The present application relates to driving and dimming solid state light sources using an AC voltage source, and more particularly, to driving multiple solid state light source strings using an AC voltage source.
Conventional driving systems for solid state light sources, such as but not limited to light emitting diodes (LEDs), typically utilize DC/DC converter circuits to generate a constant DC current to drive the LEDs. Power to a DC/DC converter is typically supplied from an AC voltage source.
Conventional driving systems for solid state light sources, such as those described above, while typically offering stable drive current, unnecessarily increase electronic component count. This may degrade the efficiency of power transfer to the LEDs. In addition, these conventional driving systems are typically ill-suited to supply power to a plurality of LED strings, since there is no guarantee that the individual channels will remain isolated and/or grounded (non-floating) during operation.
In an embodiment, there is provided a solid state light source driving and dimming system. The solid state light source driving and dimming system includes a plurality of solid state light source driver circuits configured to be coupled to an AC voltage source. Each driver circuit includes: a constant current circuitry coupled to the AC voltage source, wherein the constant current circuitry is configured to generate a constant AC current from the AC voltage source; rectifier circuitry coupled to the constant current circuitry and configured to generate a DC current to drive at least one solid state light source; shunt circuitry coupled to a negative voltage rail and a positive voltage rail of the AC voltage source; switch circuitry coupled to the shunt circuitry; and pulse width modulation (PWM) circuitry configured to generate a PWM signal to control a conduction station of the switch circuitry; wherein when the switch circuitry is closed, a conduction path exists between the AC voltage source and the shunt circuitry through the switch circuitry to discontinue the DC current, and when the switch circuitry is closed, the shunt circuitry is electrically decoupled from the AC voltage source.
In a related embodiment, the constant current circuitry may include a ballast capacitor coupled to the positive rail of the AC voltage source. In another related embodiment, the shunt circuitry may include a first diode coupled to the positive voltage rail and in forward bias toward the switch; and a second diode coupled to the negative voltage rail and in forward bias toward the switch; wherein when the switch is closed, the AC voltage source may be shunted through the first and second diodes to discontinue the DC current to the at least one solid state light source.
In yet another related embodiment, the shunt circuitry may include a first diode coupled to the negative voltage rail and in forward bias toward the positive voltage rail; a second diode coupled to the first diode and the positive voltage rail and in forward bias toward the switch; and a third diode coupled to the negative voltage rail and in forward bias toward the switch; wherein when the switch is closed, the AC voltage source may be shunted through the first, second and third diodes to discontinue the DC current to the at least one solid state light source.
In still another related embodiment, the rectifier circuitry may include full wave bridge rectifier circuitry configured to generate a full wave rectified AC current from the AC current and a filtering capacitor in parallel with the at least one solid state light source; and wherein the filtering capacitor may be configured to filter the full wave rectified AC current into the DC current to drive the at least one solid state light source.
In yet still another related embodiment, the rectifier circuitry may include three diodes configured to generate a rectified AC current from the AC current and a filtering capacitor in parallel with the at least one solid state light source; and wherein the filtering capacitor may be configured to filter the rectified AC current into the DC current to drive the at least one solid state light source. In still yet another related embodiment, the solid state light source driving and dimming system may further include a return diode shared by the driver circuits, wherein the return diode may be coupled to the switch and the shunt circuitry and in forward bias toward the negative voltage rail; wherein when the switch is closed, the return diode may provide a current path from the positive voltage rail, through the shunt circuitry and the switch and to the negative voltage rail.
In yet still another related embodiment, the solid state light source driving and dimming system may further include first and second return diodes shared by the driver circuits, wherein the first return diode may be coupled to the switch and the shunt circuitry and in forward bias toward the negative voltage rail, and the second return diode may be coupled to the rectifier circuitry and the solid state light source and in forward bias toward the negative voltage rail; and wherein when the switch is closed, the first return diode may provide a current path from the positive voltage rail, through the shunt circuitry and the switch and to the negative voltage rail, and wherein when the switch is opened, the second return diode may provide a current path from the solid state light source to the negative voltage rail.
In still yet another related embodiment, the switch circuitry and the PWM circuitry may be coupled to a common ground. In yet still another embodiment, the rectifier circuitry and the at least one solid state light source may be coupled to a common ground. In still another related embodiment, the switch circuitry, the PWM circuitry, the rectifier circuitry and the at least one solid state light source may be coupled to a common ground.
In yet another related embodiment, each driver circuit may further include isolation circuitry coupled to a negative voltage rail of the AC current source and configured to electrically isolate each driver circuit from each other. In still another related embodiment, the solid state light source driving and dimming system may further include an isolation transformer having a primary winding and a plurality of secondary windings, wherein the primary winding may be coupled to the AC voltage source and each driver circuit may be coupled to a respective secondary winding, and wherein the isolation transformer may be configured to electrically isolate each driver circuit from each other.
In another embodiment, there is provided a solid state light source driving and dimming system. The solid state light source driving and dimming system includes: a plurality of solid state light source driver circuits configured to be coupled to an AC voltage source, each driver circuit including: constant current circuitry coupled to an AC voltage source, the constant current circuitry is configured to generate a constant AC current from the AC voltage source; isolation circuitry coupled to the AC voltage source and configured to electrically isolate each driver circuit from each other; rectifier circuitry coupled to the constant current circuitry and configured to generate a DC current to drive at least one solid state light source; shunt circuitry coupled to a negative and positive voltage rails of the AC voltage source; switch circuitry coupled to the shunt circuitry; and pulse width modulation (PWM) circuitry configured to generate a PWM signal to control a conduction station of the switch circuitry; wherein when the switch circuitry is closed, a conduction path exists between the AC voltage source and the shunt circuitry through the switch circuitry to discontinue the DC current, and when the switch circuitry is closed, the shunt circuitry is electrically decoupled from the AC voltage source.
In a related embodiment, the shunt circuitry may include: a first diode coupled to the negative voltage rail and in forward bias toward the positive voltage rail; a second diode coupled to the first diode and the positive voltage rail and in forward bias toward the switch; and a third diode coupled to the negative voltage rail and in forward bias toward the switch; wherein when the switch is closed, the AC voltage source may be shunted through the first, second and third diodes to discontinue the DC current to the at least one solid state light source.
In another related embodiment, the isolation circuitry may include a capacitor coupled to the negative voltage rail and the constant current circuitry may include a capacitor coupled to the positive voltage rail, and wherein the capacitance of the isolation circuitry and the constant current circuitry may be approximately equal. In yet another related embodiment, the switch circuitry, the PWM circuitry, the rectifier circuitry and the at least one solid state light source may be coupled to a common ground.
In another embodiment, there is provided a solid state light source driving and dimming system. The solid state light source driving and dimming system includes: an isolation transformer having a primary winding coupled to an AC voltage source and a plurality of secondary windings, wherein the isolation transformer is configured to electrically isolate each respective secondary winding from each other; a plurality of solid state light source driver circuits configured to be coupled to a respective secondary winding, each driver circuit including: constant current circuitry coupled to a secondary winding, the constant current circuitry is configured to generate a constant AC current from the AC voltage source; rectifier circuitry coupled to the constant current circuitry and configured to generate a DC current to drive at least one solid state light source; shunt circuitry coupled to a negative and positive voltage rails of the secondary winding; switch circuitry coupled to the shunt circuitry; and pulse width modulation (PWM) circuitry configured to generate a PWM signal to control a conduction station of the switch circuitry; wherein when the switch circuitry is closed, a conduction path exists between the secondary winding and the shunt circuitry through the switch circuitry to discontinue the DC current, and when the switch circuitry is closed, the shunt circuitry is electrically decoupled from the secondary winding.
In a related embodiment, the shunt circuitry may include: a first diode coupled to the negative voltage rail and in forward bias toward the positive voltage rail; a second diode coupled to the first diode and the positive voltage rail and in forward bias toward the switch; and a third diode coupled to the negative voltage rail and in forward bias toward the switch; wherein when the switch is closed, the secondary winding may be shunted through the first, second and third diodes to discontinue the DC current to the at least one solid state light source. In another related embodiment, the switch circuitry, the PWM circuitry, the rectifier circuitry and the at least one solid state light source may be coupled to a common ground.
The foregoing and other objects, features and advantages disclosed herein will be apparent from the following description of particular embodiments disclosed herein, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles disclosed herein.
Embodiments described herein concern driving and dimming solid state light sources, such as but not limited to light emitting diode (LED) strings. Solid state light sources may include, in addition to LEDs and among other things, organic LEDs (OLEDs), as well as other LED-based light sources. The drive current for an LED string may be derived, for example, from a conventional AC power source and/or an instant start ballast conventionally used to drive one or more linear fluorescent lamps. Thus, embodiments disclosed herein may be used as a direct retrofit to replace conventional fluorescent lamps with LED-based lightning, and in some embodiments, the need for DC/DC converter circuitry may be eliminated. PWM dimming techniques may be employed to control the brightness and/or color of individual LED strings. Advantageously, embodiments disclosed herein may offer reduced component count which may translate to increased power factor efficiency and significant cost savings over conventional LED driving systems.
The rectifier circuitry 110 may be coupled to the current source circuitry 104 and configured to rectify and filter the AC current generated by the current source circuitry 104. In some embodiments, and as shown in
The solid state light source driver system 100 shown in
When the PWM signal is OFF, the switch 108 may open, thus decoupling the shunt circuitry 106 and the switch 108 from the AC voltage source 102. In that case, during a positive half wave of a signal from the AC voltage source 102, current flows through the upper right diode of the full wave rectifier FWB, through the LED string 112, through the lower left diode of the FWB and back to the AC voltage source 102. During a negative half wave of the signal from the AC voltage source 102, current flows through the lower right diode of the FWB, through the LED string 112, through the upper left diode of the FWB and back to the AC voltage source 102. Decoupling the shunt circuitry 106, such that there no power loss on the elements in the shunt circuitry 106, when power is delivered to the LED string 112, may offer significant efficiency and power factor enhancements and may further operate to increase a signal to noise ratio of power delivered to the LED string 112.
In some embodiments, the filter capacitor Cf may have a capacitance value that enables the filter capacitor Cf to still deliver energy to the LED strings 112 when the AC voltage source 102 is shunted, but also to de-energize quickly enough to allow for adequate dimming control using the duty cycle of the PWM signal generated by the PWM signal source 114. Thus, for example, the filter capacitor Cf may have a value that allows it to drain energy to the LED string 112 within a few percent of the ON time of the switch 108. The PWM signal source 114 may be coupled to the ground 116, which may include, for example, a system MAINS ground and/or common (earth) ground. Coupling the PWM signal source 114 to the ground 116 may reduce or eliminate the PWM signal source 114 from being in a “floating” state, which may reduce or eliminate harmonic noise in the switch 108 and shunt circuitry 106 and enable finer control over the LED string 112. While the switch 108 is depicted as a generalized switching circuit, those skilled in the art will recognize that the switch 108 may include a FET switch, BJT switch or other electronic circuit capable of switching conduction states. As is known, the PWM signal generated by the PWM signal source 114 may have a controllable duty cycle to control the brightness and/or color of the LED string 112. For example, assuming a 50% duty cycle, drive current is delivered to LED string 112 during the OFF time of the switch 108 and interrupted during the ON time of the switch 108. To control the overall brightness in the LED string 112, the duty cycle of the PWM signal may be adjusted. For example, the duty cycle may range from 0% (the switch 108 is always open) to 100% (the switch 108 is always closed) to control the overall brightness (luminosity) and/or color of the LED string 112.
Each LED driver circuit 201A, 201B, . . . , 201n may also include respective shunt circuitry 206A, 206B, . . . , 206n. Each respective shunt circuitry 106A, 106B, . . . , 106n may include three diodes D1, D2 and D3, where the diodes D1 and D3 are coupled to the negative rail of the AC voltage source 102 and forward biased into the respective switch 108, and the diode D2 is coupled to the positive rail of the AC voltage source 102 and forward biased into the respective switch 108. The shunt circuitry 206A, 206B, . . . , 206n is configured to independently shunt the AC voltage source 102 depending on the conduction state of the respective switch 108A, 108B, . . . , 108n, as will be described below. Embodiments may also include a return diode (Dc) 218 that is shared by each of the driver circuits 201A, 201B, . . . , 201n and coupled to each respective shunt circuitry 206A, 206B, . . . , 206n and switch 108A, 108B, . . . , 108n. Each switch 108A, 108B, . . . , 108n may be operably coupled to respective shunt circuitry 106A, 106B, . . . , 106n and the return diode 218.
In operation, each respective PWM signal source circuitry 114A, 114B, . . . , 114n is configured to generate a PWM signal to control the conduction state of a respective switch 108A, 108B, . . . 108n. Using the driver circuit 201A as an example, when the PWM signal is ON (high), the switch 108A may conduct, thus closing the switch 108A. During the positive half wave of a signal from the AC voltage source 102, current may flow through the diode D2, through the switch 108A, through the return diode 218, and back to the AC voltage source 102. During the negative half wave of a signal from the AC source 102, current may flow through the diode D3, through the switch 108A, through the diode D1, and back to the AC voltage source 102. Thus, when the switch 108A is conducting, the AC voltage source 102 may be shunted to interrupt current flow to the LED string 112A. When the PWM signal is OFF (low), the switch 108A may open, thus decoupling the shunt circuitry 206A from the AC voltage source 102. In that case, current flows through the rectifier circuitry 110A to power the LED string 112A, as described above in regards to
Each LED string 112A, 112B, . . . , 112n may include one or more individual LED devices. Each string may be arranged by color, for example but not limited to a red, green, blue (RGB) topology in which the LED string 112A may include one or more red LEDs, the LED string 112B may include one or more green LEDs, and the LED string 112n may include one or more blue LEDs. Of course, this is only an example and other color arrangements are equally contemplated herein, for example, RGW (red, green, white), RGBY (red, green, blue, yellow), infrared, etc., without departing from the scope of the embodiments described herein. By controlling the brightness in each LED string 112A, 112B, . . . , 112n, the overall brightness and/or perceived color of the collection of the LED strings 112A, 112B, . . . , 112n may be controlled. Thus, in such embodiments, each PWM signal source 114A, 114B, . . . , 114n may be independently controlled with its own duty cycle to independently control each LED string 112A, 112B, . . . , 112n. To that end, the return diode 218 may operate to reduce or eliminate crosstalk between each driver circuit 201A, 201B, . . . , 201n, i.e., reduce or eliminate the effect of varying current between LED strings 112A, 112B, . . . , 112n.
In embodiments as shown in
Embodiments may also include first and second return diodes (Dc and Dc1) 218 and 320 that are shared by each of the LED driver circuits 301A, 301B, . . . , 301n. The first return diode 218 may be coupled to each respective shunt circuitry 206A, 206B, . . . , 206n and each respective switch 108A, 108B, . . . , 108n. The second return diode 320 may be coupled to each respective LED string 112A, 112B, . . . , 112n and each respective rectifier circuitry 310A, 310B, . . . , 310n. Each switch 108A, 108B, . . . , 108n may be operably coupled to the respective shunt circuitry 206A, 206B, . . . , 206n and the first return diode 218. The rectifier circuitry 310A, 310B, . . . , 310n may include three diodes D4, D5 and D6 instead of the FWB topology that comprises four diodes as shown in
In operation, each respective PWM signal source circuitry 114A, 114B, . . . , 114n is configured to generate a PWM signal to control the conduction state of a respective switch 108A, 108B, . . . 108n. Using the LED driver circuit 301A as an example, when the PWM signal is ON (high), the switch 108A may close, creating a conduction path through the switch 108A. During the positive half wave of a signal from the AC voltage source 102, current may flow through the diode D2, through the switch 108A, through the first return diode 218, and back to the AC voltage source 102. During the negative half wave of a signal from the AC voltage source 102, current may flow through the diode D3, through the switch 108A, through the diode D1, and back to the AC voltage source 102. Thus, when the switch 108A is conducting, the AC voltage source 102 may be shunted to interrupt current flow to the LED string 112A. When the PWM signal is OFF (low), the switch 108A may open, thus decoupling the shunt circuitry 106A from the AC voltage source 102. In that case, during the positive half wave of a signal from the AC voltage source 102, current may flow through the diode D5, through the LED string 112A, through the second return diode 320, and back to the AC voltage source 102. During the negative half wave of a signal from the AC voltage source 102, current may flow through the diode D6, through the LED string 112A, through the diode D4, and back to the AC voltage source 102. As with previously described embodiments, decoupling the shunt circuitry 206A, such that there is no power loss on the elements in the shunt circuitry 206A, when power is delivered to the LED string 112A, may offer significant power factor enhancements and may further operate to increase a signal to noise ratio of power delivered to the LED string 112A. Each of the other LED driver circuits 301B, . . . , 301n may operate in a similar manner.
As with the previous described embodiments, each LED string 112A, 112B, . . . , 112n may include one or more individual LED devices. Each LED string 112A, 112B, . . . , 112n may be arranged by color, for example a red, green, blue (RGB) topology in which the LED string 112A may include one or more red LEDs, the LED string 112B may include one or more green LEDs, and the LED string 112n may include one or more blue LEDs. Of course, this is only an example, and other color arrangements are equally contemplated herein, for example, RGW (red, green, white), RGBY (red, green, blue, yellow), infrared, etc., without departing from the scope of embodiments described herein. By controlling the brightness in each LED string 112A, 112B, . . . , 112n, the overall brightness and/or perceived color of the collection of LED strings 112A, 112B, . . . , 112n may be controlled. Thus, in such embodiments, each PWM signal source circuitry 114A, 114B, . . . , 114n may be independently controlled with its own duty cycle to independently control each LED string 112A, 112B, . . . , 112n. To that end, the first and second return diodes 218 and 320 may operate to reduce or eliminate crosstalk between each LED driver circuit 301A, 301B, . . . , 301n, i.e., reduce or eliminate the effect of varying current between the LED strings 112A, 112B, . . . , 112n.
Advantageously, in such embodiments, elimination of one of the diodes in each of the respective rectifier circuitry 310A, 310B, . . . , 310n may enable the rectifier circuitry 310A, 310B, . . . , 310n and the LED string 112A, 112B, . . . , 112n in each LED driver circuit 301A, 301B, . . . , 301n to be coupled to a ground 116. Such an arrangement may reduce or eliminate noise and/or reduce electro-magnetic interference emanated by the LED string 112A, 112B, . . . , 112n and other non-controllable factors into the system 300. However, in this arrangement, the PWM signal source circuitry 114A, 114B, . . . , 114n may not be coupled to a ground due to potential shorting issues, and thus, the PWM signal source circuitry 114A, 114B, . . . , 114n may be in a floating condition, which could introduce noise and/or other non-controllable factors into the system 300.
Each LED driver circuit 401A, 401B, . . . , 401n in this embodiment may also include respective isolation circuitry 403A, 403B, . . . , 403n coupled to the negative voltage rail of the AC voltage source 102. In some embodiments, the isolation circuitry 403A, 403B, . . . , 403n may include a capacitor Cb2. The capacitance value of the capacitor Cb2 may be the same or approximately the same as the ballast capacitor Cb1 (element 104 in
As with the embodiments described previously, each LED string 112A, 112B, . . . , 112n may include one or more individual LED devices. Each string may be arranged by color, for example a red, green, blue (RGB) topology in which the LED string 112A may include one or more red LEDs, the LED string 112B may include one or more green LEDs, and the LED string 112n may include one or more blue LEDs. Of course, this is only an example and other color arrangements are equally contemplated herein, for example, RGW (red, green, white), RGBY (red, green, blue, yellow), infrared, etc., without departing from the scope of embodiments described herein. By controlling the brightness in each LED string 112A, 112B, . . . , 112n, the overall brightness and/or perceived color of the collection of the LED strings 112A, 112B, . . . , 112n may be controlled. Thus, in such embodiments, each PWM signal source circuitry 114A, 114B, . . . , 114n may be independently controlled with its own duty cycle to independently control each LED string 112A, 112B, . . . , 112n. To that end, the respective ballast capacitor Cb1 in each respective current source circuitry 104A, 104B, . . . , 104n, and the respective isolation capacitor Cb2 in each respective isolation circuitry 403A, 403B, . . . , 403n, may operate to reduce or eliminate crosstalk between each LED driver circuit 401A, 401B, . . . , 401n, i.e., reduce or eliminate the effect of varying current between LED strings 112A, 112B, . . . , 112n.
The driver system 500 may also include an isolation transformer 503 coupled between the AC voltage source 102 and each of the LED driver circuits 501A, 501B, . . . , 501n. The isolation transformer 503 may be configured to supply each LED driver circuit 501A, 501B, . . . , 501n with an AC voltage and to isolate each LED driver circuit 501A, 501B, . . . , 501n from other driver circuits. The isolation transformer 503 may be, and in some embodiments is, a known isolation transformers of any type; such transformers are generally configured with a primary winding and a plurality of isolated secondary windings. The turn ration between the primary and secondary side may determine the voltage delivered by the isolation transformer 503. Thus, advantageously, the isolation transformer 503 may reduce or eliminate crosstalk between the channels to enable more precise control over each channel. Also advantageously, the isolation transformer 503 may enable each LED driver circuit 501A, 501B, . . . , 501n to be coupled to a ground 116, thus eliminating a floating condition in any of the LED driver circuits 501A, 501B, . . . , 501n. In other words, the isolation transformer 503 may enable both the PWM signal source circuitry 114A, 114B, . . . , 114n and the LED strings 112A, 112B, . . . 112n to be coupled to the ground 116.
As with other embodiments, each LED string 112A, 112B, . . . , 112n may include one or more individual LED devices. Each string may be arranged by color, for example a red, green, blue (RGB) topology in which the LED string 112A may include one or more red LEDs, the LED string 112B may include one or more green LEDs, and the LED string 112n may include one or more blue LEDs. Of course, this is only an example and other color arrangements are equally contemplated herein, for example, RGW (red, green, white), RGBY (red, green, blue, yellow), infrared, etc., without departing from the scope of embodiments described herein. By controlling the brightness in each LED string 112A, 112B, . . . , 112n, the overall brightness and/or perceived color of the collection of LED strings 112A, 112B, . . . , 112n may be controlled. Thus, in such embodiments, each PWM signal source circuitry 114A, 114B, . . . , 114n may be independently controlled with its own duty cycle to independently control each LED string 112A, 112B, . . . , 112n.
In any of the embodiments described herein, a feedback controller (not shown in any of
As used in any embodiment herein, “circuit” or “circuitry” may comprise, for example, singly or in any combination, hardwired circuitry, programmable circuitry, state machine circuitry, and/or firmware that stores instructions executed by programmable circuitry. In at least one embodiment, the circuits and/or circuitry described herein may collectively or individually comprise one or more integrated circuits. An “integrated circuit” may include a digital, analog or mixed-signal semiconductor device and/or microelectronic device, such as, for example, but not limited to, a semiconductor integrated circuit chip.
Unless otherwise stated, use of the word “substantially” may be construed to include a precise relationship, condition, arrangement, orientation, and/or other characteristic, and deviations thereof as understood by one of ordinary skill in the art, to the extent that such deviations do not materially affect the disclosed methods and systems.
Throughout the entirety of the present disclosure, use of the articles “a” or “an” to modify a noun may be understood to be used for convenience and to include one, or more than one, of the modified noun, unless otherwise specifically stated.
Elements, components, modules, and/or parts thereof that are described and/or otherwise portrayed through the figures to communicate with, be associated with, and/or be based on, something else, may be understood to so communicate, be associated with, and or be based on in a direct and/or indirect manner, unless otherwise stipulated herein.
Although the methods and systems have been described relative to a specific embodiment thereof, they are not so limited. Obviously many modifications and variations may become apparent in light of the above teachings. Many additional changes in the details, materials, and arrangement of parts, herein described and illustrated, may be made by those skilled in the art.
Number | Name | Date | Kind |
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20090303720 | McGrath | Dec 2009 | A1 |
20100308751 | Nerone | Dec 2010 | A1 |
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202008004910 | Jun 2008 | DE |
1608206 | Dec 2005 | EP |
2048917 | Apr 2009 | EP |
Number | Date | Country | |
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20120056554 A1 | Mar 2012 | US |