Isolated control circuit and driver for micro-electromechanical system switch

What is claimed is: 1 . A switching system comprising: a switch connectable to a power circuit to receive a load current therefrom, the switch comprising one of an electrical switch, an electromechanical switch, a transistor, or a relay; and a control circuit operably connected to the switch to control selective switching of the switch, the control circuit comprising: control input terminals to receive an On-Off signal indicative of a desired operating state of the switch; control output terminals that transmit power and control signals to the switch responsive to the received On-Off signal; an oscillator coupled to the control input terminals and configured to generate a first electrical pulse responsive to the received On-Off signal, the first electrical pulse having one of a first signal characteristic and a second signal characteristic that is determined by the On-Off signal; a pulse transformer connected to receive the first electrical pulse from the oscillator and output a second electrical pulse electrically isolated from the first electrical pulse, the second electrical pulse having the same one of the first signal characteristic and the second signal characteristic as the first electrical pulse; and a pulse detection circuit configured to: receive the second electrical pulse; determine whether the second electrical pulse has the first signal characteristic or the second signal characteristic; and control transmission of power and control signals to the switch based on the determination of the second electrical pulse having the first signal characteristic or the second signal characteristic; wherein the first signal characteristic comprises one of a first frequency and a first duty cycle and the second signal characteristic comprises one of a second frequency and a second duty. 2 . The switching system of claim 1 wherein the switch comprises a micro-electromechanical system (MEMS) switching circuit including a MEMS switch and a MEMS driver circuit, and wherein the power and control signals transmitted to the MEMS switching circuit via the pulse detection circuit are transmitted to the MEMS driver circuit, which selectively provides a switching voltage to the MEMS switch to cause the MEMS switch to actuate to an open or closed position. 3 . The switching system of claim 2 wherein, when the On-Off signal received by the oscillator is an On signal, the oscillator generates a first electrical pulse having the first signal characteristic. 4 . The switching system of claim 3 wherein, when the pulse detection circuit determines the second electrical pulse has the first signal characteristic, the power and control signals transmitted to the MEMS switching circuit comprise logic high signals that cause the MEMS switch to actuate to the closed position. 5 . The switching system of claim 2 wherein, when the On-Off signal received by the oscillator is an Off signal, the oscillator generates a first electrical pulse having the second frequency. 6 . The switching system of claim 5 wherein, when the pulse detection circuit determines the second electrical pulse has the second signal characteristic, the power and control signals transmitted to the MEMS switching circuit comprise logic low signals that cause the MEMS switch to actuate to the open position. 7 . The switching system of claim 2 further comprising an auxiliary circuit coupled in parallel with the MEMS switching circuit, the auxiliary circuit comprising solid state switching circuitry that is selectively activatable to divert at least a portion of the load current away from the MEMS switch to flow to the auxiliary circuit; and wherein the control circuit is operably connected to the auxiliary circuit, to provide power and control signals to selectively activate the solid state switching circuitry. 8 . The switching system of claim 7 wherein the power and control signals transmitted to the MEMS switching circuit cause the MEMS switch to actuate to the open or closed position within a prescribed switching interval; and wherein the control circuit is programmed to: activate the auxiliary circuit during the switching interval when the MEMS switch is switching between the open and closed positions, such that at least a portion of the load current flows toward the auxiliary circuit; and deactivate the auxiliary circuit upon reaching the open or closed position after completion of the switching interval, such that the load current flows through the MEMS switch. 9 . The switching system of claim 2 wherein the control circuit further comprises: a first capacitor positioned on a primary side of the pulse transformer; a second capacitor positioned on a secondary side of the pulse transformer; and a first diode positioned on the secondary side of the pulse transformer; wherein the first and second capacitors and the first diode operate with the pulse transformer such that the duty cycle and/or frequency of the second electrical pulse is the same as the duty cycle and/or frequency of the first electrical pulse. 10 . The switching system of claim 9 wherein the control circuit further comprises a peak voltage detector including a second diode and a third capacitor, wherein an output of the peak voltage detector is provided to one of the output terminals to provide power to at least one of the MEMS driver circuit, the auxiliary circuit, and the pulse detection circuit. 11 . The switching system of claim 9 wherein the control circuit further comprises a third diode and a resistor positioned on a secondary side of the pulse transformer such that the second electrical pulse is routed therethrough, with the second electrical pulse being routed out through the third diode and the resistor to the pulse detection circuit. 12 . The switching system of claim 1 wherein the control circuit further comprises a driver coupled to an output of the oscillator, the driver boosting a current carrying capability to the first electrical pulse and providing a low voltage buffer in the control circuit. 13 . A micro-electromechanical system (MEMS) relay circuit comprising: a MEMS switching circuit including: a MEMS switch moveable between an open position and a closed position to selectively pass a load current therethrough; and a MEMS driver circuit configured to provide a drive signal to cause the MEMS switch to move between the open and closed positions; and a control circuit operably connected to the MEMS switching circuit to control switching of the MEMS switch, the control circuit comprising: a pulse transformer configured to isolate a control side of the control circuit from a power side of the control circuit; an oscillator positioned on the control side and configured to generate a first electrical pulse responsive to a received On-Off signal, the first electrical pulse having one of a specified frequency and a specified duty cycle based on the On-Off signal, the specified frequency comprising one of a first frequency and a second frequency and the specified duty cycle comprising one of a first duty cycle and a second duty cycle; and power and logic circuitry positioned on the power side and configured to: condition an output of the pulse transformer to provide a second electrical pulse, the second electrical pulse having the same one of the specified frequency or specified duty cycle as the first electrical pulse; determine whether the second electrical pulse is at the one of the specified first or second frequency or the specified first or second duty cycle; and transmit one of a logic high signal and a logic low signal to the MEMS switching circuit based on the de