Leading-edge phase-cut dimmer detector

What is claimed is: 1. A circuit for detecting a leading-edge phase-cut dimmer, comprising: an edge detector operable to receive an input signal, detect whether the input signal has a rapidly rising edge, and generate an edge detector output signal, wherein the edge detector output signal comprises a signal pulse if a rapidly rising edge is detected in the input signal; a pulse stretcher operable to receive the edge detector output signal and generate a pulse stretcher output signal, wherein if the edge detector output signal comprises a signal pulse, the pulse stretcher output signal comprises a stretched pulse having a duration that is longer than the signal pulse received from the edge detector; and a filter operable to receive the pulse stretcher output signal and generate a filter output signal, wherein if the pulse stretcher output signal comprises at least a predetermined number of stretched pulses within a predetermined amount of time, the filter output signal indicates the presence of a leading-edge phase-cut dimmer, the filter comprising a filter capacitor whose value in part determines the number of stretched pulses that must be received from the pulse stretcher before the presence of a leading-edge phase-cut dimmer is indicated. 2. The circuit of claim 1 , wherein the edge detector comprises: an edge detector comparator configured to receive the input signal at a first input of the edge detector comparator, the output of the edge detector comparator representing the edge detector output signal; an RC circuit comprising a RC resistor having a first end coupled to the input signal and a second end coupled to a RC capacitor; and an offset voltage source coupled to the junction of the RC resistor and the RC capacitor of the RC circuit, operable to add a voltage offset to the signal present at the junction of the RC resistor and the RC capacitor, and providing the resulting offset signal to the second input of the edge detector comparator. 3. The circuit of claim 1 , wherein the pulse stretcher comprises a pulse stretcher capacitor whose value determines the pulse width of any stretched pulse generated by the pulse stretcher. 4. The circuit of claim 1 , wherein the pulse stretcher comprises: an R-S flip-flop coupled to receive the edge detector output signal at its S input; a first pulse stretcher switch coupled to receive the output of the R-S flip-flop at a first terminal, wherein a voltage at said first terminal controls current flow from a second terminal of the first pulse stretcher switch to a third terminal of the first pulse stretcher switch; a first pulse stretcher current source supplying a fixed current to the second terminal of the switch; a first pulse stretcher comparator coupled to receive a signal present at the third terminal of the first pulse stretcher switch, compare it to a first reference voltage level, and output a logical “1” if the signal present at the third terminal of the first pulse stretcher switch is greater than the reference voltage, the output of the first pulse stretcher comparator being coupled to the R input of the R-S flip-flop; and a second pulse stretcher comparator coupled to receive the signal present at the third terminal of the first pulse stretcher switch, compare it to a second reference voltage level lower than the first reference voltage level, and output a logical “1” if the signal present at the third terminal of the first pulse stretcher switch is greater than the reference voltage, the output of the second pulse stretcher comparator representing the output of the pulse stretcher. 5. The circuit of claim 4 , wherein the pulse stretcher further comprises a pulse stretcher capacitor coupled to the third terminal of the first pulse stretcher switch. 6. The circuit of claim 1 , wherein the filter comprises: a filter switch coupled to receive the pulse stretcher output signal at a first terminal, wherein a voltage at said first terminal controls current flow from a second terminal of the filter switch to a third terminal of the filter switch; a first filter current source supplying a fixed current to the first terminal of the filter switch; a second filter current source connected to the third terminal of the filter switch and providing a fixed current flowing away from said third terminal, wherein a magnitude of the second filter current source is lower than a magnitude of the first filter current source; and a filter comparator coupled to receive the signal present at the third terminal of the filter switch, compare it with a reference voltage level, and output a logical “1” if the signal present at the third terminal of the filter switch is greater than the reference voltage. 7. The circuit of claim 6 , wherein the filter capacitor is coupled to the third terminal of the filter switch. 8. The circuit of claim 1 , wherein the circuit further comprises a latch operable to receive the filter output signal and to latch a filter output signal that indicates the presence of a leading-edge phase-cut dimmer. 9. A method for detecting a leading-edge phase-cut dimmer, comprising: receiving an input signal; detecting whether the input signal has a rapidly rising edge; if a rapidly rising edge is detected in the input signal, generating a signal pulse; stretching the signal pulse to generate a stretched pulse having a duration that is longer than the duration of the signal pulse; and if at least a predetermined number of stretched pulses are generated within a predetermined amount of time, generating a signal indicating the presence of a leading-edge phase-cut dimmer; if a signal indicating the presence of a leading-edge phase-cut dimmer is generated, providing a constant current load to an LED lighting device; and if a signal indicating the presence of a leading-edge phase-cut dimmer is not generated, providing a high-power-factor load to an LED lighting device. 10. A circuit for detecting a leading-edge phase-cut dimmer, comprising: a light-emitting diode driven by an LED driver signal; an edge detector operable to receive the LED driver signal, detect whether the LED driver signal has a rapidly rising edge, and provide an edge detector output signal, wherein the edge detector output signal comprises a signal pulse if a rapidly rising edge is detected in the LED driver signal; a pulse stretcher operable to receive the edge detector output signal and provide a pulse stretcher output signal, wherein if the edge detector output signal comprises a signal pulse, the pulse stretcher output signal comprises a stretched pulse having a duration that is longer than the signal pulse received from the edge detector; a filter operable to receive the pulse stretcher output signal and generate an indicator signal, wherein the filter comprises a filter capacitor whose value in part determines the number of stretched pulses that must be received from the pulse stretcher before the presence of a leading-edge phase-cut dimmer is indicated, and wherein if the pulse stretcher output signal comprises at least a predetermined number of stretched pulses within a predetermined amount of time, the indicator signal indicates the presence of a leading-edge phase-cut dimmer in a circuit generating the LED driver signal; and a loading circuit configured to receive the indicator signal and, if the indicator signal indicates the presence of a leading-edge phase-cut dimmer, provide a constant current load to the light-emitting diode, and, if the indicator signal indicates the absence of a leading-edge phase-cut dimmer, provide a high power factor load to the light-emitting diode. 11. The circuit of claim 10 , wherein the edge detector comprises: an edge detector comp