Subject matter disclosed herein relates generally to electronic circuits and, more particularly, to driver circuits for use in driving light emitting diodes (LEDs) and/or other loads.
Light emitting diode (LED) driver circuits are circuits that are used to drive one or more LEDs, typically in a controlled manner. In some instances, LED driver circuits are configured to drive multiple series-connected strings of diodes, known as “LED channels,” but driver circuits that drive single channels, or single diodes, also exist. When driving multiple LED channels, the channels may be operated in parallel with a common voltage node supplying all of the channels. A DC-DC converter (e.g., a boost converter, a buck converter, etc.) may be employed by the LED driver circuit for use in regulating a voltage level associated with the driven LEDs to ensure that all LEDs have adequate operational power. Feedback from the LEDs may be used to control the DC-DC converter. To reduce unnecessary power consumption, the regulated voltage level maintained by the DC-DC converter may be kept to a minimum or near minimum, while still providing adequate power to all LEDs.
During LED driver operation, it may be desirable to vary the light intensity of some or all of the LEDs. One technique for doing this involves driving the LEDs at a variable duty cycle (known as the dimming duty cycle). When a higher duty cycle is applied to the LEDs, a higher light intensity is typically generated. Likewise, when a lower duty cycle is applied to the LEDs, a lower light intensity is generated. Problems may occur, however, when attempting to drive LEDs at dimming duty cycles that are very low. For example, in some systems, a controller associated with a DC-DC converter may be unable to accurately track feedback levels when a dimming duty cycle is too low becalm the LEDs will be “off” for a relatively long time.
In addition, in some cases, a “turn on” time of the LEDs may limit the ability of a driver to support low dimming duty cycles. An LED driver circuit will typically take a finite amount of time to reach a desired LED current level once a drive signal is applied. Any “feedback” provided to the DC-DC converter controller during this “turn on” time can be error prone as the corresponding signal values are in a state of transition. For this reason, feedback blanking is often used to blank out portions of the feedback signal that occur during the “turn on” time. If the “turn on” time of the driver is comparable in duration to then time of the dimming duty cycle (i.e., the time period during which the corresponding LEDs are to be energized), then the DC-DC converter may not have adequate time to properly regulate the target voltage using the available feedback (i.e., the available portion of the feedback signal is not long enough to allow the target voltage to adapt).
Techniques and circuits are needed for improving the ability of LED drivers to operate under short dimming duty cycles.
In accordance with one aspect of the concepts, systems, circuits, and techniques described herein, a method for use in driving one or more LED loads, comprises: regulating a voltage associated with at least one LED load; and varying a regulated voltage value used during regulating based, at least in part, on a present dimming duty cycle associated with the at least one LED load.
In one embodiment, varying a regulated voltage value includes varying the regulated voltage value according to a function that decreases monotonically with increasing dimming duty cycle.
In one embodiment, varying a regulated voltage value comprises using a fixed regulated voltage value if the present dimming duty cycle of the at least one LED load is above a first threshold value and using a variable regulated voltage value that is greater than the fixed regulated voltage value if the present dimming duty cycle of the at least one LED load is below the first threshold value.
In one embodiment, the first threshold value corresponds to a dimming duty cycle between 5 percent and 20 percent.
In one embodiment, varying a regulated voltage value comprises using a first fixed regulated voltage value if the present dimming duty cycle of the at least one LED load is above a first threshold value and using a second fixed regulated voltage value if the present dimming duty cycle of the at least one LED load is below a second threshold value.
In one embodiment, varying a regulated voltage value comprises using a variable regulated voltage value that varies between the first fixed regulated voltage value and the second fixed regulated voltage value if the present dimming duty cycle of the at least one LED load is between the first threshold value and the second threshold value.
In one embodiment, the at least one LED load includes an LED channel that is coupled to a current regulation device to regulate a current flowing through the LED channel; and regulating a voltage associated with at least one LED load includes regulating a voltage across the current regulation device; wherein varying a regulated voltage value used during regulating includes varying the regulated voltage value in a manner that improves LED current accuracy for low dimming duty cycles.
In accordance with another aspect of the concepts, systems, circuits, and techniques described herein, a method for use in driving one or more light emitting diodes (LEDs) using a DC-DC converter comprises: determining a dimming duty cycle for at least one LED; determining a regulated voltage value to be used in connection with the at least one LED based, at least in part, on the dimming duty cycle; and generating a control signal for the DC-DC converter based on the regulated voltage value and feedback associated with the at least one LED.
In one embodiment, determining a dimming duty cycle includes extracting the dimming duty cycle from a pulse width modulation (PWM) control signal associated with the at least one LED.
In one embodiment, determining a regulated voltage value includes determining a regulated voltage value to appear across a current regulation device associated with the at least one LED.
In one embodiment, the one or more LEDs includes multiple parallel LED channels that are each coupled to a corresponding current regulation device, wherein determining a regulated voltage value includes determining a regulated voltage value to appear across a current regulation device associated with one of the multiple LED channels.
In one embodiment, determining a dimming duty cycle includes determining a dimming duty cycle to be used in all of the multiple parallel LED channels that are presently enabled.
In one embodiment, determining a regulated voltage value to appear across a current regulation device associated with one of the multiple LED channels includes determining a regulated voltage value to appear across a current regulation device associated with a dominant channel.
In one embodiment, the one or more LEDs includes multiple parallel LED channels that are each coupled to a corresponding current regulation device, wherein determining a regulated voltage value includes determining an average voltage value to appear across the current regulation devices associated with the multiple LED channels.
In one embodiment, determining a regulated voltage value includes determining a value in accordance with a function that decreases monotonically with increasing dimming duty cycle.
In one embodiment, the function is adapted to achieve enhanced operational efficiency for higher dimming duty cycles and enhanced LED current accuracy for lower dimming duty cycles.
In one embodiment, determining a regulated voltage value includes determining the regulated voltage value by evaluating an equation.
In one embodiment, determining a regulated voltage value includes determining the regulated voltage value using a lookup table (LUT).
In one embodiment, determining a regulated voltage value includes using a first voltage value if the dimming duty cycle is above a first threshold level and using a variable voltage value that is higher than the first voltage value if the dimming duty cycle is below the first threshold level.
In one embodiment, determining a regulated voltage value includes: using a first voltage value if the dimming duty cycle is above a first threshold level; using a second voltage value if the dimming duty cycle is below a second threshold level, wherein the second voltage value is greater than the first voltage value; and using a variable voltage value that varies between the first and second voltage values if the dimming duty cycle is between the first and second threshold levels.
In one embodiment, the method further comprises: continually repeating determining a dimming duty cycle, determining a regulated voltage value, and generating a control signal while driving the one or more light emitting diodes (LEDs).
In accordance with a further aspect of the concepts, systems, circuits, and techniques described herein, a light emitting diode (LED) driver circuit to drive one or more LEDs using a DC-DC converter comprises: dimming control circuitry to set a dimming duty cycle of at least one LED, wherein the dimming control circuitry is capable of changing the dimming duty cycle of the at least one LED over time; regulated voltage determination circuitry to determine a regulated voltage value to use in connection with the at least one LED based, at least in part, on the dimming duty cycle; and a DC-DC converter controller to generate a control signal for the DC-DC converter based on the regulated voltage value and feedback associated with the at least one LED.
In one embodiment, the dimming control circuitry is configured to generate a pulse width modulation (PWM) control signal for use with the at least one LED based on the dimming duty cycle; and the regulated voltage determination circuitry includes a duty cycle extractor to receive the PWM control signal and to extract the dimming duty cycle therefrom for use in determining the regulated voltage value.
In one embodiment, the regulated voltage determination circuitry is implemented primarily in analog circuitry.
In one embodiment, the regulated voltage determination circuitry is implemented primarily in digital circuitry.
In one embodiment, the regulated voltage determination circuitry is configured to determine the regulated voltage value in accordance with a function that decreases monotonically with increasing dimming duty cycle.
In one embodiment, the regulated voltage determination circuitry is configured to output a fixed regulated voltage value if the dimming duty cycle is above a first threshold value and to output a variable regulated voltage value that is greater than the fixed regulated voltage value if the dimming duty cycle is below the first threshold value.
In one embodiment, the first threshold value corresponds to a dimming duty cycle between 5 and 20 percent.
In one embodiment, the regulated voltage determination circuitry is configured to output a first fixed regulated voltage value if the dimming duty cycle is above a first threshold value, to output a second fixed regulated voltage value if the dimming duty cycle is below a second threshold value, and to output a variable regulated voltage value that varies between the first fixed regulated voltage value and the second fixed regulated voltage value if the dimming duty cycle is between the first threshold value and the second threshold value.
In one embodiment, the regulated voltage determination circuitry includes a lookup table for use in determining a regulated voltage value based on the dimming duty cycle.
In one embodiment, the at least one LED includes multiple LEDs arranged in a number of LED channels; and the LED driver circuit includes a current regulation device for each of the LED channels; wherein the regulated voltage determination circuitry is configured to determine a regulated voltage value to appear across the current regulation device associated with a dominant LED channel.
In one embodiment, the LED driver circuit is implemented as an integrated circuit having at least one contact for connection to an external DC-DC converter.
In one embodiment, the one or more LEDs includes multiple LEDS arranged in a number of LED channels; the dimming control circuitry is capable of generating different pulse width modulation (PWM) control signals for use in switching different LED channels in accordance with different dimming duty cycles; and the regulated voltage determination circuitry includes multiple duty cycle extractors to extract dimming duty cycles from different PWM control signals.
In one embodiment, the LED driver circuit is capable of driving multiple LEDs at variable load current and over a wide dimming range while generating little or no audible noise.
The foregoing features may be more fully understood from the following description of the drawings in which:
In the arrangement shown in
As shown in
As described above, the boost converter 14 is operative for converting a DC input voltage VIN to a DC output voltage VOUT that is adequate to supply the LED(s) 16. The operating principles of boost converters and other types of DC-DC converters are well known in the art. During operation, the boost control circuitry 18 provides a switching signal to a switching node 36 (SW) of the boost converter 14. The switching signal draws current from the switching node 36 at a controlled duty cycle to regulate a voltage associated with the LED(s) 16 in a closed loop manner. It should be understood that the duty cycle used to control the boost converter 14 is a different parameter from the dimming duty cycle used to adjust the illumination intensity of the LED(s) 16. In the illustrated embodiment, the boost converter 14 includes an inductor 30, a diode 32, and a capacitor 34 coupled together in a specific configuration. Other boost converter architectures may alternatively be used.
To control the duty cycle of the boost converter 14, the boost control circuitry 18 uses feedback from the LED(s) 16. As shown in
In conventional drivers, the regulated voltage associated with the LED(s) 16 (e.g., the voltage across the current sink 24, etc.) would be kept constant throughout driver operation. Typically, a single voltage level would be selected (e.g., the regulation voltage, etc.), and this value would not change. In developing the techniques and systems described herein, it was found that, while a particular regulated voltage level may be acceptable during high dimming duty cycles, the same voltage level may result in a compromised ability to accurately set LED current levels when lower dimming duty cycles are used. In this regard, in one aspect of the features described herein, the regulated voltage level that is used in an LED driver is varied during driver operation based on dimming duty cycle. Thus during higher dimming duty cycles, lower regulated voltage levels may be used by a driver and, during lower dimming duty cycles, higher regulated voltage levels may be used. The higher regulated voltage levels may ensure that an adequate voltage level exists on a current sink during low dimming duty cycle operation to enable accurate current tracking.
As described previously, the LED driver dimming control circuitry 56 and the LED driver DC current control circuitry 58 may provide control signals to each of the current sinks 64, 66, 68 to control the dimming and DC current, respectively, of the corresponding LED channels. In some multi-channel embodiments, the LED driver circuitry 52 may use the same dimming duty cycle for all of the LED channels 54a, 54b, 54n. In other multi-channel embodiments, the LED driver circuitry 52 may allow different dimming duty cycles to be used in different channels. The LED driver dimming control circuitry 56 and the LED driver DC current control circuitry 58 may each include an input to receive control signals from one or more external controllers that are indicative of desired dimming and current values. The LED driver dimming control circuitry 56 and the LED driver DC current control circuitry 58 may also, in some implementations, be user configurable/programmable to allow a user to set desired dimming and/or current values. One or more data storage locations may be provided within the LED driver circuitry 52 to store user-provided configuration information to set operational parameters such as, for example, dimming duty cycle and LED current level. Default values may be used for the different parameters in the absence of user provided values.
In some implementations, the LED driver dimming control circuitry 56 and the LED driver DC current control circuitry 58 may allow one or more of the LED channels 54a, 54b, 54n to be temporarily disabled by a user. These channels will not illuminate until they are eventually re-enabled. The LED driver dimming control circuitry 56 and the LED driver DC current control circuitry 58 may be implemented using digital, analog, or a combination of digital and analog circuitry.
Although LED driver system 50 is depicted with a boost converter 14 and boost control circuitry 60 in
In some embodiments, different LED channels being driven by an LED driver system may be allowed to have different numbers of LEDs. For example, as shown in
As described above, the regulated voltage determination circuitry 62 of the LED driver circuitry 52 is operative for determining a regulated voltage value for use in connection with the LEDs 54, based on dimming duty cycle. The regulated voltage value may then be used by the boost control circuitry 60 to regulate a voltage associated with the LEDs 54. The regulated voltage determination circuitry 62 may receive information from the LED driver dimming control circuitry 56 that is indicative of a dimming duty cycle to be used by some or all of the LEDs 54. The regulated voltage determination circuitry 62 may then use this information to determine a regulated voltage value. The regulated voltage value may then be delivered to the boost controller 60. In some embodiments, the information received from the LED driver dimming control circuitry 56 may include, for example, a dimming duty cycle value that may be used to select an appropriate regulated voltage value. In some other embodiments, the regulated voltage determination circuitry 62 may receive a signal from the LED driver dimming control circuitry 56 from which the dimming duty cycle can be extracted. For example, the regulated voltage determination circuitry 62 may receive a pulse width modulation (PWM) control signal from the LED driver dimming control circuitry 56 that is associated with one or more LED channels 54a, 54b, 54n (e.g., a signal that is used to control one or more of the current sinks 64, 66, 68, etc.). In these embodiments, the regulated voltage determination circuitry 62 may be configured to extract the dimming duty cycle value from the received signal and then use the extracted value to determine the regulated voltage value. In other embodiments, other types of dimming duty cycle related information may be provided to the regulated voltage determination circuitry 62 from the LED driver dimming control circuitry 56.
As described above, the regulated voltage determination circuitry 62 may deliver the regulated voltage value it determines to the boost control circuitry 60. As shown in
As described above, in some embodiments, the same dimming duty cycle may be used for all of the LED channels 54a, 54b, 54n coupled to LED driver circuitry 52. In these embodiments, a single regulated voltage determination circuit 62 may be provided. In other embodiments, LED driver circuitry 52 may be capable of setting a different dimming duty cycle for each of the LED channels 54a, 54b, 54n. In these embodiments, a different regulated voltage determination circuit 62 may be provided for each LED channel 54a, 54b, 54n. A maximum selector circuit (not shown) may then be used to select the highest regulated voltage value from amongst the values generated by the different regulated voltage determination circuits 62 for delivery to the boost controller 60. In an alternative approach, a minimum selector circuit may be provided to select a lowest dimming duty cycle from amongst the different LED channels. The lowest dimming duty cycle may then be used to generate a corresponding regulated voltage level for the boost control unit 60.
The function 98 returns a second fixed regulated voltage value for dimming duty cycles that are below a second threshold level (e.g., a voltage of V2 for dimming duty cycles below 0.01 percent in the illustrated embodiment). The second fixed regulated voltage value may be selected to achieve enhanced current accuracy within the LED channels for very low dimming duty cycles. The function 98 returns a variable regulated voltage value for dimming duty cycles between the first and second threshold levels. As depicted, the variable regulated voltage value varies along a straight line when plotted on a logarithmic duty cycle scale. In this manner, a progressively smaller regulated voltage value may be used as dimming duty cycle increases.
It should be appreciated that the function 98 of
In different implementations, different LED feedback may be used by the error amplifier 102 to generate the error signal. In some embodiments, for example, the error amplifier 102 may use the voltage across a current sink associated with a dominant LED channel to generate the error voltage. In some other embodiments, the error amplifier 102 may use an average voltage across current sinks associated with all LED channels to generate the error voltage. Other types of feedback may alternatively be used. The feedback that is used to generate the error voltage will determine which voltage associated with the driven LEDs will be regulated to the regulation voltage value.
The switch 104 is operative for controllably coupling the output of the error amplifier 102 to the COMP capacitor 106 during driver operation. As shown, in some implementations, the switch 104 may be controlled using a PWM signal associated with one or more of the driven LEDs. In embodiments where all LEDs are driven at the same dimming duty cycle, the switch 104 may be driven using the PWM signal associated with all of the driven LEDs. The error signal will thus be coupled to the COMP capacitor 106 during the on portion of the dimming duty cycle and decoupled from the COMP capacitor 106 during the off portion of the dimming duty cycle. During the off portion of the dimming duty cycle, the voltage on the COMP capacitor 106 will remain substantially constant so that, when a next on portion occurs, Vcomp will already be at its previous value. This technique can be used to increase the adaptation speed of the loop. In embodiments where different LED channels are allowed to use different dimming duty cycles, the switch 104 may be controlled using a PWM signal associated with the dominant LED channel. It should be appreciated that the boost control circuitry 100 of
As described above, in some embodiments, LED driver circuitry 52 of
The rectangular elements (typified by element 142 in
Alternatively, the processing blocks may represent operations performed by functionally equivalent circuits such as, for example, a digital signal processor circuit, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA), or a circuit formed from discrete elements. Some processing blocks may be manually performed while other processing blocks may be performed by a processor or circuit. The flow diagram of
With reference to
In some implementations, the same dimming duty cycle may be used by all LEDs being driven (e.g., LEDs in all driven channels, etc.). In other implementations, it may be possible to use different dimming duty cycles in different channels. In these implementations, the dimming duty cycle used to generate the regulated voltage value may be the lowest value being used in the corresponding driver system. As described previously, by using a higher regulated voltage value for lower dimming duty cycles, current accuracy can be enhanced for lower dimming duty cycles, while still maintaining high operational efficiency for higher dimming duty cycles.
In the description above, techniques and circuits for driving loads using a DC-DC converter have been discussed in the context of LED driver circuitry. It should be appreciated, however, that these techniques and circuits may also be used in other applications. That is, in some implementations, the described techniques and circuits may be used to drive loads other than LEDs according to a variable duty cycle.
Having described exemplary embodiments of the invention, it will now become apparent to one of ordinary skill in the art that other embodiments incorporating their concepts may also be used. The embodiments contained herein should not be limited to disclosed embodiments but rather should be limited only by the spirit and scope of the appended claims. All publications and references cited herein are expressly incorporated herein by reference in their entirety.
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