a button or switch, that can receive a remote control signal, It may be necessary to adjust the signal REF.

  In one embodiment, the dimming controller can operate in a first mode or a second mode to control dimming of a light emitting diode (LED) light source. In one such embodiment, the dimming controller includes a voltage control terminal and a current control terminal. The voltage control terminal supplies a pulse signal to operate the control switch in the first state or the second state when the dimming controller operates in the first mode. Increased when the first current control switch passing through the LED light source is in the first state and decreased when the control switch is in the second state. The voltage control terminal supplies a control signal to the control switch to cut off the first current when the dimming controller operates in the second mode. The current control terminal conducts a second current through the LED light source when the dimming controller operates in the second mode.

  The features and advantages of the claimed embodiments will become apparent upon reading the following detailed description with reference to the drawings, in which like numerals indicate like parts.

It is the schematic of the conventional LED drive circuit. It is the schematic of another conventional LED drive circuit. 1 is a block diagram of a light source driving circuit according to an embodiment of the present invention. FIG. 1 is a schematic diagram of a light source driving circuit according to an embodiment of the present invention. FIG. 5 is a diagram showing a configuration of a dimming controller of FIG. 4 according to an embodiment of the present invention. It is a figure which shows the signal waveform in the analog dimming mode by one Embodiment of this invention. It is a figure which shows the signal waveform in the burst dimming mode by one Embodiment of this invention. FIG. 6 is a diagram illustrating an operation of a light source driving circuit including the dimming controller of FIG. 5 according to an embodiment of the present invention. 4 is a flowchart of a method for adjusting power of a light source according to an embodiment of the present invention. 1 is a schematic diagram of a light source driving circuit according to an embodiment of the present invention. FIG. 11 is a diagram illustrating a configuration of a dimming controller of FIG. 10 according to an embodiment of the present invention. FIG. 12 is a diagram illustrating an operation of a light source driving circuit including the dimming controller of FIG. 11 according to an embodiment of the present invention. 4 is a flowchart of a method for adjusting power of a light source according to an embodiment of the present invention. 2 is an example of a schematic diagram of a light source driving circuit according to an embodiment of the present invention. FIG. FIG. 14B is an example of the power switch of FIG. 14A, according to one embodiment of the invention. 14B is an example of the configuration of the dimming controller of FIG. 14A, according to one embodiment of the present invention. FIG. 16 is an example of a diagram illustrating an operation of a light source driving circuit including the dimming controller of FIG. FIG. 16 is another example of a diagram illustrating the operation of the light source drive circuit including the dimming controller of FIG. 15, according to an embodiment of the present invention. 4 is a flowchart of a method for adjusting power of a light source according to an embodiment of the present invention. It is an example of the schematic of the light source drive circuit in one Embodiment of this invention. FIG. 20 is an example of the configuration of the dimming controller of FIG. 19 in an embodiment of the present invention. It is an example of the figure which shows operation | movement of the light source drive circuit containing the dimming controller in one Embodiment of this invention. 4 is a flowchart of a method for adjusting power of a light source in an embodiment of the present invention.

  Reference will now be made in detail to the embodiments of the present invention. When the invention is described with reference to these embodiments, it will be understood that they are not intended to limit the invention to these embodiments. On the contrary, the invention is intended to protect alternatives, modifications and equivalents that may be included within the spirit and scope of the invention as defined by the appended claims. .

  Furthermore, in the following detailed description of the present invention, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, those skilled in the art will appreciate that the invention may be practiced without these specific details. In other instances, well-known methods, procedures, elements, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the present invention.

  FIG. 3 shows an example of a block diagram of a light source driving circuit 300 according to an embodiment of the present invention. In one embodiment, the power switch 304 that couples between the power source Vin and the light source driving circuit 300 can operate to selectively couple the power source to the light source driving circuit 300. The light source driving circuit 300 is an AC / DC converter 306 that converts an AC input voltage Vin from a power source into a DC voltage Vout, and a power converter coupled to the AC / DC converter 306 that supplies adjusted power to the LED string 312. A dimming controller 308 coupled to the power converter 310 that receives the switch monitoring signal indicating the operation of the power switch 304 and adjusts the adjusted power from the power converter 310 in response to the switch monitoring signal; And a current sensor 314 that detects an LED current passing through the LED string 312. In one embodiment, the power switch 304 can be an ON / OFF switch that is mounted on the wall.

  During operation, the AC / DC converter 306 converts the input AC voltage Vin to the output DC voltage Vout. The power converter 310 receives the DC voltage Vout and supplies adjusted power to the LED string 312. The current sensor 314 generates a current monitoring signal indicating the level of LED current passing through the LED string 312. The dimming controller 308 monitors the operation of the power switch 304, receives a current monitoring signal from the current sensor 314, controls the power converter 310 in response to the operation of the power switch 304, and adjusts the power of the LED string 312 Can operate to. In one embodiment, the dimming controller 308 operates in an analog dimming mode and adjusts the power of the LED string 312 by adjusting a reference signal indicating the peak value of the LED current. In another embodiment, the dimming controller 308 operates in a burst dimming mode and adjusts the power of the LED string 312 by adjusting the duty cycle of the pulse width modulation (PWM) signal. By adjusting the power of the LED string 312, the light output of the LED string 312 can be adjusted accordingly.

  FIG. 4 shows an example of a schematic diagram of a light source driving circuit 400 according to an embodiment of the present invention. FIG. 4 is described in combination with FIG. Elements having the same reference numerals as in FIG. 3 have similar functions and will not be described in detail here.

  The light source drive circuit 400 includes a power converter 310 (shown in FIG. 3) that couples to the power supply, receives power from the power supply, and couples to the LED string 312 to provide regulated power to the LED string 312. In the example of FIG. 4, power converter 310 may be a buck converter including inductor L1, diode D4, and control switch Q16. In the embodiment shown in FIG. 4, the control switch Q16 is mounted outside the dimming controller 308. In another embodiment, the control switch Q16 can be built into the dimming controller 308.

  The dimming controller 308 receives a switch monitoring signal indicating the operation of a power switch such as the power switch 304 coupled between the power source Vin and the light source driving circuit 400, and is coupled in series with the LED string 312 according to the switch monitoring signal. By controlling the control switch Q16, it is possible to operate to adjust the regulated power from the power converter 310 (including the inductor L1, the diode D4, and the control switch Q16). The light source driving circuit 400 may further include an AC / DC converter 306 that converts an AC input voltage Vin into a DC output voltage Vout, and a current sensor 314 that detects an LED current passing through the LED string 312. In the example of FIG. 4, the AC / DC converter 306 may be a bridge rectifier including diodes D1, D2, D7, and D8. The current sensor 314 can include a current sensing resistor R5.

  In one embodiment, the terminals of dimming controller 308 may include HV_GATE, SEL, CLK, RT, VDD, CTRL, MON, and GND. Terminal HV_GATE is coupled to switch Q27 through resistor R15 to control the conductive state, such as the ON / OFF state of switch Q27 coupled to LED string 312. Capacitor C11 is coupled between terminal HV_GATE and ground to adjust the gate voltage of switch Q27.

  The user can dimm, such as analog dimming mode or burst dimming mode, by coupling terminal SEL to ground through resistor R4 (as shown in Figure 4) or by directly coupling terminal SEL to ground. A mode can be selected.

  Terminal CLK is coupled to AC / DC converter 306 through resistor R3 and to ground through resistor R6. The terminal CLK can receive a switch monitoring signal indicating the operation of the power switch 304. In one embodiment, the switch monitoring signal can be generated at a common node between resistors R3 and R6. Capacitor C12 is coupled in parallel with resistor R6 to filter unwanted noise. Terminal RT is coupled to ground through resistor R7 to determine the frequency of the pulse signal generated by dimming controller 308.

  Terminal VDD is coupled to switch Q27 through diode D9 to supply power to dimming controller 308. In one embodiment, an energy storage unit such as capacitor C10 coupled between terminal VDD and ground can supply power to dimming controller 308 when power switch 304 is turned OFF. In an alternative embodiment, the energy storage unit can be integrated into the dimming controller 308. Terminal GND is coupled to ground.

  Terminal CTRL is coupled to control switch Q16. Control switch Q16 is coupled in series with LED string 312 and switch Q27 and is coupled to ground through current sensing resistor R5. The dimming controller 308 adjusts the adjusted power from the power converter 310 by using the control signal via the terminal CTRL and controlling the conductive state such as the on and off states of the control switch Q16. Can work. Terminal MON couples to current sensing resistor R5 to receive a current monitoring signal indicative of the LED current passing through LED string 312. When the switch Q27 is turned on, the dimming controller 308 can adjust the LED current passing through the LED string 312 to the ground by controlling the control switch Q16.

  During operation, when the power switch 304 is turned ON, the AC / DC converter 306 converts the input AC voltage Vin into the DC voltage Vout. A predetermined voltage at the terminal HV_GATE is supplied to the switch Q27 through the resistor R15, and as a result, the switch Q27 is turned ON.

  When the dimming controller 308 turns on the control switch Q16, the DC voltage Vout supplies power to the LED string 312 and charges the inductor L1. The LED current passes through the inductor L1, the LED string 312, the switch Q27, the control switch Q16, and the current detection resistor R5 to reach the ground. When the dimming controller 308 turns off the control switch Q16, the LED current passes through the inductor L1, the LED string 312, and the diode D4. The inductor L1 is discharged so as to supply power to the LED string 312. Therefore, the dimming controller 308 can adjust the adjusted power from the power converter 310 by controlling the control switch Q16.

  When the power switch 304 is turned OFF, the capacitor C10 is discharged to supply power to the dimming controller 308. The voltage across resistor R6 drops to zero, so a switch monitoring signal indicating the power shutoff operation of power switch 304 can be detected by dimming controller 308 through terminal CLK. Similarly, when the power switch 304 is turned ON, the voltage across the resistor R6 rises to a predetermined voltage, and therefore the switch monitoring signal indicating the power-on operation of the power switch 304 is dimmed through the terminal CLK. It can be detected by the device 308. When power-off operation is detected, the dimming controller 308 can turn off the switch Q27 by pulling the voltage at the terminal HV_GATE to zero, and after the inductor L1 completes the discharge, the LED string 312 The power supply can be cut off. In response to the power shutdown operation, the dimming controller 308 can adjust the reference signal indicating the target light output of the LED string 312. Therefore, when the power switch 304 is turned on next time, the LED array 312 can generate a light output according to the adjusted target light output. In other words, the light output of the LED array 312 can be adjusted by the dimming controller 308 in response to the power cut-off operation of the power switch 304.

  FIG. 5 shows an example of the configuration of the dimming controller 308 of FIG. 4 according to one embodiment of the present invention. FIG. 5 is described in combination with FIG. Elements having the same reference numerals as in FIG. 4 have similar functions and will not be described in detail here.

  The dimming controller 308 includes a trigger monitoring unit 506, a dimmer 502, and a pulse signal generator 504. The trigger monitoring unit 506 is coupled to ground through a Zener diode ZD1. The trigger monitoring unit 506 can receive a switch monitoring signal indicating the operation of the external power switch 304 through the terminal CLK, and generates a drive signal for driving the counter 526 when the operation of the external power switch 304 is detected at the terminal CLK. Can be made. The trigger monitoring unit 506 can be further operated to control the conductive state of the switch Q27. The dimmer 502 generates the reference signal REF and adjusts the power of the LED string 312 in the analog dimming mode, or generates the control signal 538 and adjusts the duty cycle of the PWM signal PWM1 to adjust the LED string 312 Can operate to regulate the power of the. The pulse signal generator 504 is operable to generate a pulse signal that can turn on the control switch Q16. Dimming controller 308 is a start-up and undervoltage lockout (UVL) circuit that couples to terminal VDD to selectively power one or more elements of dimming controller 308 in response to different power conditions 508 may further be included.

  In one embodiment, the start and undervoltage lockout circuit 508 is operable to power on all elements of the dimming controller 308 when the voltage at the terminal VDD is greater than the first predetermined voltage. it can. When turning off the power switch 304, the start-up and undervoltage lockout circuit 508 causes the trigger monitoring unit 506 and dimmer to conserve energy if the voltage at the terminal VDD is less than the second predetermined voltage. Except for 502, other elements of the dimming controller 308 can be operated to power off. The start and undervoltage lockout circuit 508 can further operate to power off the trigger monitoring unit 506 and the dimmer 502 when the voltage at the terminal VDD is less than the third predetermined voltage. In one embodiment, the first predetermined voltage is greater than the second predetermined voltage, and the second predetermined voltage is greater than the third predetermined voltage. Since the dimming controller 308 can be powered by the capacitor C10 through the terminal VDD, the trigger monitoring unit 506 and the dimmer 502 still operate for a predetermined time after the power switch 304 is turned OFF. can do.

  In dimming controller 308, terminal SEL is coupled to current source 532. The user can select the dimming mode by setting the terminal SEL, for example, by directly coupling the terminal SEL to ground or by coupling the terminal SEL to ground through a resistor. In one embodiment, the dimming mode can be determined by measuring the voltage at terminal SEL. When terminal SEL is directly coupled to ground, the voltage at terminal SEL is approximately equal to zero. The control circuit can then turn on the switch 540, turn off the switch 541, and turn off the switch 542. Thus, the dimming controller 308 can operate in an analog dimming mode and can adjust the power of the LED string 312 (shown in FIG. 4) by adjusting the reference signal REF. In one embodiment, when the terminal SEL is coupled to ground through a resistor R4 (shown in FIG. 4) having a predetermined resistance value, the voltage at the terminal SEL can be greater than zero. The control circuit can then turn off switch 540, turn on switch 541, and turn on switch 542. Therefore, the dimming controller 308 can operate in the burst dimming mode, and can adjust the power of the LED string 312 (shown in FIG. 4) by adjusting the duty cycle of the PWM signal PWM1. In other words, different dimming modes can be selected by controlling the ON / OFF states of the switch 540, the switch 541, and the switch 542. The ON / OFF states of the switch 540, the switch 541, and the switch 542 can be determined by the voltage at the terminal SEL.

  Pulse signal generator 504 is coupled to ground through terminal RT and resistor R7 to generate a pulse signal 536 that can turn on control switch Q16. The pulse signal generator 504 can have different configurations, and is not limited to the configuration shown in the example of FIG.

  In the pulse signal generator 504, the non-inverting input of the operational amplifier 510 receives a predetermined voltage V1. Therefore, the voltage at the inverting input of the operational amplifier 510 can be V1. Current IRT passes through terminal RT and resistor R7 to ground. Current I1 passing through MOSFET 514 and MOSFET 515 is equal to IRT. Since MOSFET 514 and MOSFET 512 constitute a current mirror, the current I2 passing through MOSFET 512 is also approximately equal to IRT. The output of comparator 516 and the output of comparator 518 are coupled to the S and R inputs of SR flip-flop 520, respectively. The inverting input of the comparator 516 receives a predetermined voltage V2. The non-inverting input of the comparator 518 receives a predetermined voltage V3. In one embodiment, V2 is greater than V3 and V3 is greater than zero. Capacitor C4 is coupled between MOSFET 512 and ground and has one side coupled to a common node between the non-inverting input of comparator 516 and the inverting input of comparator 518. The Q output of SR flip-flop 520 is coupled to switch Q15 and the S input of SR flip-flop 522. Switch Q15 is coupled in parallel with capacitor C4. The conductive state such as the ON / OFF state of the switch Q15 can be determined by the Q output of the SR flip-flop 520.

  Initially, the voltage across capacitor C4 is approximately equal to zero, which is less than V3. Thus, the R input of SR flip-flop 520 receives a digital 1 from the output of comparator 518. The Q output of SR flip-flop 520 is set to digital 0, which turns switch Q15 off. When the switch Q15 is turned OFF, the capacitor C4 is charged by I2, so the voltage across the capacitor C4 increases. When the voltage across C4 is greater than V2, the S input of SR flip-flop 520 receives a digital 1 from the output of comparator 516. The Q output of SR flip-flop 520 is set to digital 1, which turns on switch Q15. When the switch Q15 is turned on, the capacitor C4 is discharged through the switch Q15, so the voltage across C4 decreases. When the voltage across capacitor C4 drops below V3, comparator 518 outputs a digital 1, and the Q output of SR flip-flop 520 is set to digital 0, which turns switch Q15 off. Next, the capacitor C4 is charged again by I2. Thus, through the process described above, the pulse signal generator 504 can generate a pulse signal 536 that includes a series of pulses at the Q output of the SR flip-flop 520. Pulse signal 536 is sent to the S input of SR flip-flop 522.

  The trigger monitoring unit 506 is operable to monitor the operation of the power switch 304 through the terminal CLK, and generates a drive signal that drives the counter 526 when the operation of the power switch 304 is detected at the terminal CLK. Can work. In one embodiment, when power switch 304 is turned on, the voltage at terminal CLK rises to a level equal to the voltage across resistor R6 (shown in FIG. 4). When power switch 304 is turned off, the voltage at terminal CLK drops to zero. Therefore, a switch monitoring signal indicating the operation of the power switch 304 can be detected at the terminal CLK. In one embodiment, the trigger monitoring unit 506 generates a drive signal when a power shutdown operation is detected at the terminal CLK.

  The trigger monitoring unit 506 can be further operated to control the conductive state of the switch Q27 through the terminal HV_GATE. When turning on the power switch 304, the breakdown voltage across the Zener diode ZD1 is applied to the switch Q27 through the resistor R3. Therefore, the switch Q27 can be turned on. The trigger monitoring unit 506 can turn off the switch Q27 by pulling the voltage at the terminal HV_GATE to zero. In one embodiment, the trigger monitoring unit 506 turns off the switch Q27 when the power-off operation of the power switch 304 is detected at the terminal CLK, and switches off when the power-on operation of the power switch 304 is detected at the terminal CLK. Turn on Q27.

  In one embodiment, the dimmer 502 includes a counter 526 coupled to the trigger monitoring unit 506 that counts the operation of the power switch 304 and a digital-to-analog converter (D / A converter) 528 coupled to the counter 526. Including. The dimmer 502 can further include a PWM generator 530 coupled to the D / A converter 528. The counter 526 can be driven by a drive signal generated by the trigger monitoring unit 506. More specifically, in one embodiment, when the power switch 304 is turned OFF, the trigger monitoring unit 506 detects a negative edge of the voltage at the terminal CLK and generates a drive signal. The count value of the counter 526 can be increased by, for example, 1 in response to the drive signal. The D / A converter 528 reads the count value from the counter 526 and generates a dimming signal (for example, the control signal 538 or the reference signal REF) based on the count value. The dimming signal can be used to adjust the target power level of the power converter 310 and then the light output of the LED string 312 can be adjusted.

  In the burst dimming mode, the switch 540 is turned off, and the switch 541 and the switch 542 are turned on. The inverting input of the comparator 534 receives a reference signal REF1, which can be a DC signal having a predetermined substantially constant voltage. The voltage REF1 can determine the peak value of the LED current, which in turn can determine the maximum light output of the LED string 312. The dimming signal can be a control signal 538 applied to the PWM generator 530 to adjust the duty cycle of the PWM signal PWM1. By adjusting the duty cycle of PWM1, the light output of LED string 312 can be adjusted to the same magnitude as the maximum light output determined by REF1. For example, when PWM1 has a 100% duty cycle, the LED string 312 can have a maximum light output. When the duty cycle of PWM1 is less than 100%, the LED string 312 can have a light output that is lower than the maximum light output.

  In the analog dimming mode, the switch 540 is turned on, the switches 541 and 542 are turned off, and the dimming signal can be an analog reference signal REF having an adjustable voltage. The D / A converter 528 can adjust the voltage of the reference signal REF according to the count value of the counter 526. The voltage at REF can determine the peak value of the LED current, and then the average value of the LED current. Therefore, the light output of the LED string 312 can be adjusted by adjusting the reference signal REF.

  In one embodiment, the D / A converter 528 can decrease the voltage at REF in response to an increase in the count value. For example, when the count value is 0, the D / A converter 528 adjusts the reference signal REF to have the voltage V4. When the power-off operation of the power switch 304 is detected at the terminal CLK by the trigger monitoring unit 506, if the count value increases to 1, the D / A converter 528 has the reference signal REF so that it has a voltage V5 less than V4. Adjust. In yet another embodiment, the D / A converter 528 can increase the voltage at REF in response to an increase in the count value.

  In one embodiment, after the counter 526 reaches its maximum count value, the count value is reset to zero. For example, when the counter 526 is a 2-bit counter, the count value increases from 0 to 1, 2, and 3, and then returns to zero after four power-off operations are detected. Thus, the light output of the LED string 312 can be adjusted from the first level to the second level, then to the third level, then to the fourth level, and then back to the first level.

  The inverting input of the comparator 534 can selectively receive the reference signal REF and the reference signal REF1. For example, the inverting input of the comparator 534 receives the reference signal REF through the switch 540 in the analog dimming mode and the reference signal REF1 through the switch 541 in the burst dimming mode. The non-inverting input of comparator 534 is coupled to resistor R5 through terminal MON to receive current monitoring signal SEN from current sensing resistor R5. The voltage of the current monitoring signal SEN can indicate the LED current passing through the LED string 312 when the switch Q27 and the control switch Q16 are turned on.

  The output of comparator 534 is coupled to the R input of SR flip-flop 522. The Q output of SR flip-flop 522 is coupled to AND gate 524. A PWM signal PWM1 generated by the PWM generator 530 is applied to the AND gate 524. The AND gate 524 outputs a control signal and controls the control switch Q16 through the terminal CTRL.

  When the analog dimming mode is selected, the switch 540 is turned on and the switches 541 and 542 are turned off. The control switch Q16 is controlled by the SR flip-flop 522. During operation, when turning on the power switch 304, the breakdown voltage across the Zener diode ZD1 turns on the switch Q27. In response to the pulse signal 536 generated by the pulse generator 504, the SR flip-flop 522 generates a digital 1 at the Q output and turns on the control switch Q16. The LED current passes through the inductor L1, the LED string 312, the switch Q27, the control switch Q16, and the current detection resistor R5 to reach the ground. As the inductor resists sudden changes in the LED current, the LED current increases gradually. As a result, the voltage across the current sensing resistor R5, that is, the voltage of the current monitoring signal SEN can be increased. When the voltage on SEN is greater than the voltage on the reference signal REF, the comparator 534 generates a digital 1 at the R input of the SR flip-flop 522, which results in the SR flip-flop 522 generating a digital 0 and the control switch Set Q16 to OFF. After turning off the control switch Q16, the inductor L1 discharges and supplies power to the LED string 312. The LED current passing through the inductor L1, the LED string 312 and the diode D4 gradually decreases. When SR flip-flop 522 receives a pulse again at the S input, it turns on control switch Q16, at which time the LED current again passes through current sensing resistor R5 to ground. When the voltage of the current monitoring signal SEN is larger than the voltage of the reference signal REF, the SR flip-flop 522 turns off the control switch Q16. As described above, the reference signal REF can determine the peak value of the LED current and then the light output of the LED string 312. The light output of the LED array 312 can be adjusted by adjusting the reference signal REF.

  In the analog dimming mode, when the power switch 304 is turned OFF, the capacitor C10 (shown in FIG. 4) discharges and supplies power to the dimming controller 308. When the trigger monitoring unit 506 detects the power-off operation of the power switch 304 at the terminal CLK, the count value of the counter 526 can be increased by one. The trigger monitoring unit 506 can turn off the switch Q27 in response to the power cut-off operation of the power switch 304. The D / A converter 528 can adjust the voltage of the reference signal REF from the first level to the second level in response to the change in the count value. Therefore, when the power switch 304 is turned on, the light output of the LED row 312 can be adjusted according to the adjusted reference signal REF.

  When the burst dimming mode is selected, the switch 540 is turned off and the switches 541 and 542 are turned on. The inverting input of the comparator 534 receives a reference signal REF1 having a predetermined voltage. Control switch Q16 is controlled by both SR flip-flop 522 and PWM signal PWM1 through AND gate 524. The reference signal REF1 can determine the peak value of the LED current, and then determine the maximum light output of the LED string 312. The duty cycle of the PWM signal PWM1 can determine the ON / OFF time of the control switch Q16. When the PWM signal PWM1 is logic 1, the conductive state of the control switch Q16 is determined by the Q output of the SR flip-flop 522. When the PWM signal PWM1 is logic 0, the control switch Q16 is turned OFF. By adjusting the duty cycle of the PWM signal PWM1, the power of the LED string 312 can be adjusted accordingly. Therefore, the combination of the reference signal REF1 and the PWM signal PWM1 can determine the light output of the LED array 312.

  In the burst dimming mode, when the power switch 304 is turned OFF, the power cut-off operation of the power switch 304 can be detected by the trigger monitoring unit 506 at the terminal CLK. The trigger monitoring unit 506 turns off the switch Q27 and generates a drive signal. The count value of the counter 526 can be increased by, for example, 1 in response to the drive signal. The D / A converter 528 can generate the control signal 538 to adjust the duty cycle of the PWM signal PWM1 from the first level to the second level. Therefore, when the power switch 304 is turned on next time, the light output of the LED string 312 can be adjusted to follow the target light output determined by the reference signal REF1 and the PWM signal PWM1.

  FIG. 6 shows the signal waveform of the LED current 602 passing through the LED string 312, the signal waveform of the pulse signal 536, the signal waveform of V522 indicating the output of the SR flip-flop 522, and the output of the AND gate 524 in the analog dimming mode. An example of the signal waveform of V524 and the ON / OFF state of the control switch Q16 is shown. FIG. 6 is described in combination with FIG. 4 and FIG.

  During operation, the pulse signal generator 504 generates a pulse signal 536. SR flip-flop 522 generates a digital 1 at the Q output in response to each pulse of pulse signal 536. When the Q output of the SR flip-flop 522 is digital 1, the control switch Q16 is turned ON. When the control switch Q16 is turned ON, the inductor L1 is ramped up and the LED current 602 is increased. When the LED current 602 reaches the peak value Imax, it means that the voltage of the current monitoring signal SEN is approximately equal to the voltage of the reference signal REF, and the comparator 534 generates a digital 1 at the R input of the SR flip-flop 522 As a result, the SR flip-flop 522 generates a digital 0 at the Q output. When the Q output of the SR flip-flop 522 is digital 0, the control switch Q16 is turned OFF. When the control switch Q16 is turned OFF, the inductor L1 is discharged to supply power to the LED string 312 and the LED current 602 decreases. In this analog dimming mode, by adjusting the reference signal REF, the average LED current can be adjusted accordingly, and thus the light output of the LED string 312 can be adjusted.

  FIG. 7 shows the signal waveform of the LED current 602 passing through the LED string 312, the signal waveform of the pulse signal 536, the signal waveform of V522 indicating the output of the SR flip-flop 522, and the output of the AND gate 524 in the burst dimming mode. An example of the signal waveform of V524, the ON / OFF state of the control switch Q16, and the signal waveform of the PWM signal PWM1 is shown. FIG. 7 is described in combination with FIG. 4 and FIG.

  When PWM1 is digital 1, the relationship among the LED current 602, the pulse signals 536, V522, V524, and the ON / OFF state of the switch Q1 is the same as the relationship shown in FIG. When PWM1 is digital 0, the output of AND gate 524 changes to digital 0. Therefore, the control switch Q16 is turned OFF, and the LED current 602 decreases. When PWM1 holds digital 0 long enough, the LED current 602 can drop to zero. In the burst dimming mode, by adjusting the PWM1 duty cycle, the average LED current can be adjusted accordingly, and thus the light output of the LED string 312 can be adjusted.

  FIG. 8 shows an example of a diagram illustrating the operation of a light source drive circuit including the dimming controller of FIG. 5, according to one embodiment of the present invention. FIG. 8 is described in combination with FIG.

  In the example shown in FIG. 8, the count value of the counter 526 increases by 1 every time the power monitoring operation of the power switch 304 is detected by the trigger monitoring unit 506. The counter 526 may be a 2-bit counter having a maximum count value of 3.

  In the analog dimming mode, the D / A converter 528 reads the count value from the counter 526 and decreases the voltage of the reference signal REF in response to the increase in the count value. The voltage at REF can determine the peak value Imax of the LED current, and then the average value of the LED current can be determined. In the burst dimming mode, the D / A converter 528 reads the count value from the counter 526 and decreases the duty cycle of the PWM signal PWM1 in response to the increase in the count value (for example, decreases by 25% each time). The counter 526 is reset after reaching its maximum count value (eg, 3).

  FIG. 9 shows a flowchart 900 of a method for adjusting the output of a light source, according to one embodiment of the invention. FIG. 9 is described in combination with FIG. 4 and FIG.

  In block 902, a light source such as LED string 312 is powered with regulated power from a power converter such as power converter 310. In block 904, a switch monitoring signal may be received, for example, by the dimming controller 308. The switch monitoring signal can indicate the operation of a power switch such as power switch 304 that couples between the power source and the power converter. At block 906, a dimming signal is generated in response to the switch monitoring signal. At block 908, a switch coupled in series with the light source, such as control switch Q16, is controlled in response to the dimming signal to adjust the adjusted power from the power converter. In one embodiment, in the analog dimming mode, the adjusted power from the power converter can be adjusted by comparing the dimming signal with a feedback current monitoring signal indicative of the light source current from the light source. In another embodiment, in burst dimming mode, the adjusted power from the power converter can be adjusted by controlling the duty cycle of the PWM signal with the dimming signal.

  Therefore, the embodiment according to the present invention provides a light source driving circuit capable of adjusting the power of a light source according to a switch monitoring signal indicating the operation of a power switch such as an ON / OFF switch attached to a wall. The power of the light source supplied by the power converter can be adjusted by the dimming controller by controlling a switch coupled in series with the light source. Advantageously, as described above, the user can adjust the light output of the light source through the operation of a common ON / OFF power switch (eg, power off operation). Therefore, an additional device for dimming such as an external dimmer or a specially designed switch with an adjustment button can be avoided, and the cost can be reduced.

  FIG. 10 shows an example of a schematic diagram of a light source driving circuit 1000 according to an embodiment of the present invention. FIG. 10 is described in combination with FIG. Elements having the same reference numerals as in FIGS. 3 and 4 have similar functions.

  The light source drive circuit 1000 includes a power converter 310 coupled to the power supply and the LED string 312 that receives power from the power supply and provides regulated power to the LED string 312. The dimming controller 1008 can operate to monitor the power switch 304 coupled between the power source and the light source driving circuit 1000 by monitoring the voltage at the terminal CLK. The dimming controller 1008 is operable to receive a dimming request signal indicating the operation of the first set of power switches 304 and to receive a dimming end signal indicating the operation of the second set of power switches 304. it can. The dimming controller 1008 can receive the dimming request signal and the dimming end signal via the terminal CLK. The dimming controller 1008 continuously adjusts the adjusted power from the power converter 310 when receiving the dimming request signal and adjusts the adjusted power from the power converter 310 when receiving the dimming end signal. Can be further operated to abort. In other words, when the dimming controller 1008 detects the operation of the first set of the power switch 304, it continuously supplies the power from the power converter 310 until it detects the operation of the second set of the power switch 304. Can be adjusted. In one embodiment, the dimming controller 1008 can adjust the regulated power from the power converter 310 by controlling a control switch Q16 coupled in series with the LED string 312.

  FIG. 11 shows an example of the configuration of the dimming controller 1008 of FIG. 10, according to one embodiment of the present invention. FIG. 11 is described in combination with FIG. Elements having the same reference numerals as those in FIGS. 4, 5, and 10 have the same functions.

  In the example of FIG. 11, the configuration of the dimming controller 1008 in FIG. 11 is the same as the configuration of the dimming controller 308 in FIG. 5 except for the configurations of the dimmer 1102 and the trigger monitoring unit 1106. In FIG. 11, the trigger monitoring unit 1106 receives the dimming request signal and the dimming end signal via the terminal CLK, and operates to generate the signal EN to enable or disable the clock generator 1104. it can. The trigger monitoring unit 1106 can further operate to control the conductive state of the switch Q27 coupled to the LED string 312.

  The dimmer 1102 generates the reference signal REF to adjust the power of the LED string 312 in the analog dimming mode, or the PWM signal PWM1 to adjust the power of the LED string 312 in the burst dimming mode. Can be operated to generate a control signal 538 that adjusts the duty cycle. In the example shown in FIG. 11, the dimmer 1102 generates a clock signal, a clock generator 1104 coupled to the trigger monitoring unit 1106, a counter 1126 driven by the clock signal, and a digital analog coupled to the counter 1126 ( D / A) converter 528. The dimmer 1102 can further include a PWM generator 530 coupled to the D / A converter 528.

  During operation, when the power switch 304 is turned ON or OFF, the trigger monitoring unit 1106 can detect a positive edge or a negative edge of the voltage at the terminal CLK. For example, when the power switch 304 is turned OFF, the capacitor C10 is discharged and supplies power to the dimming controller 1008. The voltage across resistor R6 drops to zero. Therefore, the negative edge of the voltage at the terminal CLK can be detected by the trigger monitoring unit 1106. Similarly, when turning on the power switch 304, the voltage across the resistor R6 rises to a predetermined voltage. Therefore, the positive edge of the voltage at the terminal CLK can be detected by the trigger monitoring unit 1106. Therefore, an operation such as a power-on operation or a power-off operation of the power switch 304 can be detected by monitoring the voltage at the terminal CLK by the trigger monitoring unit 1106.

  In one embodiment, the dimming request signal can be received via the terminal CLK by the trigger monitoring unit 1106 when detecting a first set of operations of the power switch 304. The dimming end signal can be received by the trigger monitoring unit 1106 via the terminal CLK when detecting the second set of operations of the power switch 304. In one embodiment, the first set of operations of the power switch 304 includes a first power-up operation following the first power-off operation. In one embodiment, the second set of operations of the power switch 304 includes a second power-up operation following the second power-off operation.

  When the trigger monitoring unit 1106 receives the dimming request signal, the dimming controller 1008 begins to continuously adjust the adjusted power from the power converter 310. In the analog dimming mode, the dimming controller 1008 adjusts the voltage of the reference signal REF and adjusts the adjusted power from the power converter 310. In the burst dimming mode, the dimming controller 1008 adjusts the duty cycle of the PWM signal PWM1 to adjust the adjusted power from the power converter 310.

  When the trigger monitoring unit 1106 receives the dimming end signal, the dimming controller 1008 can stop adjusting the adjusted power from the power converter 310.

  FIG. 12 shows an example of a diagram illustrating the operation of the light source drive circuit including the dimming controller 1008 of FIG. 11, according to one embodiment of the present invention. FIG. 12 is described in combination with FIG. 10 and FIG.

  First, assume that the power switch 304 is OFF. In one embodiment, during operation, for example when the user turns on the power switch 304, the LED string 312 is powered by the regulated power from the power converter 310 to generate the initial light output. In the analog dimming mode, the initial light output can be determined by the initial voltage of the reference signal REF. In the burst dimming mode, the first light output can be determined by the first duty cycle (eg, 100%) of the PWM signal PWM1. In one embodiment, the reference signal REF and the PWM signal PWM1 can be generated by the D / A converter 528 in accordance with the count value of the counter 1126. Thus, the first voltage at REF and the first duty cycle of PWM1 can be determined by the first count value provided by counter 1126 (eg, 0).

  To adjust the light output of the LED string 312, the user can perform a first set of operations on the power switch 304. When the operation of the first set of power switches 304 is detected, a dimming request signal is generated. In one embodiment, the first set of operations can include a first power-up operation following the first power-off operation. As a result, the trigger monitoring unit 1106 can detect and receive a dimming request signal including the positive edge 1206 following the negative edge 1204 of the voltage at the terminal CLK. In response to the dimming request signal, the trigger monitoring unit 1106 can generate a high level signal EN. Therefore, the clock generator 1104 generates a clock signal. The counter 1126 driven by the clock signal can change the count value in response to each clock pulse of the clock signal. In the example of FIG. 12, the count value increases in response to the clock signal. In one embodiment, after the counter 1126 reaches its predetermined maximum count value, the count value can be reset to zero. In another embodiment, the count value increases until the counter 1126 reaches its predetermined maximum count value and decreases until the counter 1126 reaches its predetermined minimum count value.

  In one embodiment, in the analog dimming mode, the D / A converter 528 reads the count value from the counter 1126 and decreases the voltage of the reference signal REF in response to the increase in the count value. In one embodiment, in burst dimming mode, the D / A converter 528 reads the count value from the counter 1126 and decreases the duty cycle of the PWM signal PWM1 in response to the increase in count value (e.g., decreases by 10% each time). ) Therefore, the adjusted power from the power converter 310 can be determined by the voltage of the reference signal REF (in analog dimming mode) or the duty cycle of the PWM signal PWM1 (in burst dimming mode), so the LED string 312 light output can be adjusted.

  When the desired light output is reached, the user can end the adjustment process by performing a second set of actions on the power switch 304. When the operation of the second set of the power switch 304 is detected, a dimming end signal is generated. In one embodiment, the second set of operations can include a second power-up operation following the second power-off operation. As a result, the trigger monitoring unit 1106 can detect and receive a dimming end signal including the positive edge 1210 following the negative edge 1208 of the voltage at the terminal CLK. Upon detecting the dimming end signal, the trigger monitoring unit 1106 can generate a low level signal EN. Therefore, the clock generator 1104 is disabled so that the counter 1126 can hold the count value. Therefore, in the analog dimming mode, the voltage of the reference signal REF can be held at a desired level. In the burst dimming mode, the duty cycle of the PWM signal PWM1 can be held at a desired value. Therefore, the light output of the LED array 312 can be maintained at a desired light output.

  FIG. 13 shows a flowchart 1300 of a method for adjusting the power of a light source, according to one embodiment of the invention. FIG. 13 is described in combination with FIG. 10 and FIG.

  In block 1302, a light source such as LED string 312 is powered with regulated power from a power converter such as power converter 310.

  In block 1304, the dimming request signal may be received by the dimming controller 1008, for example. The dimming request signal can indicate the operation of a first set of power switches, such as power switch 304, coupled between the power source and the power converter. In one embodiment, the first set of power switch operations includes a first power-up operation following the first power-off operation.

  In block 1306, the adjusted power from the power converter is continuously adjusted, eg, by the dimming controller 1008. In one embodiment, the clock generator 1104 can drive the counter 1126. In accordance with the count value of the counter 1126, a dimming signal (for example, the control signal 538 or the reference signal REF) can be generated. In the analog dimming mode, the adjusted power from the power converter can be adjusted by comparing the reference signal REF and a feedback current monitoring signal indicating the light source current of the light source. The voltage of REF can be determined by the count value. In the burst dimming mode, the adjusted power from the power converter can be adjusted by changing the duty cycle of the PWM signal PWM1 by the control signal 538. The duty cycle of PWM1 can also be determined by the count value.

  In block 1308, the dimming end signal may be received by the dimming controller 1008, for example. The dimming end signal can indicate the operation of a second set of power switches, such as power switch 304, coupled between the power source and the power converter. In one embodiment, the second set of power switch operations includes a second power-up operation following the second power-off operation.

  At block 1310, adjustment of the adjusted power from the power converter ends when a dimming end signal is received. In one embodiment, the clock generator 1104 is disabled, allowing the counter 1126 to hold its count value. As a result, in the analog dimming mode, the voltage of REF can be held at a desired level. In the burst dimming mode, the duty cycle of the PWM signal PWM1 can be held at a desired value. As a result, the light source can maintain a desired light output.

FIG. 14A shows an example of a schematic diagram of a light source drive circuit 1400 according to one embodiment of the invention. Elements having the same reference numerals as in FIGS. 3 and 4 have similar functions. FIG. 14A is described in combination with FIG. The light source drive circuit 1400 is coupled to the power source V _IN (eg, 110/120 volts AC, 60 Hz) via the power switch 304 and is coupled to the LED light source 312. Referring to FIG. 14B, an example of the power switch 304 of FIG. 14A is shown according to one embodiment of the present invention. In one embodiment, the power switch 304 is an ON / OFF switch that is mounted on the wall. By switching the element 1480 to the ON position or the OFF position, the conductive state of the power switch 304 is controlled to be ON or OFF, for example, by the user.

Referring to FIG. 14A again, the light source driving circuit 1400 includes an AC / DC converter 306, a power converter 310, and a dimming controller 1408. The AC / DC converter 306 converts the input AC voltage V _IN into the output DC voltage V _OUT . In the example of FIG. 14A, the AC / DC converter 306 includes a bridge rectifier including diodes D1, D2, D7, and D8. A power converter 310 coupled to the AC / DC converter 306 receives the output DC voltage V _OUT and provides an output voltage to the LED light source 312. A dimming controller 1408 coupled to the AC / DC converter 306 and coupled to the power converter 310 monitors the power switch 304 and controls the power switch 304 to control the brightness of the light emitted from the LED light source 312. The power converter 310 can be operated to adjust the output power according to the operation.

  In one embodiment, power converter 310 includes inductor L1, diode D4, switch Q27, control switch Q16, and current sensor R5. The dimming controller 1408 includes a plurality of terminals such as a terminal HV_GATE, a terminal CLK, a terminal VDD, a terminal GND, a terminal CTRL, a terminal RT, and a terminal MON. The terminals of the dimming controller 1408 operate in the same manner as the corresponding terminals of the dimming controller 308 described in FIG.

  In operation, the dimming controller 1408 monitors the power switch 304 by receiving a switch monitoring signal 1450 at terminal CLK. A switch monitoring signal 1450 indicates a conductive state such as an ON / OFF state of the power switch 304. In response, the dimming controller 1408 controls the switch Q27 through the terminal HV_GATE and the control switch Q16 through the terminal CTRL so as to control the dimming of the LED light source 312.

More specifically, in one embodiment, when power switch 304 is turned on, dimming controller 1408 generates a signal such as a logic high at terminal HV_GATE to turn on switch Q27 and switch at terminal CTRL. A control signal 1452 is generated to turn on and off the control switch Q16. In one embodiment, the control switch Q16 operates in a switch on state and a switch off state. While the control switch Q16 is switched on, the switch control signal 1452 alternately turns the control switch Q16 on and off. For example, the dimming controller 1408 periodically turns on the control switch Q16. In addition, the dimming controller 1408 receives a sense signal 1454 indicative of the current I _LED through the LED light source 312 via the terminal MON, and when the sense signal 1454 indicates that the current I _LED reaches the current threshold I _TH Set control switch Q16 to OFF. Therefore, when the control switch Q16 is turned on, the current I _LED is ramped up, and when the control switch Q16 is turned off, the current I _LED is ramped down. In this way, the dimming controller 1408, the average level I _AVERAGE current I _LED to determine the peak level of the current I _LED to be controlled. During the switch-off state of the control switch Q16, the switch control signal 1452 keeps the control switch Q16 off and cuts off the current I _LED . In one embodiment, the dimming controller 1408 determines the time ratio between the switch-on state and the switch-off state to control the average level I _AVERAGE of the current I _LED .

In one embodiment, when turning off the power switch 304, the dimming controller 1408 generates a signal such as a logic low at the terminal HV_GATE to turn off the switch Q27. Therefore, the current I _LED passing through the LED light source 312 drops to almost zero amperes and the LED light source 312 is shut off.

In one embodiment, the dimming controller 1408 receives a switch monitoring signal 1450 that indicates the conduction state of the power switch 304 at the terminal CLK. In response, the dimming controller 1408 can identify the operation of the power switch 304 and supply a dimming request signal indicating the operation of the power switch 304. In one embodiment, the dimming controller 1408 provides a dimming request signal when identifying a power off operation of the power switch 304. Alternatively, when identifying the power-on operation of the power switch 304, the dimming controller 1408 supplies a dimming request signal. In one embodiment, the dimming controller 1408 accordingly operates in analog dimming mode, burst dimming mode, or combination mode to adjust the ON / OFF state of the control switch Q16 to control the LED light source 312. Control dimming. For example, in the analog dimming mode, the peak level of the current I _LED is determined by the dimming controller 1408, while the time ratio between the switch-on state and the switch-off state remains at the same level. In the burst dimming mode, the time ratio between the switch-on state and the switch-off state is determined by the dimming controller 1408, while the peak level of the current I _LED remains at the same level. In the combination mode, the peak level of the current I _LED and the time ratio between the switch-on state and the switch-off state are both determined by the dimming controller 1408. Therefore, when switch Q27 is turned on again (which indicates power switch 304 is turned on again), the current I _LED peak level and / or the duration of the switch-on and switch-off state times are adjusted Is done. As a result, the average current I _AVERAGE passing through the LED light source 312 is adjusted to control the luminance of the LED light source 312.

Advantageously, by adjusting both the peak level of the current I _LED and the duration of the switch-on state and the duration of the switch-off state, the dimming controller 1408 has a relatively wide range of average currents I _AVERAGE Can be adjusted. For example, when I _MAX is the maximum level of the average current I _AVERAGE , I _AVERAGE is 4% * according to one embodiment compared to the prior art 20% * I _MAX to 100% * I _MAX range. Can vary from I _MAX to 100% * I _MAX . As a result, a wider range of dimming of the LED light source 312 is achieved, which is beneficial for energy efficient light applications such as night lighting.

  FIG. 15 shows an example of the configuration of the dimming controller 1408 of FIG. 14A, according to one embodiment of the invention. FIG. 15 is described in combination with FIG. 5 to FIG. 7 and FIG. 14A. Elements having the same reference numerals as in FIGS. 5 and 14A have similar functions.

In the example of FIG. 15, the dimming controller 1408 includes a start and UVL circuit 508, a pulse signal generator 504, a trigger monitoring unit 506, a dimmer 1502, a comparator 534, an SR flip-flop 522, and an AND gate 524. . The dimmer 1502 includes a reference signal generator 1506 that generates the reference signal REF, and further includes a PWM generator 1508 that generates the pulse width modulation signal PWM1. As illustrated in FIG. 5, the comparator 534 compares the sense signal 1454 with the reference signal REF to generate a comparison signal COMP. The pulse signal generator 504 generates a pulse signal 536 having a periodic pulse waveform. In one embodiment, the SR flip-flop 522 sets the pulse signal V ₅₂₂ to digital one when the pulse signal 536 is digital one and when the comparison signal COMP is digital one (e.g., the sense signal 1454 is a reference). Reset pulse signal V ₅₂₂ to digital zero (when signal REF is reached). The AND gate 524 receives the pulse signal V ₅₂₂ and the pulse width modulation signal PWM1, and generates the switch control signal 1452 accordingly to control the control switch Q16.

Assuming that the switch Q27 is turned ON, the dimming controller 1408 controls the current I _{LED in} the same manner as the dimming controller 308 described in FIG. 6 and FIG. In one embodiment, the first state of the pulse width modulation signal PWM1 (e.g., PWM1 digital one) in, the AND gate 524 is turned ON and OFF the control switch Q16 alternately in response to the pulse signal V _522. Therefore, the control switch Q16 operates in a switch-on state, and the current I _LED is ramped up when the control switch Q16 is turned on, and is ramped down when the control switch Q16 is turned off. The reference signal REF determines the peak level of the current I _LED by turning off the control switch Q16 when the sense signal 1454 reaches the reference signal REF. During the second state of the pulse width modulation signal PWM1 (for example, PWM1 is digital zero), the AND gate 524 maintains the control switch Q16 to be OFF. Therefore, the control switch Q16 operates in the switch-off state to turn off the current I _LED .

Thus, the reference signal REF is used to determine the peak level of the current I _LED , and the pulse width modulation signal duty cycle PWM1 is used to determine the time ratio between the switch-on state and the switch-off state of the control switch Q16. In other words, the average current I _AVERAGE through the LED light source 312 varies according to the reference signal REF and the duty cycle of the PWM1. For example, I _AVERAGE increases when the voltage V _REF of the reference signal REF increases and decreases when V _REF decreases. Also, I _AVERAGE increases when the _PWM1 duty cycle _DPWM1 increases, and decreases when _DPWM1 decreases.

The dimmer 1502 further includes a counter 1504 that provides a count value. In one embodiment, the reference signal generator 1506 coupled to the counter 1504 determines the voltage level V _REF based on the count value VALUE_1504 of the counter 1504. A PWM generator 1508 coupled to the counter 1504 determines the duty cycle D _PWM1 based on the count value VALUE_1504.

Table 1 and Table 2 show examples of the voltage V _REF and the duty cycle D _PWM1 for the count value VALUE_1504 of the counter 1504. In one embodiment, counter 1504 is a 2-bit counter, so the count value can be 0, 1, 2, or 3. V _MAX represents the maximum voltage level of the reference signal REF. According to Table 1, when the count value VALUE_1504 is 0, 1, 2, and 3, the reference signal REF is level V _MAX , 50% * V _MAX , 20% * V _MAX and 20% * With V _MAX respectively, the duty cycle D _PWM1 has the values 100%, 100%, 100% and 20%, respectively. According to Table 2, when the count value VALUE_1504 is 0, 1, 2, and 3, the reference signal REF is level V _MAX , 50% * V _MAX , 30% * V _MAX and 20% * With V _MAX respectively, the duty cycle D _PMW1 has the values 100%, 60%, 40% and 20%, respectively. The count value, the reference signal REF, and the duty cycle of PWM1 may have other relationships and are not limited to the examples in Table 1 and Table 2.

  In one embodiment, the trigger monitoring unit 506 generates an enable signal 1510 when receiving a dimming request signal indicating, for example, a power shutdown operation of the power switch 304. The counter 1504 receives the enable signal 1510 and increases or decreases the count value accordingly. Therefore, the reference signal generator 1506 determines the reference signal REF according to, for example, Table 1 (Table 1) or Table 2 (Table 2). The PWM generator 1508 determines the duty cycle of PWM1 according to, for example, Table 1 or Table 2.

As a result, the dimming controller 1408 selectively operates in an analog dimming mode, a burst dimming mode, and a combination mode. In analog dimming mode, in one embodiment, the level of the reference signal REF is determined by the count value of the counter 1504 to adjust the average current I _AVERAGE , while the duty cycle D _PWM1 of _PWM1 remains at the same level. It is. In burst dimming mode, in one embodiment, the duty cycle D _PWM1 of _PWM1 is determined by the count value of counter 1504 to adjust the average current I _AVERAGE , while the reference signal REF remains at the same level. . In the combination mode, both the level of the reference signal REF and the duty cycle _DPWM1 are determined according to the count value of the counter 1504. Therefore, the brightness of the LED light source 302 is adjusted. The operation of the dimming controller 1408 is further described in FIGS. The dimming controller 1408 may have other configurations, and is not limited to the example illustrated in FIG.

FIG. 16 shows an example of a diagram illustrating the operation of the light source drive circuit including the dimming controller 1408 of FIG. 15, according to one embodiment of the invention. FIG. 16 is described in combination with FIG. 14A and FIG. FIG. 16 shows voltage V _{CLK at} terminal CLK, count value VALUE_1504 of counter 1504, voltage V _PWM1 of pulse width modulation signal PWM1, duty cycle D _PWM1 of pulse width modulation signal PWM1, voltage V _{REF of} reference signal _REF , sensing signal 1454 The voltage V _SENSE , and the average level I _AVERAGE of the current I _LED . In the example of FIG. 16, the dimming controller 1408 sets the voltage V _REF and the duty cycle D _PWM1 in accordance with the example shown in Table 1.

At time t0, the power switch 304 is OFF. The count value VALUE_1504 is 0. Based on Table 1 (Table 1), the duty cycle D _PWM1 is 100%, the voltage V _REF has a maximum level V _MAX. Since both power switch 304 and switch Q27 are turned off, the current I _LED is cut off and therefore the average current I _AVERAGE is zero.

At time t1, voltage V _CLK has a rising edge indicating the power-on operation of power switch 304. The dimming controller 1408 turns on the switch Q27, and thus the current I _LED is controlled according to the conductive state of the control switch Q16. between t1 and t2, the duty cycle D _PWM1 is 100%, the voltage V _REF has a maximum level V _MAX. The control switch Q16 operates in a switch-on state and is alternately turned ON and OFF. As shown in FIG. 16, the voltage V _SENSE ramps up when the control switch Q16 is turned on and ramps down when the control switch Q16 is turned off. Since the peak level of the voltage V _SENSE is equal to the maximum level V _MAX of the reference signal REF, the average current I _AVERAGE has a maximum level I _MAX .

At time t2, the voltage V _CLK has a falling edge indicating the power shutoff operation of the power switch 304. Switch Q27 is turned off to cut off current I _LED . Thus, between t2 and t3, the voltage V _SENSE drops to approximately zero volts and the average current I _AVERAGE drops to approximately zero amperes.

In one embodiment, a dimming request signal is generated when a power-off operation of the power switch 304 is detected at time t2. The count value VALUE_1504 increases from 0 to 1. Based on the example in Table 1, dimming controller 1408 switches to analog dimming mode and adjusts voltage V _REF to 50% * V _MAX and maintains duty cycle D _PWM1 at 100%.

At time t3, the switch Q27 is turned ON again. Therefore, during the time interval between t3 and t4, the dimming controller 1408 switches the control switch Q16 on and off according to the reference signal REF and the pulse width modulation signal PWM1. Therefore, the average current I _AVERAGE is adjusted to 50% * I _MAX .

At time t4, the voltage V _CLK has a falling edge indicating the power shutoff operation of the power switch 304. The count value VALUE_1504 increases from 1 to 2. Based on Table 1, the dimming controller 1408 will adjust the voltage V _REF to 20% * V _MAX and maintain the duty cycle D _PWM1 at 100% in the analog dimming mode. Therefore, between t5 and t6, the average current I _AVERAGE is adjusted to 20% * I _MAX .

At time t6, the falling edge of the voltage V _CLK indicates the power cutoff operation of the power switch 304. Accordingly, the count value increases from 2 to 3. Based on Table 1, dimming controller 1408 switches to burst dimming mode to maintain voltage V _REF at 20% * V _MAX and reduce duty cycle D _PWM1 to 20%. Thus, when turning on the power switch 304 during the time interval between t7 and t8, the voltage V _SENSE ramps up and down when the voltage V _PWM1 has a first state such as a logic high, V _PWM1 drops to approximately zero volts when it has a second state such as a logic low. Therefore, the average current I _AVERAGE is adjusted to 4% * I _MAX between t7 and t8.

Thus, in the example of FIG. 16, the dimming controller 1408 first operates in analog dimming mode to adjust the average current I _AVERAGE from 100% * I _MAX to 20% * I _MAX , and then burst dimming. Operate in mode to adjust the average current I _AVERAGE from 20% * I _MAX to 4% * I _MAX . Advantageously, both the duty cycle D _PWM1 and the voltage V _REF are adjusted to achieve an average current I _AVERAGE in the range of 100% * I _MAX to 4% * I _MAX . Therefore, dimming of the LED light source 312 is achieved in a wider range. Also, during a relatively wide range of dimming, the voltage V _REF is maintained above a voltage threshold (for example, 15% * V _MAX ) and the duty cycle D _PWM1 is maintained above a duty cycle threshold (for example, 10%). Is done. Therefore, the accuracy of the reference signal REF and the pulse width modulation signal PWM1 is not adversely affected by undesirable conditions such as noise, thereby improving the dimming accuracy of the light source driving circuit 1400.

FIG. 17 shows another example of a diagram illustrating the operation of the light source drive circuit including the dimming controller 1408 of FIG. 15, according to one embodiment of the invention. FIG. 17 is described in combination with FIG. 14A to FIG. FIG. 17 shows voltage V _{CLK at} terminal CLK, count value VALUE_1504 of counter 1504, voltage V _PWM1 of pulse width modulation signal PWM1, duty cycle D _PWM1 of pulse width modulation signal PWM1, voltage V _{REF of} reference signal _REF , sensing signal 1454 The voltage V _SENSE , and the average level I _AVERAGE of the current I _LED . In the example of FIG. 17, the dimming controller 1408 sets the voltage V _REF and the duty cycle D _PWM1 according to the example shown in Table 2.

Between t0 ′ and t2 ′, the dimming controller 1408 operates in the same manner as the operation between t0 and t2 as described in FIG. For example, the count value VALUE_1504 is 0 between t0 ′ and t2 ′. Table 2 on the basis of (Table 2), the duty cycle D _PWM1 is 100%, the voltage V _REF has a maximum level V _MAX. Therefore, between t1 ′ and t2 ′, the peak level of the voltage V _SENSE is equal to the maximum level V _MAX of the reference signal REF, and the average current I _AVERAGE has the maximum level I _MAX .

At time t2 ′, the falling edge of the voltage V _CLK indicates the power cut-off operation of the power switch 304. Switch Q2 is turned OFF to cut off current I _LED . Therefore, between t2 ′ and t3 ′, the voltage V _SENSE drops to approximately zero volts and the average current I _AVERAGE drops to approximately zero amperes.

In one embodiment, a dimming request signal is generated when a power shutdown operation of the power switch 304 is detected at time t2 ′. The count value VALUE_1504 increases from 0 to 1. Based on the example in Table 2, dimming controller 1408 operates in combination mode and adjusts voltage V _REF to 50% * V _MAX and adjusts duty cycle D _PWM1 to 60% . Therefore, between t3 ′ and t4 ′, the control switch Q16 operates in a switch-on state, and alternately according to the pulse signal V ₅₂₂ when the voltage V _PWM1 has a first state such as a logic high. Turn on and off. The peak level of the voltage V _SENSE is equal to the voltage V _REF , ie 50% * V _MAX . Further, the control switch Q16 operates in the switch-off state, and cuts off the current I _LED when the voltage V _PWM1 has the second state such as logic low. Therefore, the average level of the current I _LED is equal to 30% * I _MAX .

At time t4 ′, the falling edge of the voltage V _CLK indicates the power cut-off operation of the power switch 304, and thus a dimming request signal is generated. Accordingly, the count value VALUE_1504 increases from 1 to 2. Based on the example in Table 2, the dimming controller 1408 operates in the combination mode to adjust from the voltage V _REF to 30% * V _MAX and adjust the duty cycle D _PWM1 to 40%. As a result, between t5 ′ and t6 ′, the average level of the current I _LED is equal to 12% * I _MAX .

At time t6 ′, the falling edge of the voltage V _CLK indicates the power cut-off operation of the power switch 304, and thus a dimming request signal is generated. Accordingly, the count value VALUE_1504 increases from 2 to 3. Based on the example in Table 2, the dimming controller 1408 operates in the combination mode to adjust the voltage V _REF to 20% * V _MAX and adjust the duty cycle D _PWM1 to 20%. As a result, between t7 ′ and t8 ′, the average level of the current I _LED is equal to 4% * I _MAX .

Therefore, between t1 ′ and t7 ′, the dimming controller operates in the combination mode when changing the count value VALUE_1504. Advantageously, both the duty cycle D _PWM1 and the voltage V _REF are adjusted to achieve an average current I _AVERAGE in the range of 100% * I _MAX to 4% * I _MAX . The dimming of the LED light source 302 is achieved in a wider dimming range. Also, during a relatively wide range of dimming, the voltage V _REF is maintained above a voltage threshold (for example, 15% * V _MAX ) and the duty cycle D _PWM1 is maintained above a duty cycle threshold (for example, 10%). Is done. Therefore, the accuracy of the reference signal REF and the pulse width modulation signal PWM1 is not adversely affected by undesirable conditions such as noise, thereby improving the dimming accuracy of the light source driving circuit 1400.

  FIG. 18 shows a flowchart 1800 of a method for controlling dimming of an LED light source, according to one embodiment of the present invention. FIG. 18 is described in combination with FIG. 14A to FIG. Although specific steps are disclosed in FIG. 18, such steps are examples. That is, the present invention is well suited for implementing various other steps or variations of the steps described in FIG.

In block 1802, the sensing signal such as sensing signal 1454 indicative of the current through the LED light source such as I _LED is compared with a reference signal, such as the reference signal REF, and supplies a pulse signal such as a pulse signal V _522. In block 1804, the current through the LED light source is controlled in response to a pulse signal during a first state of a pulse width modulated signal such as PWM1. At block 1806, the current through the LED light source is interrupted during the second state of the pulse width modulated signal.

  In block 1808, both the level of the reference signal and the duty cycle of the pulse width modulation signal are adjusted based on the dimming request signal. In one embodiment, the count value of the counter is adjusted in response to the dimming request signal. The level of the reference signal and the duty cycle of the pulse width modulation signal are determined according to this count value. When the count value changes from the first value to the second value, the first mode (for example, analog dimming mode), the second mode (for example, burst dimming mode), or the third mode (for example, , Combination mode) is selected. In the first mode, the level of the reference signal is adjusted and the duty cycle of the pulse width modulated signal is maintained. In the second mode, the level of the reference signal is maintained and the duty cycle of the pulse width modulation signal is adjusted. In the third mode, both the level of the reference signal and the duty cycle of the pulse width modulation signal are adjusted.

FIG. 19 shows an example of a schematic diagram of a light source driving circuit 1900 in an embodiment of the present invention. Elements having the same reference numerals as in FIGS. 3 and 4 have similar functions. FIG. 19 is described in combination with FIG. 3 and FIG. The light source driving circuit 1900 is coupled to the power source V _IN (eg, 110/120 volts AC, 60 Hz) via the power switch 304 and is coupled to the LED light source 312. As described in FIG. 14B, in one embodiment, the power switch 304 is an ON / OFF switch attached to a wall, and the power switch 304 is controlled to be ON or OFF by, for example, a user.

The light source driving circuit 1900 includes an AC / DC converter 306, a power converter 310, and a dimming controller 1908. The AC / DC converter 306 converts the input AC voltage V _IN into the output DC voltage V _OUT . In the example of FIG. 19, the AC / DC converter 306 includes a bridge rectifier having diodes D1, D2, D7, and D8, and includes a filter having a diode D10 and a capacitor C9. The power converter 310 is coupled to the AC / DC converter 306, receives the output DC voltage _VOUT , and supplies the output voltage to the LED light source 312. In one embodiment, power converter 310 includes inductor L1, diode D4, switch Q27, control switch Q16, and current sensor R5. Dimming controller 1908 is coupled to AC / DC converter 306 and power converter 310. The dimming controller 1908 monitors the operation of the power switch 304 such as the power-on operation and / or the power-off operation, and controls the output power supplied to the LED light source 312 accordingly, thereby dimming the LED light source 312. Can be operated to control. The dimming controller 1908 includes a plurality of terminals such as a terminal HV_GATE, a terminal CLK, a terminal VDD, a terminal GND, a voltage control terminal CTRL, a terminal RT, a terminal MON, and a current control terminal CS. The terminals VDD, GND, RT, and MON operate in the same manner as the corresponding terminals of the dimming controller 1408 shown in FIG.

In one embodiment, the dimming controller 1908 receives a switch monitoring signal 1450 that indicates a conductive state, such as an ON / OFF state of the power switch 304 at the terminal CLK. In one embodiment, the dimming controller 1908 controls the switch Q27 in response to the switch monitoring signal 1450. More specifically, when the switch monitoring signal 1450 indicates that the power switch 304 is turned off, the dimming controller 1908 generates a signal such as a logic low at the terminal HV_GATE to turn off the switch Q27. Therefore, the current I _LED passing through the LED light source 312 drops to almost zero amperes and the LED light source 312 is shut off. When the switch monitoring signal 1450 indicates that the power switch 304 is turned on, the dimming controller 1908 generates a signal such as a logic high at the terminal HV_GATE to turn on the switch Q27. Next, the dimming controller 1908 controls the current I _LED that passes through the LED light source 312 in accordance with the signals at the terminal CTRL and the terminal CS.

  In one embodiment, the dimming controller 1908 detects a dimming request signal indicating the operation of the power switch 304 in response to the switch monitoring signal 1450. In one embodiment, the dimming controller 1908 receives the dimming request signal when the switch monitoring signal 1450 indicates that the power switch 304 is performing a power off operation. When the power switch 304 is turned on again, the dimming controller 1908 adjusts the luminance of the LED light source 312 by adjusting the average current passing through the LED light source 312 in response to the dimming request signal.

The dimming controller 1908 can operate in the first mode and the second mode to adjust the average current of the LED light source 312. As described below, current I _LED represents the current passing through LED light source 302. During operation in the first mode, current I _LED is represented as current I _LED1 . During operation in the second mode, the current I _LED is represented as current I _LED2 .

When the dimming controller 1908 operates in the first mode, the voltage control terminal CTRL of the dimming controller 1908 supplies the pulse signal 1952 to the first state such as the switch on state, and the switch off The control switch Q16 is operated alternately in the second state such as the state. Therefore, the current I _LED1 passes through the LED light source 312 and changes according to the state of the control switch Q16. In one embodiment, during the switch-on state of switch Q16, current I _LED1 passes through LED light source 312, switch Q16, resistor R5, and ground. Therefore, the current I _LED1 increases. During the switch-off state of switch Q16, current I _LED1 passes through LED light source 312 and diode D4, thereby decreasing. Thus, in one embodiment, the average current through the LED light source 312 can be adjusted by controlling the control switch Q16 in analog dimming mode, burst dimming mode, and / or combination dimming mode, This is further illustrated in FIG.

When the dimming controller 1908 operates in the second mode, the dimming controller 1908 supplies a control signal 1954 at the voltage control terminal CTRL, such as a digital zero signal, which causes the control switch Q16 to be switched off. maintain. Therefore, the current I _LED1 is cut off. The dimming controller 1908 conducts the current I _LED2 through the LED light source 312 and the current control terminal CS.

Advantageously, the dimming controller 1908 achieves a relatively broad range of dimming by selecting an operating mode from at least the first mode and the second mode. For example, when I _MAX indicates the maximum level of the average current I _AVERAGE , the dimming controller 1908 operates in the first mode and (for example) ranges from 4% * I _MAX to 100% * I _MAX . The average level I _AVERAGE of the current I _LED1 can be adjusted. The dimming controller 1908 can operate in the second mode and adjusts the average current I _AVERAGE to a low level. For example, the dimming controller 1908 sets the current I _LED2 to a constant level 1% * I _MAX . In other words, the second mode LED light source 312 is beneficial for energy efficient light applications such as night lighting, which are adjusted to be darker than the first mode LED light source 312. In addition, the current I _LED2 in the second mode is at a substantially constant level, and this does not change according to the power-on operation and the power-off operation of the switch Q16. Therefore, the light emitted from the light LED light source 312 is not interfered by the switching noise of the switch Q16, thereby enhancing the stability of the illumination of the LED light source 312.

  FIG. 20 shows an example of the configuration of the dimming controller 1908 of FIG. 19 in one embodiment of the present invention. FIG. 20 is described in combination with FIG. 15 and FIG. Elements having the same reference numerals as those in FIGS. 15 and 19 have similar functions. In the example of FIG. 20, the dimming controller 1908 includes a start and UVL circuit 508, a pulse signal generator 504, a trigger monitoring unit 506, a dimmer 2002, a driver 2010, a switch 2008, and a current source 2006.

  In one embodiment, the switch monitoring signal 1450 can be received by the trigger monitoring unit 506 via terminal CLK. The trigger monitoring unit 506 identifies a dimming request signal indicating a power-off operation in response to the switch monitoring signal 1450. When receiving the dimming request signal, the trigger monitoring unit 506 generates an enable signal 1510.

  The dimmer 2002 includes a counter 1504, a reference signal generator 1506, a PWM generator 1508, and a mode selection module 2004. The counter 1504 supplies a count value VALUE_1504 that changes in response to the enable signal 1510. In one embodiment, the counter 1504 increases the count value VALUE_1504 in response to the enable signal 1510. Alternatively, the counter 1504 decreases the count value VALUE_1504 in response to the enable signal 1510.

The mode selection module 2004 selects the operation mode of the dimming controller 1908 from the first mode and the second mode according to the count value VALUE_1504. In one embodiment, the count value VALUE_1504 indicates the required brightness level of the LED light source 312. The necessary luminance level corresponds to the target level I _TARGET of the average current I _AVERAGE of the LED light source 312. An example of the target level I _TARGET and the operation mode of the dimming controller 1908 with respect to the count value VALUE_1504 of the counter 1504 will be described with reference to Table 3 and Table 4 (Table 4). In the example in Table 3, the count value VALUE_1504 can be 0, 1 and 2 indicating the target levels 100% * I _MAX , 30% * I _MAX and 1% * I _MAX respectively, I _MAX represents the maximum level of the average current I _AVERAGE . In the example of Table 4, the count value VALUE_1504 may be 0, 1 and 2 indicating the target levels 1% * I _MAX , 30% * I _MAX and 100% * I _MAX , respectively.

The mode selection module 2004 determines the selection of the operation mode by comparing the count value VALUE_1504 with a threshold value. As an example, the threshold is set to 1 according to the examples in Table 3 and Table 4. In Table 3, the mode selection module 2004 selects the first mode when the count value VALUE_1504 is 1 or less, and selects the second mode when the count value VALUE_1504 is greater than 1. In Table 4, the mode selection module 2004 selects the first mode when the count value VALUE_1504 is 1 or less, and selects the second mode when the count value VALUE_1504 is less than 1. Thus, in the embodiments shown in Table 3 and Table 4, the first mode has a relatively high target level of average current I _AVERAGE , for example, I _TARGET is 30% * I _MAX and Selected when 100 * I _MAX . The second mode is selected when the target level of the average current I _AVERAGE is relatively low, for example, I _TARGET is 1% * I _MAX .

Upon detecting the operating mode, the mode selection module 2004 controls the switch 2008, the reference signal generator 1506, and the PWM generator 1508 to adjust the average current I _AVERAGE . More specifically, in one embodiment, current source 2006 generates a substantially constant current I _LED2 . While operating in the first mode, the mode selection module 2004 _turns off the switch 2008 to cut off the current I _LED2 , controls the reference signal generator 1506 to generate the reference signal REF, and controls the PWM generator 1508 Then, the pulse width modulation signal PWM1 is generated. In one embodiment, driver 2010 uses reference signal REF and pulse width modulation signal PWM1 to generate pulse signal 1952 to control switch Q16.

In one embodiment, driver 2010 includes a comparator 534, an SR flip-flop 522, and an AND gate 524. When the first mode is selected, the driver 2010 operates similarly to the corresponding components of the dimming controller 1408 of FIG. As illustrated in FIG. 15, the comparator 534 compares the sense signal 1454 with the reference signal REF to generate a comparison signal COMP. The pulse signal generator 504 generates a pulse signal 536 having a periodic pulse waveform. In one embodiment, the SR flip-flop 522 sets the pulse signal V ₅₂₂ to digital one when the pulse signal 536 is digital one and when the comparison signal COMP is digital one (e.g., the sense signal 1454 is Reset pulse signal V ₅₂₂ to digital zero (when reference signal REF is reached). The AND gate 524 receives the pulse signal V ₅₂₂ and the pulse width modulation signal PWM1, and accordingly generates the pulse signal 1952 at the terminal CTRL to control the control switch Q16. Therefore, when the pulse width modulation signal PWM1 is in the first state such as digital one, the pulse signal 1952 is equal to the pulse signal V ₅₂₂ , which is digital one and digital zero depending on the result of the comparison signal COMP. Can be switched between. When the pulse width modulation signal PWM1 is in a second state such as digital zero, the pulse signal 1952 remains digital zero. As described in FIG. 15, the reference signal REF determines the peak level of the current I _LED1 . The duty cycle PWM1 of the pulse width modulation signal determines the ratio between the time when the switch Q16 is turned on and the time when the switch Q16 is turned off. Therefore, by adjusting the duty cycle PWM1 of the reference signal REF and / or the pulse width modulation signal, the dimmer 2002 operates in analog dimming mode, burst dimming mode, and combination dimming mode, and the average current I _AVERAGE can be adjusted.

According to the example in Table 3, when the count value VALUE_1504 is 0, the dimming controller 1908 operates in the first mode, the reference signal REF has the level V _REF0 , and the pulse width modulation signal The duty cycle PWM1 has the value D _PWM0 . When the count value VALUE_1504 changes from 0 to 1, the dimming controller 1908 remains in the first mode and the target level of the average current I _AVERAGE changes from 100% * I _MAX to 30% * I _MAX To do. When the dimmer 2002 operates in the analog dimming mode, the level of the reference signal REF is adjusted to 30% * V _REFO and the duty cycle of PWM1 remains the same value D _PWM0 . When the dimmer 2002 operates in the burst dimming mode, the level of the reference signal REF remains at the same level V _REFO , while the duty cycle of PWM1 is adjusted to 30% * D _PWM0 . When the dimmer 2002 operates in the combination mode, both the level of the reference signal REF and the duty cycle of the PWM1 change, for example, the level of the reference signal REF is 50% * V _REFO , and the duty cycle of the PWM1 is 60 % * D _PWM0 . In all three cases, the average current I _AVERAGE can be adjusted from 100% * I _MAX to 30% * I _MAX to achieve dimming control of the LED light source 312 in the first mode.

When the dimming controller 1908 operates in the second mode, for example, when the count value VALUE_1504 changes from 1 to 2 according to Table 3, the dimming controller 1908 is connected to the voltage control terminal CTRL Then, a control signal 1954 is generated to turn off the switch Q16. More specifically, the mode selection module 2004 controls the PWM generator 1508 to maintain the pulse width modulation signal PWM1 in the second state such as digital zero. AND gate 524 maintains the voltage at a low electrical level at terminal CTRL and generates a control signal 1954 such as a digital zero signal. Accordingly, the current I _LED1 passing through the LED light source 312 is blocked.

In addition, in one embodiment, current source 2006 generates a substantially constant current I _LED2 . The mode selection module 2004 generates a switch control signal 2012 and turns on the switch 2008. The current path for the current I _LED2 is conducted after the power switch operation of the power switch 304, for example, when the switch Q27 is turned on. Therefore, the current I _LED2 passes through the LED light source 312, the current control terminal CS, the switch 2008, and the ground. As used herein, “substantially constant current I _LED2 ” means that current I _LED2 can vary but current ripple caused by non-idealities of circuit components can be ignored. It means that there is. Advantageously, the current I _LED2 is not adversely affected by the switching noise of one or more switches, such as the power switch 304 and / or the switch Q16, so that the line interface of the light source 312 can be reduced or eliminated. Therefore, the illumination stability of the light source driving circuit 1900 is further improved. The dimming controller 1908 may have other configurations and is not limited to the example illustrated in FIG.

FIG. 21 shows an example of a diagram illustrating the operation of the light source driving circuit including the dimming controller 1908 of FIG. 19 in one embodiment of the present invention. FIG. 21 is described in combination with FIG. 19 and FIG. FIG. 21 shows voltage V _{CLK at} terminal CLK, count value VALUE_1504 of counter 1504, voltage V _PWM1 of pulse width modulation signal PWM1, duty cycle D _PWM1 of pulse width modulation signal PWM1, current I _LED passing through LED light source 312, and The average level I _AVERAGE of the current I _LED is shown. In the example of FIG. 19, the dimming controller 1908 determines the operation mode, and controls the average current of the LED light source 312 according to Table 3.

At time t0 ", the power switch 304 is OFF. The dimming controller 1908 turns OFF the switch Q27. The count value VALUE_1504 is 0. Based on Table 3, the mode selection module 2004 is Select the first mode, the target level of the average current I _AVERAGE is 100% * I _MAX , so the PWM generator 1508 adjusts the duty cycle D _PWM1 to 100% and the reference signal generator 1506 , Control the reference signal REF to adjust the peak value of the current I _LED to I _PEAK such as the maximum level of the peak value. At time t1 ", the voltage V _{CLK at the} CLK pin causes the power switch 304 to power up. As a result, the average current I _AVERAGE is adjusted to 100% * I _MAX when having the rising edge shown. Between times t1 "and t2", the average current I _AVERAGE is maintained at 100% * I _MAX .

At time t2 ", the voltage V _CLK has a falling edge that indicates the power cut-off operation of the power switch 304. The switch Q27 is turned off to cut off the current I _LED . Therefore, the current between t2" and t3 " The I _LED drops to approximately zero amperes, and the average current I _AVERAGE drops to approximately zero amperes.

In one embodiment, a dimming request signal is received upon detecting a power off operation of the power switch 304 at time t2 ". The count value VALUE_1504 increases from 0 to 1. According to Table 3, the mode The selection module 2004 remains in the first mode from time t2 "to time t4" and the target level of the average current I _AVERAGE is adjusted to 30% * I _MAX . In the example of FIG. 2002 operates in a combination mode where the PWM generator 1508 adjusts the duty cycle D _PWM1 to 60%, the reference signal generator 1506 controls the reference signal REF, and the peak value of the current I _LED is 50% * I _The average current I _AVERAGE is adjusted to 30% * I _MAX when the voltage V _{CLK at the CLK} terminal has a rising edge indicating the power-up operation of the power switch 304 at time t3 ". The Between times t3 "and t4", the average current I _AVERAGE is maintained at 30% * I _MAX .

At time t4 ", the falling edge of the voltage V _CLK indicates the power cut-off operation of the power switch 304, and therefore receives a dimming request signal. In response, the count value VALUE_1504 increases from 1 to 2. 3 (Table 3), the target level of the average current I _AVERAGE is adjusted to 1% * I _MAX and the mode selection module 2004 selects the second mode, so the mode selection module 2004 Generate control signal 2012 and turn on switch 2008. Since power switch 304 and switch Q27 are OFF between t4 "and t5", both current I _LED and average current I _AVERAGE are zero amperes is there.

At time t5 ", the voltage V _CLK has a rising edge indicating the power-on operation of the power switch 304. Since the switch Q27 is turned on after the power-on operation of the power switch 304 and the switch 2008 is also turned on at time t4", The current path of the current I _LED2 is conducted. In one embodiment, the current I _LED2 is equal to 1% * I _MAX . Therefore, the average current I _AVERAGE is maintained at 1% * I _MAX between t5 ″ and t6 ″.

Therefore, between t1 ″ and t6 ″, the dimming controller 1908 selects an operation mode from the first mode and the second mode according to the count value VALUE — 1504. Advantageously, the dimming controller 1908 achieves a relatively wide dimming range, for example, a range of 100% * I _MAX to 1% * I _MAX . The operation of the dimming controller 1908 is not limited to the example shown in FIG. In another embodiment, during the second mode, the dimming controller 1908 provides another current, for example with a smaller constant current level 0.01 * I _MAX , and passes through the LED light source 312 and the terminal CS. Can be. Therefore, the luminance of the LED light source 312 can be lowered, and a wider dimming range is achieved. In addition, current I _LED2 is at a substantially constant level, and current I _LED2 does not change according to the power-on operation and power-off operation of switch Q16. Therefore, the light emitted by the LED light source 312 is not interfered by the switching noise of the switch Q16, thereby increasing the lighting stability of the LED light source 312.

  FIG. 22 shows a flowchart 2200 of operations performed by a source dimming controller, such as dimming controller 1908, in one embodiment of the invention. FIG. 22 is described in combination with FIG. 19 to FIG. Although specific steps are disclosed in FIG. 22, such steps are examples. That is, the present invention is well suited to implementing various other steps or variations of the steps described in FIG.

  In block 2202, a light source such as an LED light source 312 is powered by a regulated voltage from a power converter such as power converter 310.

  At block 2204, a switch monitoring signal is received. The switch monitoring signal indicates the conductive state of a power switch, such as power switch 304, coupled between the power source and the power converter.

  In block 2206, the operating mode is selected from at least a first mode and a second mode in response to the switch monitoring signal. In one embodiment, when receiving a switch monitoring signal indicating a power shutdown operation of the power switch, the count value of the counter changes from the first value to the second value accordingly. The count value is compared with a threshold value such as 1, and the operation mode is selected according to the comparison result.

In block 2208, a control switch, such as switch Q16, selects a first state, such as a switch-on state, and a second state, such as a switch-off state, in response to a pulse signal such as a pulse signal 1952 when the first mode is selected. Operate between states. In one embodiment, a first current passing through an LED light source, such as I _LED1 , increases during a first state of the control switch and decreases during a second state of the control switch. In one embodiment, when the first mode is selected, a reference signal such as the reference signal REF and a pulse width modulation signal such as the pulse width modulation signal PWM1 are received. When the first mode is selected, the sense signal including the first current passing through the LED light source is compared with a reference signal. The control switch turns on and off according to the comparison result of the pulse width modulation signal during the first state such as digital one, and turns off during the second state of the pulse width modulation signal such as digital zero. Become. In one embodiment, when the count value changes from the third value to the fourth value, while still operating in the first mode, the level of the reference signal and the duty cycle of the pulse width signal are Adjusted to adjust brightness.

In block 2210, when the second mode is selected, a first current, such as current I _LED1 , is interrupted in response to a control signal, such as control signal 1954. In one embodiment, in the second mode, the pulse width modulated signal is maintained in a second state, such as digital zero, to generate a control signal, such as a digital zero signal, to block the first current.

At block 2212, a substantially constant current, such as current I _LED2 , passes through the LED light source 312 when the second mode is selected. In one embodiment, current I _LED2 is provided by a current source, such as current source 2006. When the second mode is selected, the mode selection module 2004 generates a switch control signal 2012 to turn on the switch 2008 coupled in series with the current source 2006.

  Although the foregoing description and drawings represent embodiments of the present invention, various additions, modifications and replacements may be made therein without departing from the spirit and scope of the principles of the invention as defined in the appended claims. It will be appreciated that can be done. The invention is not limited to the forms, structures, configurations, ratios, materials, elements, elements, and many others used in the practice of the invention, specifically tailored to the particular environment and operating requirements without departing from the principles of the invention. One skilled in the art will appreciate that it can be used with modification. Accordingly, the embodiments disclosed herein are to be considered in all respects as illustrative and not restrictive, and the scope of the present invention is defined by the appended claims and their legal It is shown by an equivalent thing and is not limited to the above description.

300 Light source drive circuit
302 LED light source
304 Power switch
306 AC / DC converter
308 Dimming controller
310 Power converter
312 LED string, LED light source
314 Current sensor

Claims (28)

A dimming controller for a light emitting diode (LED) light source,
A voltage control terminal configured to supply a pulse signal that operates the control switch in one of a first state and a second state when the dimming controller operates in the first mode; The first current passing through the LED light source increases during operation of the control switch in the first state, decreases during operation of the control switch in the second state, and the dimming A voltage control terminal for supplying a control signal to the control switch to cut off the first current when the controller operates in a second mode;
A dimming controller comprising: a current control terminal configured to conduct a second current through the LED light source when the dimming controller operates in the second mode;   2. The dimming controller of claim 1, wherein the second current has a substantially constant level. A monitoring terminal configured to receive a switch monitoring signal indicative of a conductive state of a power switch coupled between a power source and a power converter, wherein the power converter receives an input voltage from the power source and the LED A monitoring terminal for supplying an output voltage to supply power to the light source;
2. A dimmer coupled to the monitoring terminal and configured to select an operation mode from the first mode and the second mode in response to the switch monitoring signal. Dimming controller. The dimmer is
A counter configured to provide a count value that changes in response to the switch monitoring signal;
4. A dimming controller according to claim 3, comprising a mode selection module coupled to the counter and configured to select the operation mode in response to the count value.   5. The dimming controller according to claim 4, wherein the mode selection module selects the operation mode by comparing the count value with a threshold value.   5. The dimming device according to claim 4, wherein the counter changes the count value from a first value to a second value when the switch monitoring signal indicates that the power switch performs a power shut-off operation. Controller. A dimmer configured to provide a reference signal and a pulse width modulated signal;
Coupled to the dimmer and configured to compare the reference signal with a sensing signal indicative of the first current through the LED light source, based on the result of the comparison and operating in the first mode 2. The dimming controller of claim 1, further comprising a driver further configured to generate the pulse signal based on the pulse width modulation signal.   When the pulse width modulation signal has a first state and a second state, and the pulse signal has the pulse width modulation signal in the first state, the control switch is turned on according to the comparison result. 8. The dimming controller according to claim 7, wherein the dimming controller is turned on and off, and the control switch is turned off when the pulse width modulation signal is in the second state.   8. The dimming controller of claim 7, wherein the first current decreases until a predetermined current level is reached when the pulse width modulation signal is in a second state.   When the dimming controller switches to the second mode, the dimmer maintains the pulse width modulation signal in the second state, and the control signal is generated at the voltage control terminal. 8. The dimming controller according to claim 7, wherein the first current is cut off. The dimmer is
A counter configured to provide a count value;
During operation in the first mode, the dimmer maintains the level of the reference signal when the count value changes from a first value to a second value, and the pulse width modulation signal 8. The dimming controller of claim 7, wherein the dimming controller adjusts the duty cycle. The dimmer is
A counter configured to provide a count value;
During operation in the first mode, the dimmer adjusts the level of the reference signal when the count value changes from a first value to a second value, and the pulse width modulation signal 8. The dimming controller of claim 7, wherein the dimming controller is maintained. The dimmer is
It has a counter that gives count values,
During operation in the first mode, when the count value changes from a first value to a second value, the dimmer is configured so that the level of the reference signal and the duty of the pulse width modulation signal The dimming controller of claim 7, wherein the dimming controller adjusts the cycle together. A current source configured to generate the second current;
A second switch coupled to the current source;
When the dimming controller operates in the second mode, the second switch is turned on to conduct the second current through the current control terminal and the LED light source. The dimmer further comprising a dimmer further configured to turn off the second switch and shut off the second current when the light controller operates in the first mode. Dimming controller as described. A power converter configured to receive an input voltage from a rectifier and supply an output voltage to a light emitting diode (LED) light source, wherein a power switch is connected from an AC power source to the rectifier when the power switch is on. A power converter that transmits power,
A dimming controller coupled to the power converter and configured to detect a dimming request signal indicative of an operation of the power switch, the dimming of the LED light source in response to the dimming request signal An electronic system comprising a dimming controller capable of operating in a mode selected from a first mode and a second mode to control
During operation in the first mode, the dimming controller supplies a pulse signal to a voltage control terminal to control a first current passing through the LED light source, and the first current is When the pulse signal increases during the first state, decreases during the second state of the pulse signal, and operates in the second mode, the dimming controller applies a control signal to the voltage control terminal. An electronic system that supplies and blocks the first current and transmits a substantially constant current through the LED light source. A control switch coupled to the LED light source and controlled by the pulse signal and the control signal;
During the operation in the first mode, the control switch is turned on and off in response to the pulse signal, and during the operation in the second mode, the control switch is kept off in response to the control signal. 16. The electronic system of claim 15, wherein The dimming controller is
A trigger monitoring unit configured to receive a switch monitoring signal indicative of a conductive state of a power switch, and further configured to detect the dimming request signal in response to the switch monitoring signal;
A counter configured to provide a count value that changes in response to the dimming request signal;
16. The electronic device of claim 15, further comprising a mode selection module coupled to the counter and configured to select the operation mode from the first mode and the second mode in response to the count value. system.   18. The electronic system of claim 17, wherein the trigger monitoring unit receives the dimming request signal when the switch monitoring signal indicates that the power switch performs a power shutdown operation.   18. The electronic system according to claim 17, wherein the mode selection module selects the operation mode by comparing the count value with a threshold value. The dimming controller is
A driver configured to receive a reference signal and a pulse width modulated signal and further configured to compare the reference signal and a sensing signal indicative of the first current passing through the LED light source; While operating in the mode of 1, using the pulse width modulation signal in the first state, the driver uses the first state of the pulse signal and the second state of the pulse signal according to the result of the comparison 16. The electronic system according to claim 15, wherein the pulse signal is switched between and wherein the pulse signal in a second state is maintained using the pulse width modulation signal in a second state. The dimming controller is
Further comprising a dimmer coupled to the driver and configured to maintain the level of the reference signal and adjust the duty cycle of the pulse width modulation signal when receiving the dimming request signal. 21. The electronic system according to claim 20. The dimming controller is
A dimmer configured to adjust the level of the reference signal and maintain the duty cycle of the pulse width modulation signal when coupled to the driver and receiving the dimming request signal; 21. The electronic system according to claim 20. The dimming controller is
A dimmer configured to couple to the driver and to adjust both the level of the reference signal and the duty cycle of the pulse width modulation signal when receiving the dimming request signal. 20. The electronic system according to 20.   When the dimming controller switches to the second mode, the driver terminates the pulse signal and generates the control signal by holding the pulse width modulation signal in a second state. Item 20. The electronic system according to Item 20. A method of adjusting the power of a light emitting diode (LED) light source,
Supplying power to the light source by a regulated voltage from a power converter;
Receiving a switch monitoring signal indicative of a conductive state of a power switch coupled between a power source and the power converter;
Selecting an operation mode from at least a first mode and a second mode in response to the switch monitoring signal;
When the first mode is selected, operating a control switch in one of a first state and a second state, wherein the first current passing through the LED light source is Increasing during operation in a first state and decreasing during operation in the second state; and
Cutting off the first current when the second mode is selected;
Conducting a substantially constant current through the LED light source when the second mode is selected. Receiving a reference signal and a pulse width modulated signal;
Comparing a sensing signal indicative of the first current and the reference signal during operation in the first mode;
When the first mode is selected, according to the result of the comparison using the pulse width modulation signal in the first state, turning the control switch ON and OFF,
Turning off the control switch using the pulse width modulation signal in a second state when the first mode is selected;
26. The method of claim 25, further comprising: maintaining the pulse width modulated signal in a second state and interrupting the first current when the second mode is selected. Supplying a count value that changes from a first value to a second value when the switch monitoring signal indicates that the power switch performs a power shutoff operation; and
26. The method of claim 25, further comprising: comparing the count value with a threshold to select the operating mode from the first mode and the second mode. Adjusting the level of the reference signal and the duty cycle of the pulse width modulation signal when the count value changes from a first value to a second value during the first mode operation; 28. The method of claim 27, comprising.

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