System and method for controlling an active material actuator

The invention claimed is: 1. A system for controlling an active material actuator, comprising: a power supply configured to supply electrical power; a control circuitry including a plurality of circuits and configured to selectively establish an electrical connection between the active material actuator and the power supply upon receipt of an activation signal, the active material actuator being configured to actuate when energized; and wherein the control circuitry is configured to de-energize at least one of the plurality of circuits when no activation signal is received by the control circuitry in order to minimize parasitic current drawn from the power supply; wherein the plurality of circuits includes a voltage sensing circuit configured to measure a voltage potential of the electrical power supplied by the power supply, the voltage sensing circuit being configured to de-energize when no activation signal is received by the control circuitry; and wherein the voltage sensing circuit includes a low on-resistance solid state switch configured to selectively disconnect the voltage sensing circuit from the power supply when no activation signal is received by the control circuitry. 2. The system of claim 1 , wherein the plurality of circuits includes a power supply filter electrically connected to the power supply, the power supply filter being configured to filter an output voltage supplied by the power supply. 3. The system of claim 2 , wherein the power supply filter includes at least one diode configured to prevent reverse voltage. 4. The system of claim 2 , wherein the plurality of circuits includes a bias voltage regulator electrically connected to the power supply filter, the bias voltage regulator configured to regulate the output voltage supplied by the power supply, and the power supply filter includes a diode configured to prevent reverse voltage. 5. The system of claim 4 , wherein the bias voltage regulator is configured to de-energize when no activation signal is received by the control circuitry. 6. The system of claim 1 , wherein the plurality of circuits includes a power switch circuit configured to selectively establish the electrical connection between the active material actuator and the power supply when the control circuitry receives the activation signal. 7. The system of claim 6 , wherein the power switch circuit includes a low on-resistance solid state switch to control an electrical current across the active material actuator. 8. The system of claim 6 , wherein the plurality of circuits includes a digital control processor configured to generate a pulse width modulation signal having a duty cycle, the digital control processor being electrically connected to the power switch circuit such that the digital control processor is configured to transmit the pulse width modulation signal to the power switch circuit. 9. The system of claim 8 , wherein the plurality of circuits includes a temperature sensing circuit configured to measure an ambient temperature adjacent the active material actuator and generate a temperature signal indicative of the ambient temperature. 10. The system of claim 8 , further comprising a computer program port electrically connected to the digital control processor, the computer program port being configured to allow transfer of data between the digital control processor and a remote computer. 11. The system of claim 1 , wherein the control circuitry includes a signal processing unit configured to filter the activation signal supplied by an external controller, and the signal processing unit includes a low pass filter circuit and a Zener diode electrically connected to the low pass filter circuit to impose limits on the activation signal to thereby generate a control signal. 12. The system of claim 1 , wherein the the low on-resistance solid state switch of the voltage sensing circuit is a first low on-resistance solid state switch, the plurality of circuits includes a power supply filter electrically connected to the power supply, the power supply filter is configured to filter an output voltage supplied by the power supply, the power supply filter includes a first diode configured to prevent reverse voltage, the plurality of circuits includes a bias voltage regulator electrically connected to the power supply filter, the bias voltage regulator is configured to regulate the output voltage supplied by the power supply, the bias voltage regulator is configured to de-energize when no activation signal is received by the control circuitry, the plurality of circuits includes a power switch circuit configured to selectively establish the electrical connection between the active material actuator and the power supply when the control circuitry receives the activation signal, the power switch circuit includes a second low on-resistance solid state switch to control an electrical current across the active material actuator, the plurality of circuits includes a digital control processor configured to generate a pulse width modulation signal having a duty cycle, the digital control processor is electrically connected to the power switch circuit such that the digital control processor is configured to transmit the pulse width modulation signal to the power switch circuit, the plurality of circuits includes a temperature sensing circuit configured to measure an ambient temperature adjacent the active material actuator and generate a temperature signal indicative of the ambient temperature, the plurality of circuits includes a position sensing circuit configured to detect a position of the active material actuator and generate a position signal indicative of the position of the active material actuator, and the position sensing circuit includes a first non-electrolytic capacitor, and an op-amp buffer amplifier electrically connected to the first non-electrolytic capacitor, the plurality of circuits includes a current sensing circuit configured to measure an electrical current across the active material actuator and generate a current signal indicative of the electrical current, the digital control processor is configured to receive the temperature signal, the current signal, a voltage signal, and position signal, and wherein the digital control processor is configured to adjust the duty cycle of the pulse width modulation signal based on the current signal, the voltage signal, the position signal, and the temperature signal, the system includes a computer program port electrically connected to the digital control processor, the computer program port being configured to allow transfer of data between the digital control processor and a remote computer, the control circuitry includes a signal processing unit configured to filter the activation signal supplied by an external controller, and the signal processing unit includes a low pass filter circuit and a first Zener diode electrically connected to the low pass filter circuit to impose limits on the activation signal to thereby generate a control signal, the low pass filter circuit includes a first resistor and a second non-electrolytic capacitor, the first resistor electrically connected in parallel with the second non-electrolytic capacitor, the first diode is a first p-n diode, the power supply filter includes a second non-electrolytic capacitor, a first electrolytic capacitor, a second electrolytic capacitor, and a transient voltage suppression diode electrically connected in parallel with each other, the temperature sensing circuit includes a negative temperature coefficient thermistor and a second resistor, the negative temperature coefficient thermistor is electrically connected in series with the second resis