Abstract: Systems and methods for transferring power across an isolation barrier using an active self-synchronized rectifier are described. A rectifier as described herein may provide DC to DC power conversion with high efficiency. Furthermore, by using a microfabricated transformer or microfabricated capacitor as an isolation component, an isolation component and rectifier may be microfabricated and implemented on chip.

Abstract: Systems and methods for transferring power across an isolation barrier using an active self-synchronized resonator are described. A resonator may use the isolation barrier to resonate with active devices arranged on both sides of the barrier, to provide DC to DC power conversion with high efficiency. Furthermore, by using a microfabricated transformer or microfabricated capacitor as an isolator, the entire resonator may be microfabricated and implemented on chip. The resonator is also bidirectional, allowing power transfer in either direction across the isolation barrier.

Abstract: Systems and methods for transferring power across an isolation barrier using an active self-synchronized rectifier are described. A rectifier as described herein may provide DC to DC power conversion with high efficiency. Furthermore, by using a microfabricated transformer or microfabricated capacitor as an isolation component, an isolation component and rectifier may be microfabricated and implemented on chip.

Abstract: Systems and methods for transferring power across an isolation barrier using an active self-synchronized resonator are described. A resonator may use the isolation barrier to resonate with active devices arranged on both sides of the barrier, to provide DC to DC power conversion with high efficiency. Furthermore, by using a microfabricated transformer or microfabricated capacitor as an isolator, the entire resonator may be microfabricated and implemented on chip. The resonator is also bidirectional, allowing power transfer in either direction across the isolation barrier.

Abstract: It is often desirable to transmit data between circuits or components operating at a relatively high voltage and circuits operating at a relatively low voltage. Such a task can be performed by use of an isolator. Some isolator designs use magnetic coupling to transfer the data as this is more robust against inadvertently transmitting high voltage transients than capacitor based isolators. However it is often desirable to encode the data for exchange across the transformer of the isolator and decode after transmission across the transformer. This requires power for the encoding and decoding circuits. To ensure both sides are powered, power may be transferred by another transformer. The transformer primary is driven by an oscillating signal. The system disclosed in some embodiments herein varies the frequency of the oscillating signal to mitigate the risk of it interfering with other circuits or systems associated with the isolator.

Abstract: It is often desirable to transmit data between circuits or components operating at a relatively high voltage and circuits operating at a relatively low voltage. Such a task can be performed by use of an isolator. Some isolator designs use magnetic coupling to transfer the data as this is more robust against inadvertently transmitting high voltage transients than capacitor based isolators. However it is often desirable to encode the data for exchange across the transformer of the isolator and decode after transmission across the transformer. This requires power for the encoding and decoding circuits. To ensure both sides are powered, power may be transferred by another transformer. The transformer primary is driven by an oscillating signal. The system disclosed in some embodiments herein varies the frequency of the oscillating signal to mitigate the risk of it interfering with other circuits or systems associated with the isolator.