Drive circuit for DC latching devices

What is claimed is: 1. A drive circuit for a DC latching device, the drive circuit comprising: a battery; a plurality of switches for momentarily energizing a coil of a DC latching device from the battery; a microcontroller in communication with the plurality of switches and configured to establish a first inductance associated with the DC latching device being in an open state, to establish a second inductance associated with the DC latching device being in a closed state, and to establish an inductance threshold that is between the first and second inductances; a sensing resistor configured in series with the coil to form a sensing circuit; circuitry configured to measure voltage and current across the sensing resistor while applying an AC signal to the sensing circuit, the AC signal having insufficient energy to change the state of the DC latching device; the microcontroller further configured to calculate an inductive reactance of the DC latching device based on the measured voltage and current, to calculate an inductance of the DC latching device based on the inductive reactance and a frequency of the AC signal, and to compare the calculated inductance of the DC latching device with the threshold inductance to determine a state of the DC latching device; and circuitry responsive to the determined state of the DC latching device. 2. The drive circuit of claim 1 wherein the AC signal is added to a first signal applied to the coil, and the circuitry configured to measure voltage and current is further configured to filter a voltage signal measured across the coil to produce a filtered signal. 3. The drive circuit of claim 2 further comprising a high-pass filter configured to filter the voltage signal measured across the coil. 4. The drive circuit of claim 2 wherein the measured voltage and current are based on the filtered signal. 5. The drive circuit of claim 1 wherein the current lags the voltage by approximately 90 degrees. 6. The drive circuit of claim 1 wherein the inductance reactance of the coil DC latching device is determined based on a ratio of the measured voltage and current. 7. The drive circuit of claim 1 wherein the DC latching device is a DC latching solenoid configured to be mounted in a pilot valve assembly of an irrigation valve. 8. An irrigation system comprising the drive circuit of claim 1 . 9. A drive circuit for a DC latching device, the drive circuit comprising: a battery; a plurality of switches for momentarily energizing a coil of a DC latching device from the battery; a microcontroller comprising at least one timer and in communication with the plurality of switches and configured to establish a first inductance associated with the DC latching device being in an open state, to establish a second inductance associated with the DC latching device being in a closed state, and to establish an inductance threshold that is between the first and second inductances; a capacitor configured in parallel with the coil to form a resonant circuit; the at least one timer configured to measure a period of the resonant signal from the resonant circuit when a first signal is applied to the resonant circuit, the first signal approximating an impulse function and having insufficient energy to change the state of the DC latching device; the microcontroller configured to calculate an inductance of the DC latching device based on the period of the resonant signal and a capacitance of the capacitor and to compare the calculated inductance of the DC latching device with the threshold inductance to determine a state of the DC latching device; and circuitry responsive to the determined state of the DC latching device. 10. The drive circuit of claim 9 wherein the first signal applied to the resonant circuit is a spectrally rich signal. 11. The drive circuit of claim 9 wherein the first signal applied to the resonant circuit is a low-level step function. 12. The drive circuit of claim 9 wherein the DC latching device is a DC latching solenoid configured to be mounted in a pilot valve assembly of an irrigation valve. 13. An irrigation system comprising the drive circuit of claim 9 . 14. A drive circuit for a DC latching device, the drive circuit comprising: a battery; a plurality of switches for momentarily energizing a coil of a DC latching device from the battery; a microcontroller in communication with the plurality of switches and configured to establish a first inductance associated with the DC latching device being in an open state, to establish a second inductance associated with the DC latching device being in a closed state, and to establish an inductance threshold that is between the first and second inductances; a resistor configured in series with the coil to form a voltage divider; circuitry configured to measure the voltage across the coil when an AC signal is applied to the voltage divider, the AC signal having insufficient energy to change the state of the DC latching device; the microcontroller configured to calculate an inductive reactance of the DC latching device based on the measured voltage, a resistance of the resistor, and a voltage of the AC signal, to calculate an inductance of the DC latching device based on the inductive reactance and a frequency of the AC signal, and to compare the calculated inductance of the DC latching device with the threshold inductance to determine a state of the DC latching device; and circuitry responsive to the determined state of the DC latching device. 15. The drive circuit of claim 14 wherein the circuitry configured to measure the voltage across the coil comprises peak detector circuitry. 16. The drive circuit of claim 15 wherein the circuitry configured to measure the voltage across the coil is further configured to sample an output of the peak detector circuitry. 17. The drive circuit of claim 16 wherein the microcontroller is further configured to compare samples of the output of the peak detector circuitry to a limit to determine the state of the DC latching device. 18. The drive circuit of claim 14 wherein the circuitry responsive to the determined state of the DC latching device comprises a processor. 19. The drive circuit of claim 14 wherein the DC latching device is a DC latching solenoid configured to be mounted in a pilot valve assembly of an irrigation valve. 20. An irrigation system comprising a valve comprising a pilot orifice that can be covered or uncovered to switch the valve between ON and OFF states, the DC latching device further comprising a plunger that retracts through the coil to cover and uncover the pilot orifice, and the drive circuit of claim 14 .