Reduced flicker AC LED lamp with separately shortable sections of an LED string

US 20110227489A1
Filed: 05/04/2010
Published: 09/22/2011
Est. Priority Date: 03/19/2010
Status: Active Grant

First Claim

Patent Images

1-30. -30. (canceled)

View all claims

1 Assignment

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

An LED lamp with an integrated circuit, a rectifier, and a string of series-connected LEDs rectifies an incoming AC signal. The integrated circuit includes power switches that can separately and selectably short out a corresponding one of several groups of LEDs in an LED string across which the rectified AC signal is present. As the voltage across the string increases, the integrated circuit controls the power switches to increase the number of LEDs through which current flows, whereas as the voltage across the string decreases the integrated circuit controls the power switches to decrease the number of LEDs through which current flows. The flow of LED string current is broken to reduce flicker. Alternatively, a valley fill capacitor peaks LED current during the valleys of the incoming AC signal to reduce flicker. LED current is regulated to provide superior efficiency, reliability, power-factor correction, and lamp over-voltage, -current, and -temperature protection.

124 Citations

57 Claims

1-30. -30. (canceled)

31. A method comprising:
- increasing a number of light emitting diodes (LEDs) in a string of series-connected LEDs through which an LED current flows from a first node to a second node as a voltage amplitude of a changing voltage signal increases to a peak amplitude, wherein the number has at least two discrete nonzero values as the voltage amplitude of the changing voltage signal increases, and wherein the changing voltage signal has a cycle period;
  
  decreasing the number of LEDs in the string of series-connected LEDs through which the LED current flows from the first node to the second node as the voltage amplitude of the changing voltage signal decreases from the peak amplitude, wherein the changing voltage signal has an associated current magnitude; and
  
  reducing the LED current during the cycle period by more than half of the current magnitude of the changing voltage signal for a duration of less than 12% of the cycle period.
- View Dependent Claims (32, 33, 34)
- - 32. The method of claim 31, wherein the periodic peak amplitude of the changing input voltage signal occurs about every 8.33 milliseconds, and wherein the duration of reduced LED current is between 0.7 and 0.9 milliseconds.
  - 33. The method of claim 31, wherein the changing voltage signal is generated by rectifying a sinusoidal alternating current signal, wherein the sinusoidal alternating current signal has a frequency, and wherein the reducing the LED current is performed such that peaks of light intensity are emitted from the string of series-connected LEDs at a rate that is four times the frequency of the sinusoidal alternating current signal.
  - 34. The method of claim 31, wherein the voltage signal is generated by rectifying a sinusoidal alternating current signal, and wherein the reducing the LED current is performed such that peaks of light intensity are emitted from the string of series-connected LEDs at more then 130 times per second.

35. A method comprising:
- rectifying a sinusoidal alternating current (AC) voltage signal having an amplitude higher than one hundred volts to generate a changing voltage signal, wherein the changing voltage signal has a period and instantaneous voltages;
  
  supplying a string of series-connected light emitting diodes (LEDs) with the changing voltage signal, wherein the string of series-connected LEDs through which an LED current flows has a total forward voltage drop that approximately equals the instantaneous voltage during a portion of the period of the changing input voltage signal; and
  
  modulating light that is emitted from the string of series-connected LEDs such that peaks of light intensity are generated at more than 130 times per second.
- View Dependent Claims (36, 37, 38)
- - 36. The method of claim 35, wherein the sinusoidal AC voltage signal has a frequency, and wherein the peaks of light intensity are generated at a rate that is four times the frequency of the sinusoidal AC voltage signal.
  - 37. The method of claim 35, wherein the changing voltage signal has a peak amplitude, and wherein the modulating involves reducing the LED current when the changing voltage signal is at or near its peak amplitude.
  - 38. The method of claim 35, wherein a valley fill capacitor provides the LED current when the changing voltage signal has a voltage lower than a valley voltage threshold.

39. A system comprising:
- a first terminal of an integrated circuit, wherein a first node is coupled to the first terminal, wherein a changing voltage signal with a voltage amplitude and a cycle period is present on the first node, and wherein the changing voltage signal has an associated current magnitude;
  
  a second terminal of the integrated circuit, wherein a second node is coupled to the second terminal; and
  
  a string of series-connected LEDs through which an LED current flows from the first node to the second node, wherein a number of light emitting diodes (LEDs) in the string of series-connected LEDs through which the LED current flows is increased as the voltage amplitude of the changing input voltage signal increases to a peak amplitude, wherein the number of LEDs in the string of series-connected LEDs through which the LED current flows is decreased as the voltage amplitude of the changing input voltage signal decreases from the peak amplitude, wherein the integrated circuit reduces the LED current during the cycle period by more than half of the current magnitude of the changing voltage signal for a duration of less than 12% of the cycle period.
- View Dependent Claims (40, 41, 42)
- - 40. The system of claim 39, wherein the duration of reduced LED current occurs from before the voltage amplitude of the changing voltage signal reaches the peak amplitude at least until the changing voltage signal is at its peak amplitude.
  - 41. The system of claim 39, wherein the integrated circuit adjusts the LED current based on a dimmer phase cut angle.
  - 42. The system of claim 39, wherein the changing voltage signal is generated by rectifying a sinusoidal alternating current signal, and wherein the integrated circuit reduces the LED current such that peaks of light intensity are generated at more than 130 times per second

43. A method comprising:
- increasing a number of light emitting diodes (LEDs) in a string of series-connected LEDs through which an LED current flows from a first node to a second node as a voltage amplitude of a changing voltage signal increases to a peak amplitude, wherein the number has at least two discrete nonzero values as the voltage amplitude of the changing voltage signal increases;
  
  decreasing the number of LEDs in the string of series-connected LEDs through which the LED current flows from the first node to the second node as the voltage amplitude of the changing voltage signal decreases from the peak amplitude;
  
  charging a valley fill capacitor that is connected to the first node as the voltage amplitude of the changing voltage signal increases by coupling the valley fill capacitor to the changing voltage signal;
  
  decoupling the valley fill capacitor from the changing voltage signal at a first time that occurs when the voltage amplitude of the changing input voltage signal has reached more than 90% of the peak amplitude; and
  
  coupling the valley fill capacitor to the changing voltage signal when the voltage amplitude of the changing voltage signal drops below a valley voltage threshold.
- View Dependent Claims (44, 45, 46)
- - 44. The method of claim 43, wherein the coupling of the valley fill capacitor to the changing voltage signal when the voltage amplitude of the changing input voltage signal drops below the valley voltage threshold provides a supplemented voltage onto the first node that prevents the first node from having a voltage lower than the valley voltage threshold.
  - 45. The method of claim 43, wherein the coupling the valley fill capacitor to the changing input voltage signal when the voltage amplitude of the changing voltage signal drops below the valley voltage threshold causes light to be emitted from the string of series-connected LEDs, and wherein the emitted light exhibits a peak-to-peak fluctuation of light intensity of less than 50% from a mean light intensity.
  - 46. The method of claim 43, further comprising:
    - adjusting the LED current based on a dimmer phase cut angle.

47. A system comprising:
- a rectifier that is coupled to a first node, wherein a changing voltage signal with a voltage amplitude is present on the first node;
  
  a terminal of an integrated circuit that is coupled to a second node;
  
  a string of series-connected LEDs through which an LED current flows from the first node to the second node, wherein a number of light emitting diodes (LEDs) in the string of series-connected LEDs through which the LED current flows is increased as the voltage amplitude of the changing voltage signal increases to a peak amplitude, wherein the number of LEDs in the string of series-connected LEDs through which the LED current flows is decreased as the voltage amplitude of the changing voltage signal decreases from the peak amplitude; and
  
  a valley fill capacitor that is coupled to the first node, wherein the valley fill capacitor is charged as the voltage amplitude of the changing voltage signal increases, wherein the valley fill capacitor is decoupled from the changing voltage signal at a first time that occurs when the voltage amplitude of the changing voltage signal has reached at least 90% of the peak amplitude, and wherein the valley fill capacitor is coupled to the changing voltage signal when the voltage amplitude of the changing input voltage signal drops below a valley voltage threshold.
- View Dependent Claims (48, 49)
- - 48. The system of claim 47, wherein the valley fill capacitor provides a supplemented voltage onto the first node that prevents the first node from having a voltage lower than the valley voltage threshold when the voltage amplitude of the changing voltage signal would otherwise drop below the valley voltage threshold.
  - 49. The system of claim 47, wherein the integrated circuit couples the valley fill capacitor to the changing voltage signal when the voltage amplitude of the changing voltage signal drops below the valley voltage threshold by coupling the valley fill capacitor when the number of LEDs in the string of series-connected LEDs through which the LED current flows is decreased to a predetermined number.

50. A system comprising:
- a full wave rectifier coupled to a first node and to a ground node;
  
  a string of series-connected LEDs through which an LED current flows from the first node to a second node;
  
  a capacitor coupled to the first node and to a third node; and
  
  an integrated circuit with a capacitor terminal, a switch terminal and a valley fill switch, wherein the capacitor terminal is coupled to the third node, wherein the switch terminal is coupled to the second node, and wherein the valley fill switch is coupled to the capacitor terminal.
- View Dependent Claims (51, 52, 53, 54)
- - 51. The system of claim 50, wherein the integrated circuit includes a VSS terminal that is coupled to the ground node, and wherein the valley fill switch is coupled to the VSS terminal.
  - 52. The system of claim 50, wherein the integrated circuit includes a VSS terminal that is coupled to the ground node, and wherein the valley fill switch selectively couples the capacitor terminal to the VSS terminal.
  - 53. The system of claim 50, wherein the integrated circuit includes a VSS terminal that is coupled to the ground node, wherein the valley fill switch is closed during a first part of an alternating-current signal received onto the full wave rectifier such that the capacitor terminal and the VSS terminal are coupled together thereby charging the capacitor, and wherein the valley fill switch is open during a second part of the alternating-current signal thereby maintaining a charge on the capacitor that is later used to raise a voltage on the first node when the alternating-current signal has a voltage that falls below a valley voltage threshold.
  - 54. The system of claim 50, wherein a changing voltage signal with a voltage amplitude is present on the first node, wherein a number of light emitting diodes (LEDs) in the string of series-connected LEDs through which the LED current flows is increased as the voltage amplitude of the changing voltage signal increases to a peak amplitude, wherein the number of LEDs in the string of series-connected LEDs through which the LED current is decreased as the voltage amplitude of the changing voltage signal decreases from the peak amplitude, wherein the capacitor is charged as the voltage amplitude of the changing voltage signal increases, wherein the valley fill switch decouples the capacitor from the changing voltage signal when the voltage amplitude of the changing voltage signal reaches at least 90% of the peak amplitude, and wherein the valley fill switch couples the capacitor to the changing voltage signal when the voltage amplitude of the changing voltage signal would otherwise drop below a valley voltage threshold.

55. A method comprising:
- increasing a number of light emitting diodes (LEDs) in a string of series-connected LEDs through which an LED current flows from a first node to a second node as a voltage amplitude of a changing voltage signal increases to a peak amplitude;
  
  decreasing the number of LEDs in the string of series-connected LEDs through which the LED current flows from the first node to the second node as the voltage amplitude of the changing voltage signal decreases from the peak amplitude;
  
  storing energy from the changing voltage signal in a passive component as the voltage amplitude of the changing voltage signal increases; and
  
  releasing energy from the passive component when the voltage amplitude of the changing voltage signal drops below a valley voltage threshold and thereby doubling the rate by which peaks of light intensity are emitted from the string of series-connected LEDs.
- View Dependent Claims (56)
- - 56. The method of claim 55, further comprising:
    - adjusting the LED current based on a dimmer phase cut angle.

57. A method comprising:
- using a full wave rectifier and a valley fill capacitor to convert an AC signal of a first frequency into an AC signal of a second frequency, wherein the second frequency is four times the first frequency; and
  
  driving a string of Light Emitting Diodes (LEDs) with the AC signal of the second frequency, wherein a terminal of the valley fill capacitor is coupled to an end of the string of LEDs.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Active-Semi, Inc. (Qorvo, Inc.)
Original Assignee
Active-Semi, Inc. (Qorvo, Inc.)
Inventors
Huynh, Steven

Granted Patent

US 8,456,095 B2
Time in Patent Office

Days
Field of Search
US Class Current

315/185.R
CPC Class Codes

H05B 45/14   using electrical feedback f...

H05B 45/30   Driver circuits

H05B 45/31   Phase-control circuits

H05B 45/345   Current stabilisation; Main...

H05B 45/355   Power factor correction [PF...

H05B 45/36   Circuits for reducing or su...

H05B 45/395   Linear regulators

H05B 45/48   having LEDs organised in st...

H05B 45/50   responsive to malfunctions ...

H05B 45/54   in a series array of LEDs

H05B 45/56   involving measures to preve...

H05B 45/59   for reducing or suppressing...

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

Reduced flicker AC LED lamp with separately shortable sections of an LED string

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

124 Citations

57 Claims

Specification

Solutions

Use Cases

Quick Links

Reduced flicker AC LED lamp with separately shortable sections of an LED string

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

124 Citations

57 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links