LOAD CONTROL DEVICE FOR A LIGHT-EMITTING DIODE LIGHT SOURCE

US 20110080110A1
Filed: 06/11/2010
Published: 04/07/2011
Est. Priority Date: 10/07/2009
Status: Active Grant

First Claim

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1. An LED driver for controlling the intensity of an LED light source, the LED driver comprising:

a power converter circuit operable to receive a rectified AC voltage and to generate a DC bus voltage;

a LED drive circuit operable to receive the bus voltage and to control the magnitude of a load current conducted through the LED light source, so as to control the intensity of the LED light source, the LED drive circuit comprising a controllable-impedance circuit adapted to be coupled in series with the LED light source; and

a control circuit operatively coupled to the power converter circuit for adjusting the magnitude of the bus voltage, and to the LED drive circuit for controlling the controllable-impedance circuit to thus adjust the magnitude of the load current through the LED light source;

wherein the control circuit adjusts the magnitude of the bus voltage in response to the magnitude of a voltage generated across the controllable-impedance circuit to reduce the total power dissipation in the power converter circuit and the LED drive circuit.

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Abstract

A light-emitting diode (LED) driver is adapted to control either the magnitude of the current conducted through a LED light source or the magnitude of a voltage generated across the LED light source. The LED driver comprises a power converter circuit for generating a DC bus voltage, and an LED drive circuit for receiving the bus voltage and adjusting the magnitude of the current conducted through the LED light source. The LED driver is operable to dim the LED light source using either a pulse-width modulation technique or a constant current reduction technique. The LED drive circuit may comprise a controllable-impedance circuit, such as a linear regulator. The LED driver may be operable to control the magnitude of the bus voltage to optimize the efficiency and reduce the power dissipation in the LED drive circuit, as well ensuring that the load voltage and current do not have any ripple.

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33 Claims

1. An LED driver for controlling the intensity of an LED light source, the LED driver comprising:
- a power converter circuit operable to receive a rectified AC voltage and to generate a DC bus voltage;
  
  a LED drive circuit operable to receive the bus voltage and to control the magnitude of a load current conducted through the LED light source, so as to control the intensity of the LED light source, the LED drive circuit comprising a controllable-impedance circuit adapted to be coupled in series with the LED light source; and
  
  a control circuit operatively coupled to the power converter circuit for adjusting the magnitude of the bus voltage, and to the LED drive circuit for controlling the controllable-impedance circuit to thus adjust the magnitude of the load current through the LED light source;
  
  wherein the control circuit adjusts the magnitude of the bus voltage in response to the magnitude of a voltage generated across the controllable-impedance circuit to reduce the total power dissipation in the power converter circuit and the LED drive circuit.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The LED driver of claim 1, wherein the controllable-impedance circuit comprises a linear regulator.
  - 3. The LED driver of claim 2, wherein the linear regulator comprises a regulation transistor adapted to be coupled in series with the LED light source, the control circuit operable to control the regulation transistor to operate in the linear region to thus control the magnitude of the load current conducted through the LED light source.
  - 4. The LED driver of claim 3, wherein the control circuit controls the LED drive circuit to adjust the DC magnitude of a gate voltage at a gate of the regulation transistor to control the regulation transistor in the linear region.
  - 5. The LED driver of claim 4, wherein the control circuit increases the DC magnitude of the gate voltage at the gate of the regulation transistor to increase the magnitude of the load current, and decreases the DC magnitude of the gate voltage to decrease the magnitude of the load current.
  - 6. The LED driver of claim 3, wherein the LED drive circuit further comprises a feedback circuit coupled in series with the regulation transistor and operable to generate a load current feedback signal representative of the magnitude of the load current, the control circuit operable to control the regulation transistor to operate in the linear region in response to the magnitude of the load current.
  - 7. The LED driver of claim 3, wherein the regulation transistor comprises a FET.
  - 8. The LED driver of claim 2, wherein the control circuit adjusts the magnitude of the bus voltage to thus control the magnitude of the voltage generated across the linear regulator circuit to a target regulator voltage.
  - 9. The LED driver of claim 8, wherein the control circuit decreases the magnitude of the bus voltage if the voltage generated across the linear regulator circuit is greater than the target regulator voltage, and increases the magnitude of the bus voltage if the voltage generated across the linear regulator circuit is less than the target regulator voltage.
  - 10. The LED driver of claim 2, wherein the control circuit is operable to measure the magnitude of the bus voltage and the magnitude of a load voltage generated across the LED light source, the control circuit further operable to calculate the magnitude of the voltage generated across the linear regulator by subtracting the magnitude of the load voltage generated across the LED light source from the magnitude of the bus voltage.
  - 11. The LED driver of claim 2, wherein the control circuit is operable to measure the magnitude of the voltage generated across the linear regulator.

12. An LED driver for controlling the intensity of an LED light source, the LED driver comprising:
- a power converter circuit operable to receive a rectified AC voltage and to generate a DC bus voltage;
  
  a LED drive circuit operable to receive the bus voltage and to control the magnitude of a load current conducted through the LED light source, so as to control the intensity of the LED light source, the LED drive circuit comprising a controllable-impedance circuit adapted to be coupled in series with the LED light source; and
  
  a control circuit operatively coupled to the power converter circuit for adjusting the magnitude of the bus voltage, and to the LED drive circuit for controlling the controllable-impedance circuit to thus adjust the magnitude of the load current through the LED light source;
  
  wherein the control circuit adjusts the magnitude of the bus voltage in response to the magnitude of a voltage generated across the controllable-impedance circuit to control the magnitude of the voltage generated across the controllable-impedance circuit to a target voltage.
- View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22)
- - 13. The LED driver of claim 12, wherein the controllable-impedance circuit comprises a linear regulator.
  - 14. The LED driver of claim 13, wherein the linear regulator comprises a regulation transistor adapted to be coupled in series with the LED light source, the control circuit operable to control the regulation transistor to operate in the linear region to thus control the magnitude of the load current conducted through the LED light source.
  - 15. The LED driver of claim 14, wherein the control circuit controls the LED drive circuit to adjust the DC magnitude of a gate voltage at a gate of the regulation transistor to control the regulation transistor in the linear region.
  - 16. The LED driver of claim 15, wherein the control circuit increases the DC magnitude of the gate voltage at the gate of the regulation transistor to increase the magnitude of the load current, and decreases the DC magnitude of the gate voltage to decrease the magnitude of the load current.
  - 17. The LED driver of claim 14, wherein the LED drive circuit further comprises a feedback circuit coupled in series with the regulation transistor and operable to generate a load current feedback signal representative of the magnitude of the load current, the control circuit operable to control the regulation transistor to operate in the linear region in response to the magnitude of the load current.
  - 18. The LED driver of claim 14, wherein the regulation transistor comprises a FET.
  - 19. The LED driver of claim 13, wherein the control circuit decreases the magnitude of the bus voltage if the voltage generated across the linear regulator circuit is greater than the target voltage, and increases the magnitude of the bus voltage if the voltage generated across the linear regulator circuit is less than the target voltage.
  - 20. The LED driver of claim 13, wherein the control circuit is operable to measure the magnitude of the bus voltage and the magnitude of a load voltage generated across the LED light source, the control circuit further operable to calculate the magnitude of the voltage generated across the linear regulator by subtracting the magnitude of the load voltage generated across the LED light source from the magnitude of the bus voltage.
  - 21. The LED driver of claim 13, wherein the control circuit is operable to measure the magnitude of the voltage generated across the linear regulator.
  - 22. The LED driver of claim 12, wherein the control circuit adjusts the magnitude of the bus voltage in response to the magnitude of the voltage generated across the controllable-impedance circuit to reduce the total power dissipation in the power converter circuit and the LED drive circuit.

23. An LED driver for driving an LED light source including at least one LED, the LED driver comprising:
- a first circuit receiving a rectified AC voltage and providing a DC bus voltage;
  
  a second circuit receiving said DC bus voltage and producing one of a load current through said LED light source or a load voltage across said LED light source;
  
  a control circuit having a first control input from said first circuit and a second control input from said second circuit and further having a first control output provided to said first circuit and a second control output provided to said second circuit;
  
  said first control input comprising a signal related to said DC bus voltage;
  
  said first control output comprising a control signal for controlling said first circuit to deliver a desired DC bus voltage;
  
  said second control input comprising a signal related to the load current provided by said second circuit through said LED light source;
  
  said second control output comprising a control signal to regulate either or both said load current to said LED light source and said load voltage provided to said LED light source; and
  
  wherein said second circuit comprises a linear regulator circuit having a power semiconductor device adapted to be coupled in series with said LED light source to regulate said load current to a desired load current, such that a load voltage is generated across said LED light source, said control circuit operable to control said first circuit to adjust the magnitude of the DC bus voltage to a magnitude that is above said load voltage by at least a minimum regulator voltage to enable said linear regulator to regulate said load current to said desired load current.
- View Dependent Claims (24, 25, 26)
- - 24. The LED driver of claim 23, wherein said second circuit is operated as a current control mode driver, such that said power semiconductor device is operated in a linear region by said control circuit providing said second control output to control said power semiconductor device into said linear region.
  - 25. The LED driver of claim 23, wherein said second control output comprises a PWM signal, said second circuit further comprising a filter circuit receiving said second control output from said control circuit, said filter circuit providing a filtered signal to said power semiconductor device to control said power semiconductor device in said linear region to regulate said load current to said desired load current.
  - 26. The LED driver of claim 23, wherein said power semiconductor device comprises a FET.

27. A method for controlling the intensity of an LED light source, the method comprising:
- generating a DC bus voltage;
  
  controlling the magnitude of a load current conducted through the LED light source by controlling a controllable-impedance circuit that is coupled to conduct the load current through the LED light source;
  
  determining the magnitude of a voltage generated across the controllable-impedance circuit; and
  
  adjusting the magnitude of the bus voltage in response to the magnitude of the voltage generated across the controllable-impedance circuit to reduce the total power dissipation in the power converter circuit and the LED drive circuit.
- View Dependent Claims (28, 29, 30, 31, 32)
- - 28. The method of claim 27, wherein adjusting the magnitude of the bus voltage further comprises controlling the magnitude of the voltage generated across the controllable-impedance circuit to a target regulator voltage.
  - 29. The method of claim 28, wherein controlling the magnitude of the voltage generated across the controllable-impedance circuit further comprises decreasing the magnitude of the bus voltage if the voltage generated across the controllable-impedance circuit is greater than the target regulator voltage, and increasing the magnitude of the bus voltage if the voltage generated across the controllable-impedance circuit is less than the target regulator voltage.
  - 30. The method of claim 27, wherein determining the magnitude of a voltage generated across the controllable-impedance circuit further comprises measuring the magnitude of the voltage generated across the controllable-impedance circuit.
  - 31. The method of claim 27, wherein determining the magnitude of a voltage generated across the controllable-impedance circuit further comprises:
    - measuring the magnitude of the bus voltage;
      
      measuring the magnitude of a load voltage generated across the light source; and
      
      calculating the magnitude of the voltage generated across the controllable-impedance circuit by subtracting the magnitude of the load voltage generated across the light source from the magnitude of the bus voltage.
  - 32. The method of claim 27, wherein the controllable-impedance circuit comprises a linear regulator.

33. A method for controlling the intensity of an LED light source, the method comprising:
- generating a DC bus voltage;
  
  controlling the magnitude of a load current conducted through the LED light source by controlling a controllable-impedance circuit that is coupled to conduct the load current through the LED light source;
  
  determining the magnitude of a voltage generated across the controllable-impedance circuit; and
  
  adjusting the magnitude of the bus voltage in response to the magnitude of the voltage generated across the controllable-impedance circuit to control the magnitude of the voltage generated across the controllable-impedance circuit to a target voltage.

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Current Assignee
Lutron Technology Company LLC
Original Assignee
Lutron Electronics Company Incorporated (Lutron Electronics)
Inventors
Chitta, Venkatesh, Nuhfer, Matthew W., Shearer, Thomas M., Iyer, Kartik

Granted Patent

US 8,492,987 B2
Time in Patent Office

Days
Field of Search
US Class Current

315/291
CPC Class Codes

H05B 45/10   Controlling the intensity o...

H05B 45/12   using optical feedback

H05B 45/18   using temperature feedback

H05B 45/3725   Switched mode power supply ...

H05B 45/385   using flyback topology

H05B 45/397   Current mirror circuits

H05B 45/44   with an active control insi...

H05B 47/155   Coordinated control of two ...

Y02B 20/30   Semiconductor lamps, e.g. s...

LOAD CONTROL DEVICE FOR A LIGHT-EMITTING DIODE LIGHT SOURCE

First Claim

2 Assignments

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Abstract

Citations

33 Claims

Specification

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LOAD CONTROL DEVICE FOR A LIGHT-EMITTING DIODE LIGHT SOURCE

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

Citations

33 Claims

Specification

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Solutions

Use Cases

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