A detection circuit includes a first transistor coupled to a gate of a high power transistor, a second transistor whose source is coupled to a drain of the first transistor, a first voltage divider coupled to a source of the first transistor, and a second voltage divider coupled to the source of the second transistor. The first transistor is configured to generate a first transistor output voltage representative of a gate voltage of the high power transistor shifted based on a first gate-to-source voltage of the first transistor. The second transistor is configured to generate a second gate-to-source voltage substantially equal to the first gate-to-source voltage. The first divider is configured to divide the first transistor output voltage by a first factor. The second divider is configured to divide the second gate-to-source voltage by a second factor correlated with the first factor.

A fully integrated GaN driver comprising a digital logic signal inverter, a level shifter circuit, a UVLO circuit, an output buffer stage, and (optionally) a FET to be driven, all integrated in a single package. The level shifter circuit converts a ground reference 0-5 V digital signal at the input to a 0-10 V digital signal at the output. The output drive circuitry includes a high side GaN FET that is inverted compared to the low side GaN FET. The inverted high side GaN FET allows switch operation, rather than a source follower topology, thus providing a digital voltage to control the main FET being driven by the circuit.

VCONN pull-down circuits and related methods are disclosed for USB Type-C connections. A device is connected through a USB Type-C connection to a separate device using connections including a CC (configuration channel) pin and a VCONN (connection power) pin. The device pulls down the VCONN pin to ground through a resistance (Ra) by applying the voltage on the CC pin to close a switch coupled between the VCONN pin and ground. The device can also be operated in a dead-battery mode where no supply voltage is present for the device. The device can also stop the pull-down on the VCONN pin after a connection is established, for example, using additional switches coupled to a pull-down control signal to remove the CC voltage and open the switch. The voltage on the CC pin can also be clamped to a desired voltage or voltage range using a voltage clamp.

The present disclosure provides a start-up initialization circuit of motor drive system, including a power amplitude detecting and internal power supply module, a controlled delay module, a waveform shaping module and a power supply judging and adjusting module integrated on a same substrate, configured to detect and manage a voltage change of each node of a drive system in real time to cause a motor drive system to realize a start-up initialization process transit from an off state to a normal working state. The present disclosure finally forms the start-up initialization circuit of motor drive system by integrating the power amplitude detecting and internal power supply module, the controlled delay module, the waveform shaping module and the power supply judging and adjusting module and integrating on a single chip, which greatly ensures the reliability of power on and start-up of the motor drive system.

A voltage regulator circuit may generate a regulated voltage level using a voltage level of a feedback node. The regulated voltage level may be distributed, via a power distribution network, to package power supply node of a package, into which an integrated circuit has been mounted. Power switches included in the integrated circuit may couple the package power supply node to respective local power supply nodes in the integrated circuit. A particular power switch may selectively couple different ones of the local power supply nodes to the feedback node, allowing the voltage regulator circuit to compensate for reductions in the regulated voltage level due to the power distribution network, as well as adjust the regulated voltage level based on power consumptions of load circuits coupled to the local power supply nodes.

Disclosed is a high voltage power system with enable control, comprising a high voltage start-up circuit, a PWM control module, and a driving module; the high voltage start-up circuit comprises a first transistor, a third transistor, a fourth transistor, a resistor, a diode, a VDD detection unit and an I/O interface unit; the high voltage start-up circuit is controlled by an input of a pin EN; when the pin EN is set, the high voltage start-up circuit stops working; the power system is shut off and doesn't restart, and enters a zero standby state; when the pin EN is reset, the high voltage start-up circuit restores to work, and the power system restarts and enters a normal working state. The power system having the high voltage start-up circuit with enable control has characteristics that the standby input power consumption and standby input current are both close to zero.

An integrated circuit with a power-on-reset circuit includes an inverter circuit connected between the first and second supply node, a cascode-connected series of transistors MCn, for n going from 1 to N, connected between the first supply node and the input node of the inverter, and a resistive element connected between the input node of the inverter and the second supply node. The transistors in the cascode-connected series of transistors MCn pull up the input node voltage above a trip point voltage when the voltage between the input node and the first supply node is more than a threshold of the cascode-connected series. A circuit connected between the first and second supply nodes is responsive to a POR pulse output by the inverter.

An electrical circuit for ensuring safe ramp-up and ramp-down of at least a regulated operating voltage, a reference voltage, and a reset signal for a consumer is described. The electrical circuit includes a voltage reference circuit and a voltage regulator. The voltage regulator is provided in order to furnish a regulated operating voltage, the voltage reference circuit is provided in order to be supplied with the regulated operating voltage furnished by the voltage regulator, and the voltage regulator is provided in order to obtain a reference voltage from the voltage reference circuit.

Voltage monitoring circuit having an analog reset signal generator to generate a reset signal and coupled to a voltage to be monitored; first register to store a first state bit and coupled to the voltage to be monitored; second register connected in parallel to the first register, redundant to the first register, to store a second state bit, and coupled to the voltage to be monitored; logic coupled to the first and second registers and to determine a state control signal from the first and second state bits, and a second reset signal; and OR logic to receive the following signals on the input side and process them with one another according to an OR operation: a first reset signal generated by the analog reset signal generator and the second reset signal, so that a reset control signal is generated and fed to reset inputs of the registers.

Various implementations described herein are directed to a circuit. The circuit may include a memory circuit having a first latch. The circuit may include a power-on-reset circuit having a second latch coupled to the first latch. The second latch may be configured to reset the first latch to a predetermined state at power-up.