GaN-based half bridge power conversion circuits employ control, support and logic functions that are monolithically integrated on the same devices as the power transistors. In some embodiments, a low side GaN device communicates through one or more level shift circuits with a high side GaN device. B
GaN-based half bridge power conversion circuits employ control, support and logic functions that are monolithically integrated on the same devices as the power transistors. In some embodiments, a low side GaN device communicates through one or more level shift circuits with a high side GaN device. Both the high side and the low side devices may have one or more integrated control, support and logic functions.
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1. A half bridge GaN circuit, comprising: a low side circuit, comprising: a low side switch having a low side switch control gate and a first source,a level shift driver, comprising: a first level shift driver input connected to a first logic signal, wherein the first logic signal is referenced to t
1. A half bridge GaN circuit, comprising: a low side circuit, comprising: a low side switch having a low side switch control gate and a first source,a level shift driver, comprising: a first level shift driver input connected to a first logic signal, wherein the first logic signal is referenced to the voltage of the first source, anda level shift driver output, configured to transmit a first level shift input signal,a low side switch driver, comprising: a first low side switch driver input configured to receive a second logic signal, wherein the second logic signal is referenced to a voltage at the first source, anda first low side switch driver output connected to the low side switch control gate and configured to transmit a low side switch control signal to the low side switch control gate, wherein the low side switch control signal is generated based on the second logic signal,a first level shift circuit configured to receive the first level shift input signal and to generate a first level shift signal, anda second level shift circuit configured to generate a second level shift signal; anda high side circuit, comprising: a high side switch having a high side switch control gate and a second source,a first high side receiver circuit referenced to a voltage at the second source and configured to receive the first level shift signal and to generate a first high side driver control signal,a second high side receiver circuit referenced to the voltage of the second source and configured to receive the second level shift signal and to generate a second high side driver control signal, anda high side switch driver referenced to the voltage of the second source, wherein the high side switch driver comprises: one or more logic inputs configured to receive the first and second high side driver control signals, anda high side switch driver output connected to the high side switch control gate and configured to transmit a high side switch control signal to the high side switch control gate, wherein the high side switch control signal is generated base on the first and second high side driver control signals,wherein the first and second high side receiver circuits are configured to prevent a change of voltage state of the high side control gate in response to voltage transients of the voltage of the second source. 2. The half bridge GaN circuit of claim 1, wherein the first level shift signal is configured to cause the high side switch to turn on and wherein the second level shift signal is configured to cause the high side switch to turn off. 3. The half bridge GaN circuit of claim 1, wherein: the level shift driver further comprises: an HS STP input configured to receive a high side shoot through protection signal from the low side switch driver, wherein the level shift driver is configured to generate the first level shift input signal based in part on the high side shoot through protection signal;the low side switch driver further comprises: an LS STP input configured to receive a low side shoot through protection signal from the level shift driver, wherein the low side switch driver is configured to generate the low side switch control signal based in part on the low side shoot through protection signal; andthe high side shoot through protection signal and the low side shoot through protection signal are respectively generated by the low side switch driver and the level shift driver so as to prevent the high side switch and the low side switch from being simultaneously on. 4. The half bridge GaN circuit of claim 3, wherein the level shift driver comprises a first pulse generator configured to generate a pulse in response to a high to low transition of the first logic signal and to transmit the pulse to the first level shift driver output as the low side shoot through protection signal. 5. The half bridge GaN circuit of claim 4, wherein the low side switch control gate is controlled according to a logical combination of the low side shoot through protection signal, the first logic signal, and the second logic signal. 6. The half bridge GaN circuit of claim 3, wherein the low side switch driver comprises a second pulse generator configured to generate a pulse in response to a high to low transition of the second logic signal and to transmit the pulse to the first level shift driver as the high side shoot through protection signal. 7. The half bridge GaN circuit of claim 6, wherein the high side switch control gate is controlled according to a logical combination of the high side shoot through protection signal, the first logic signal, and the second logic signal. 8. The half bridge GaN circuit of claim 3, wherein the first level shift circuit is configured to generate a pulse in response to a high to low transition of the first logic signal and to output the pulse as the first level shift signal, wherein, in response to the first level shift signal, the first high side receiver is configured to reduce a turn-off propagation delay of the high side control gate. 9. The half bridge GaN circuit of claim 1, wherein the high side circuit further comprises: a first conductive element configured to pull up a voltage of the first level shift signal toward a voltage of a floating power supply;a first pull up transistor configured to pull up the voltage of the first level shift signal toward the voltage of the floating power supply;a second conductive element configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply; anda second pull up transistor configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply. 10. A half bridge GaN circuit, comprising: a low side circuit, comprising: a low side switch having a low side switch control gate and a first source,a level shift driver, comprising: a first level shift driver input connected to a first logic signal, wherein the first logic signal is referenced to the voltage of the first source, anda level shift driver output, configured to transmit a first level shift input signal,a low side switch driver, comprising: a first low side switch driver input configured to receive a second logic signal, wherein the second logic signal is referenced to a voltage at the first source, anda first low side switch driver output connected to the low side switch control gate and configured to transmit a low side switch control signal to the low side switch control gate, wherein the low side switch control signal is generated based on the second logic signal,a first level shift circuit configured to receive the first level shift input signal and to generate a first level shift signal, anda second level shift circuit configured to generate a second level shift signal; anda high side circuit, comprising: a high side switch having a high side switch control gate and a second source,a first high side receiver circuit referenced to a voltage at the second source and configured to receive the first level shift signal and to generate a first high side driver control signal,a second high side receiver circuit referenced to the voltage of the second source and configured to receive the second level shift signal and to generate a second high side driver control signal, anda high side switch driver referenced to the voltage of the second source, wherein the high side switch driver comprises: one or more logic inputs configured to receive the first and second high side driver control signals, anda high side switch driver output connected to the high side switch control gate and configured to transmit a high side switch control signal to the high side switch control gate, wherein the high side switch control signal is generated base on the first and second high side driver control signals,wherein the first and second level shift signals comprise a plurality of pulses, andwherein the high side switch gate control signal is generated in response to the pulses, and wherein durations of on and off times of the high side switch are based on durations of the pulses. 11. The half bridge GaN circuit of claim 10, wherein the first level shift signal is configured to cause the high side switch to turn on and wherein the second level shift signal is configured to cause the high side switch to turn off. 12. The half bridge GaN circuit of claim 10, wherein: the level shift driver further comprises: an HS STP input configured to receive a high side shoot through protection signal from the low side switch driver, wherein the level shift driver is configured to generate the first level shift input signal based in part on the high side shoot through protection signal;the low side switch driver further comprises: an LS STP input configured to receive a low side shoot through protection signal from the level shift driver, wherein the low side switch driver is configured to generate the low side switch control signal based in part on the low side shoot through protection signal; andthe high side shoot through protection signal and the low side shoot through protection signal are respectively generated by the low side switch driver and the level shift driver so as to prevent the high side switch and the low side switch from being simultaneously on. 13. The half bridge GaN circuit of claim 12, wherein the level shift driver comprises a first pulse generator configured to generate a first pulse in response to a high to low transition of the first logic signal and to transmit the first pulse to the first level shift driver output as the low side shoot through protection signal. 14. The half bridge GaN circuit of claim 13, wherein the low side switch control gate is controlled according to a logical combination of the low side shoot through protection signal, the first logic signal, and the second logic signal. 15. The half bridge GaN circuit of claim 12, wherein the low side switch driver comprises a second pulse generator configured to generate a first pulse in response to a high to low transition of the second logic signal and to transmit the first pulse to the first level shift driver as the high side shoot through protection signal. 16. The half bridge GaN circuit of claim 15, wherein the high side switch control gate is controlled according to a logical combination of the high side shoot through protection signal, the first logic signal, and the second logic signal. 17. The half bridge GaN circuit of claim 12, wherein the first level shift circuit is configured to generate a first pulse in response to a high to low transition of the first logic signal and to output the first pulse as the first level shift signal, wherein, in response to the first level shift signal, the first high side receiver is configured to reduce a turn-off propagation delay of the high side control gate. 18. The half bridge GaN circuit of claim 10, wherein the high side circuit further comprises: a first conductive element configured to pull up a voltage of the first level shift signal toward a voltage of a floating power supply;a first pull up transistor configured to pull up the voltage of the first level shift signal toward the voltage of the floating power supply;a second conductive element configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply; anda second pull up transistor configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply. 19. A half bridge GaN circuit, comprising: a low side circuit, comprising: a low side switch having a low side switch control gate and a first source,a level shift driver, comprising: a first level shift driver input connected to a first logic signal, wherein the first logic signal is referenced to the voltage of the first source, anda level shift driver output, configured to transmit a first level shift input signal,a low side switch driver, comprising: a first low side switch driver input configured to receive a second logic signal, wherein the second logic signal is referenced to a voltage at the first source, anda first low side switch driver output connected to the low side switch control gate and configured to transmit a low side switch control signal to the low side switch control gate, wherein the low side switch control signal is generated based on the second logic signal,a first level shift circuit configured to receive the first level shift input signal and to generate a first level shift signal, anda second level shift circuit configured to generate a second level shift signal; anda high side circuit, comprising: a high side switch having a high side switch control gate and a second source,a first high side receiver circuit referenced to a voltage at the second source and configured to receive the first level shift signal and to generate a first high side driver control signal,a second high side receiver circuit referenced to the voltage of the second source and configured to receive the second level shift signal and to generate a second high side driver control signal, anda high side switch driver referenced to the voltage of the second source, wherein the high side switch driver comprises: one or more logic inputs configured to receive the first and second high side driver control signals, anda high side switch driver output connected to the high side switch control gate and configured to transmit a high side switch control signal to the high side switch control gate, wherein the high side switch control signal is generated base on the first and second high side driver control signals, anda trigger circuit configured to, in response to a voltage of a first power supply referenced to the voltage of the second source being less than a threshold greater than the voltage of the second source, cause the high side switch to turn-off. 20. The half bridge GaN circuit of claim 19, wherein the first level shift signal is configured to cause the high side switch to turn on and wherein the second level shift signal is configured to cause the high side switch to turn off. 21. The half bridge GaN circuit of claim 19, wherein: the level shift driver further comprises: an HS STP input configured to receive a high side shoot through protection signal from the low side switch driver, wherein the level shift driver is configured to generate the first level shift input signal based in part on the high side shoot through protection signal;the low side switch driver further comprises: an LS STP input configured to receive a low side shoot through protection signal from the level shift driver, wherein the low side switch driver is configured to generate the low side switch control signal based in part on the low side shoot through protection signal; andthe high side shoot through protection signal and the low side shoot through protection signal are respectively generated by the low side switch driver and the level shift driver so as to prevent the high side switch and the low side switch from being simultaneously on. 22. The half bridge GaN circuit of claim 21, wherein the level shift driver comprises a first pulse generator configured to generate a pulse in response to a high to low transition of the first logic signal and to transmit the pulse to the first level shift driver output as the low side shoot through protection signal. 23. The half bridge GaN circuit of claim 22, wherein the low side switch control gate is controlled according to a logical combination of the low side shoot through protection signal, the first logic signal, and the second logic signal. 24. The half bridge GaN circuit of claim 21, wherein the low side switch driver comprises a second pulse generator configured to generate a pulse in response to a high to low transition of the second logic signal and to transmit the pulse to the first level shift driver as the high side shoot through protection signal. 25. The half bridge GaN circuit of claim 24, wherein the high side switch control gate is controlled according to a logical combination of the high side shoot through protection signal, the first logic signal, and the second logic signal. 26. The half bridge GaN circuit of claim 21, wherein the first level shift circuit is configured to generate a pulse in response to a high to low transition of the first logic signal and to output the pulse as the first level shift signal, wherein, in response to the first level shift signal, the first high side receiver is configured to reduce a turn-off propagation delay of the high side control gate. 27. The half bridge GaN circuit of claim 19, wherein the high side circuit further comprises: a first conductive element configured to pull up a voltage of the first level shift signal toward a voltage of a floating power supply;a first pull up transistor configured to pull up the voltage of the first level shift signal toward the voltage of the floating power supply;a second conductive element configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply; anda second pull up transistor configured to pull up the voltage of the second level shift signal toward the voltage of the floating power supply.
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