Two-wire dimmer with improved zero-cross detention

What is claimed is: 1. A dimmer switch control circuit to: receive a signal from the controllably conductive device that represents a voltage developed across the controllably conductive device during a portion of an alternating current (AC) half-cycle; generate a direct current (DC) fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle; combine the AC signal received from the controllably conductive device and the DC fill signal to produce a combined signal, the combined signal having the same frequency as an AC supply signal to the controllably conductive device; and filter the combined signal by filtering the signal received from the controllably conductive device during the portion of the AC half-cycle in which the voltage is developed across the controllably conductive device and filtering the DC fill signal during the remaining portion of the AC half-cycle. 2. The dimmer switch control circuit of claim 1 wherein to generate the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, the dimmer switch control circuit to further: generate a constant DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 3. The dimmer switch control circuit of claim 1 wherein to generate the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, the dimmer switch control circuit to further: generate a ramped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 4. The dimmer switch control circuit of claim 1 wherein to generate the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, the dimmer switch control circuit to further: generate a sine-wave-shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 5. The dimmer switch control circuit of claim 4 wherein to generate the sine-wave-shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, the dimmer switch control circuit to further: generate a step-sine wave DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 6. The dimmer switch control circuit of claim 5 wherein to generate the step-sine wave shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, the dimmer switch control circuit to further: generate the step-sine wave DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, wherein the step-sine wave DC fill signal includes steps based on at least one pulse-width modulated signal. 7. A method to control power delivered to an electrical load, the method comprising: receiving, by a dimmer switch control circuit, a signal from a controllably conductive device that represents a voltage developed across the controllably conductive device during a portion of an alternating current (AC) half-cycle; generating, by the dimmer switch control circuit, a direct current (DC) fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle; combining, by the dimmer switch control circuit, the AC signal received from the controllably conductive device and the DC fill signal to produce a combined signal, the combined signal having the same frequency as an AC supply signal to the controllably conductive device; and filtering, by the dimmer switch control circuit, the combined signal by filtering the signal received from the controllably conductive device during the portion of the AC half-cycle in which the voltage is developed across the controllably conductive device and filtering the DC fill signal during the remaining portion of the AC half-cycle. 8. The method of claim 7 wherein generating the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, further comprises: generating, by the dimmer switch control circuit, a constant DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 9. The method of claim 7 wherein generating the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, further comprises: generating, by the dimmer switch control circuit, a ramped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 10. The method of claim 7 wherein generating the DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, further comprises: generating, by the dimmer switch control circuit, a sine-wave-shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 11. The method of claim 10 wherein generating the sine-wave-shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, further comprises: generating, by the dimmer switch control circuit, a step-sine wave DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle. 12. The method of claim 11 wherein generating the step-sine wave shaped DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, further comprises: generating, by the dimmer switch control circuit, the step-sine wave DC fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle, wherein the step-sine wave DC fill signal includes steps based on at least one pulse-width modulated signal. 13. A non-transitory, machine-readable, storage device that includes instructions that, when executed by a dimmer switch control circuit, causes the dimmer switch control circuit to: receive a signal from a controllably conductive device that represents a voltage developed across the controllably conductive device during a portion of an alternating current (AC) half-cycle; generate a direct current (DC) fill signal that complements the signal received from the controllably conductive device during the remaining portion of the AC half-cycle; combine the AC signal received from the controllably conductive device and the DC fill signal to produce a combined signal, the combined signal having the same frequency as an AC supply signal to the controllably conductive device; and filter the combined signal by filtering the signal received from the controllably conductive device during the portion of the AC half-cycle in which the voltage is developed across the controllably conductive device and filtering the DC fill signa