Solid state lighting devices utilizing memristors

I claim: 1. A circuit, comprising: a light emitting diode (LED); a memristor coupled to the LED; and a resistor connected in parallel with said memristor and coupled to the LED, in which a change in a resistance of the combination of the memristor and the resistor changes an emission intensity of the LED. 2. The circuit of claim 1 , wherein said memristor varies a drive signal applied to said LED. 3. The circuit of claim 1 , wherein said emission intensity is varied in response to changes in a resistance of said memristor. 4. The circuit of claim 1 , wherein as the emission intensity of said LED varies over time, said memristor varies a drive signal to said LED to compensate for at least a portion of said variation of the emission intensity. 5. The circuit of claim 1 , wherein as the emission intensity of said LED depreciates over time, said memristor increases a drive signal to said LED to compensate for at least a portion of said depreciation of the emission intensity. 6. The circuit of claim 1 , wherein as the emission intensity of said LED varies with operating temperature, said memristor varies a drive signal to said LED to compensate for at least a portion of said variation in operating temperature. 7. The circuit of claim 1 , wherein said memristor increases a drive signal applied to said LED over time. 8. The LED chip circuit of claim 1 , wherein said resistor is a thermistor. 9. A light emitting diode (LED) chip circuit, comprising: an LED chip; and a resistor circuit, coupled to said LED chip, comprising a memristor in parallel with a resistor; wherein a change in a resistance of said memristor changes a resistance of said resistor circuit. 10. The LED chip circuit of claim 9 , wherein said resistor circuit is coupled to a red emitting LED chip. 11. A light emitting diode (LED) chip circuit, comprising: an LED chip; and a bypass circuit, coupled to said LED chip, the bypass circuit comprising a memristor in parallel with a resistor to vary an emission intensity of said LED chip. 12. The LED chip circuit of claim 11 , further comprising a second LED hip in series with said LED chip, said bypass circuit coupled across said LED chip. 13. The LED chip circuit of claim 12 , wherein a decrease in resistance from said memristor causes an increase in current bypassing said LED chip through said bypass circuit. 14. The LED chip circuit of claim 13 , wherein said LED chip is a Blue-Shifted Yellow (BSY) emitting LED chip and said second LED chip is a red emitting LED chip. 15. A solid state luminaire comprising: a first light emitting diode (LED) chip having at least one of a time-varying emission intensity and a temperature-dependent emission intensity; a memristor to vary a drive signal applied to said first LED chip to compensate for said emission changes; and a resistor connected in parallel with said memristor. 16. The solid state luminaire of claim 15 , wherein a resistance of said memristor is varied to vary said drive signal. 17. The solid state luminaire of claim 15 , further comprising a second LED chip, said memristor varying the drive signal to said first LED chip to maintain a desired combination of light from said first and second LED chips. 18. A solid state luminaire comprising: a first light emitting diode (LED) chip having at least one of a time-varying emission intensity and a temperature-dependent emission intensity; and a resistor circuit coupled to said first LED chip, said resistor circuit comprising a memristor in parallel with resistor to vary a drive signal applied to said first LED chip to compensate for said said at least one of said time-varying emission intensity and said temperature-dependent emission intensity, wherein a change in a resistance of said memristor changes a resistance of said resistor circuit. 19. A solid state luminaire comprising: a first light emitting diode (LED) chip having at least one of a time-varying emission intensity; and a temperature-dependent emission intensity; and a bypass circuit coupled to said first LED chip, said bypass circuit comprising a memristor in parallel with a resistor to vary a drive signal applied to said first LED chip to compensate for said at least one of said time-varying emission intensity and said temperature-dependent emission intensity. 20. A solid state light engine comprising: a light emitting diode (LED) chip array comprising at least one first LED chip emitting at one color of light and at least one second LED chip emitting a different color of light than said at least one first LED chip, wherein an emission of said at least one first LED chip and an emission of said at least one second LED chip depreciates over time at different rates; a memristor coupled to said LED chip array to vary a drive signal applied to said at least one first LED chip to compensate for at least a portion of said different rates of emission depreciation; and a resistor connected in parallel with said memristor. 21. The solid state light engine of claim 20 , wherein a resistance of said memristor is varied to vary said drive signal. 22. The solid state light engine of claim 20 , wherein said memristor varies the drive signal to said at least one first LED chip to maintain a desired combination of light from said at least one first LED chip and said at least one second LED chip. 23. A solid state luminaire, comprising: a housing comprising a housing opening; a light engine in said housing with an array of light emitting diode (LED) chips comprising first and second LED chips emitting at different colors of light, the light from said first and second LED chips emitting out said housing opening; a memristor to vary the emission of at least one of said first and second LED chips over time; and a resistor connected in parallel with said memristor. 24. The solid state luminaire of claim 23 , further comprising a mounting mechanism to mount said housing. 25. The solid state luminaire of claim 23 , wherein the resistance of said memristor is varied no vary said emission. 26. The solid state luminaire of claim 23 , wherein said memristor varies the drive signal to at least one of said first LED chips over time to maintain a desired combination of light from said first and second LED chips. 27. A solid state lighting device, comprising: a light emitting diode (LED); a memristor that receives DC current while the LED is being driven by a drive current; a drive circuit that provides said drive current, said drive circuit responsive to the memristor resistance value and varying the drive current to said LED based on the resistance of said memristor; and a resistor connected in parallel with said memristor. 28. A solid state lighting device, comprising: a light emitting diode (LED); a memristor in parallel with a resistor, wherein the parallel combination of said memristor and said resistor receives DC current while the LED is being driven by a drive current; and a drive circuit that provides said drive current, said drive circuit responsive to the memristor resistance value and varying the drive current to said LED based on the resistance of said memristor, wherein the DC current received by said memristor is proportional to said drive current. 29. A solid state lighting device, comprising: light emitting diode (LED); a memristor in parallel with