A semiconductor device and a method of generating a power on reset signal that can reliably perform power on reset on an internal circuit and subsequently cancel the reset state regardless of environmental temperature are provided. The semiconductor device according to the disclosure includes: a voltage divider circuit dividing a power supply voltage to obtain first and second voltages having different voltage values; a first transistor receiving the first voltage at the control electrode to generate a first current; a second transistor receiving the second voltage at the control electrode to generate a second current; a current comparing part comparing the first and second currents to generate a current comparison result signal representing a comparison result; and a reset signal generating part generating a power on reset signal having a first level that prompts reset or a second level that prompts reset cancelation based on the current comparison result signal.

A power-on reset signal generator and an associated electronic device are provided. The power-on reset signal generator includes a detection circuit and a comparator. The detection circuit detects the power-supply voltage to generate detection signals, and includes a plurality of sets of transistors, a first resistor and a second resistor, and at least one third resistor. Each set of transistors within the plurality of sets of transistors includes a first transistor and a second transistor respectively positioned on a first current path and a second current path within the detecting circuit. The first resistor and the second resistor are respectively positioned on the first current path and the second current path. The first current path and the second current path pass through the third resistor. The comparator receives the set of detection signals from the detection circuit, and compares the set of detection signals to generate a power-on reset signal.

A control device for connecting between two portions of an electrical power supply line. The device includes a bipolar transistor including a wide bandgap semiconductor material and having its emitter connected to one portion of the power supply line, its collector connected to another portion of the power supply line, and the device also including control connected to the base of the transistor.

A semiconductor device and a method of generating a power on reset signal that can reliably perform power on reset on an internal circuit and subsequently cancel the reset state regardless of environmental temperature are provided. The semiconductor device according to the disclosure includes: a voltage divider circuit dividing a power supply voltage to obtain first and second voltages having different voltage values; a first transistor receiving the first voltage at the control electrode to generate a first current; a second transistor receiving the second voltage at the control electrode to generate a second current; a current comparing part comparing the first and second currents to generate a current comparison result signal representing a comparison result; and a reset signal generating part generating a power on reset signal having a first level that prompts reset or a second level that prompts reset cancelation based on the current comparison result signal.

Power-on reset circuits and methods for providing a power-on reset signal are provided. A first branch is configured to receive the power supply voltage. The first branch comprises a first current generator configured to generate a first current having a positive relationship with a power supply voltage. A second branch receives the power supply voltage and comprises a second current generator that is configured to generate a second current. A relationship between the first and second currents indicates whether the power supply voltage exceeds a threshold voltage of the power-on reset circuit. A current comparator circuit compares the first current to the second current and generates an output based on the comparison. The power-on reset signal is asserted when the output indicates that the second current is greater than the first current.

In accordance with an embodiment, a circuit includes a first and a second switching transistors configured to be coupled in series between a first reference voltage terminal and a transformer. The circuit also includes a first diode coupled between a first drain of the first switching transistor and a first input terminal. The first diode is configured to clamp a voltage of the first drain to a voltage of the first input terminal. The circuit further includes a switching circuit coupled between the second switching transistor and the first input terminal. The switching circuit is configured to connect a second source of the second switching transistor to a second gate of the second switching transistor when a voltage of the second source exceeds the voltage of the first input terminal.

In accordance with an embodiment, a circuit includes a first and a second switching transistors configured to be coupled in series between a first reference voltage terminal and a transformer. The circuit also includes a first diode coupled between a first drain of the first switching transistor and a first input terminal. The first diode is configured to clamp a voltage of the first drain to a voltage of the first input terminal. The circuit further includes a switching circuit coupled between the second switching transistor and the first input terminal. The switching circuit is configured to connect a second source of the second switching transistor to a second gate of the second switching transistor when a voltage of the second source exceeds the voltage of the first input terminal.

Certain aspects of the present disclosure provide techniques for power management of a wireless powered appliance. A wireless powered appliance includes a wireless power receiver configured to generate electric power from a magnetic field emitted from a wireless power transmitter. The electric power comprises a supply voltage. The wireless powered appliance further includes power level detection circuit comprising circuit components configured to generate one or more output signals. The one or more output signals correspond to the supply voltage exceeding one or more thresholds. The wireless powered appliance further includes a power transition stabilizer circuit configured to receive the one or more output signals and the supply voltage. The power transition stabilizer circuit includes one or more electrical loads configured to electrically couple to the supply voltage based on the one or more output signals such that the supply voltage is reduced by the one or more electrical loads.