Reduction of Harmonic Distortion for LED Loads

What is claimed: 1 . A method of conditioning current in a light engine, the method comprising: providing a pair of input terminals adapted to receive a periodic excitation voltage; receiving a current of equal magnitude and opposite polarity into each one of the pair of terminals, said current flowing in response to the excitation voltage; providing a plurality of light emitting diodes (LEDs) arranged in a first network, said first network arranged to conduct said current in response to the excitation voltage exceeding at least a forward threshold voltage associated with the first network; providing a plurality of LEDs arranged in a second network in series relationship with said first network; providing a bypass path in parallel with said second network and in series relationship with said first network; dynamically increasing an impedance of the bypass path as a substantially smooth and continuous function of said current amplitude in response to said current amplitude increasing in a range above a threshold current value; substantially smoothly and continuously reducing current flow through the bypass path in response to a substantially smooth and continuous increase in the voltage drop across the bypass path in a range above the forward threshold voltage associated with the second network. 2 . The method of claim 1 , wherein said excitation voltage comprises a periodic waveform having voltages of alternating polarity in each period. 3 . The method of claim 1 , further comprising rectifying the excitation voltage received at the input terminals to form a substantially unipolar excitation voltage to drive said current. 4 . The method of claim 1 , further comprising modulating the excitation voltage. 5 . The method of claim 4 , wherein modulating the excitation voltage comprises controlling an amplitude of the excitation voltage. 6 . The method of claim 4 , wherein modulating the excitation voltage comprises receiving a control signal and, in response to information contained in the control signal, applying the excitation voltage to the input terminals only during a portion of the period of the excitation voltage waveform that corresponds to the information in the control signal. 7 . The method of claim 6 , wherein applying the excitation voltage to the input terminals only during a portion of the period of the excitation voltage waveform that corresponds to the information contained in the control signal comprises delaying application of the excitation voltage to the input terminals during at least one of the periods, wherein a length of the delay is responsive to the information contained in the control signal. 8 . The method of claim 6 , wherein applying the excitation voltage to the input terminals only during a portion of the period of the excitation voltage waveform that corresponds to the information contained in the control signal comprises advancing removal of the excitation voltage from the input terminals during at least one of the periods, wherein a length of the advance is responsive to the information contained in the control signal. 9 . The method of claim 1 , further comprising modulating the impedance of the bypass path at two times a fundamental frequency of the excitation voltage waveform. 10 . The method of claim 1 , further comprising modulating the impedance of the bypass path at a fundamental frequency of a unipolar excitation voltage waveform. 11 . The method of claim 1 , further comprising arranging said first network, said second network, said substantially smooth and continuous function of said current, and said threshold current value so that said current exhibits less than 30% total harmonic distortion in response to the excitation voltage having a substantially sinusoidal waveform. 12 . A light engine comprising: a pair of input terminals adapted to receive a periodic excitation voltage and receive a current of equal magnitude and opposite polarity into each one of the pair of terminals, said current flowing in response to the excitation voltage; a plurality of light emitting diodes (LEDs) arranged in a first network, said first network arranged to conduct said current in response to the excitation voltage exceeding at least a forward threshold voltage associated with the first network; a plurality of LEDs arranged in a second network in series relationship with said first network; a bypass path in parallel with said second network and in series relationship with said first network; a controllable impedance element in the bypass path; and, a dynamic impedance control module coupled to the controllable impedance element, said dynamic impedance control module adapted to dynamically operate the controllable impedance element to increase an impedance of the bypass path as a substantially smooth and continuous function of said current amplitude in response to said current amplitude increasing above a threshold current value, the dynamic impedance module being further adapted to dynamically operate the controllable impedance element to substantially smoothly and continuously reduce current flow through the bypass path in response to a substantially smooth and continuous increase in the voltage drop across the bypass path in a range above the forward threshold voltage associated with the second network.