Overload detection and protection for power switch circuits. For circuits with faster switching speed, fast fault detection and response to a detected overload condition may be desirable. Detection circuitry may monitor a voltage on the control terminal of one or more power switches. Based on empirical measurements, in an overload condition of a power switch circuit, e.g., a half-bridge circuit, the voltage at the control terminal may increase, and in some examples, increase to a magnitude that is greater than a supply voltage. A comparator may detect a voltage increase that exceeds a voltage magnitude threshold, output an indication to control circuitry for the power switch circuit, and the control circuitry may take action to protect the rest of the circuitry, such as reduce voltage or shut off the power switch circuit.

A semiconductor device includes a galvanic isolator; a transmitting circuit that transmits a transmission signal via the galvanic isolator; a receiving circuit that receives a received signal corresponding to the transmission signal via the galvanic isolator; an encoding circuit that encodes two input signals and generates the transmission signal; and a decoding circuit that decodes the two input signals from the received signals.

An electronic device includes a driver that is connected with a pin, receives an input signal, and outputs an output signal to the pin in response to the input signal, a core circuit that transfers the input signal to the driver, and a monitor circuit that receives the input and output signals and detects a stuck voltage state of the output signal based on the input and output signals. The monitor circuit includes a first detection circuit that detects the stuck voltage state when the input and output signals are logically incorrect, a second detection circuit that detects the stuck voltage state when the input and output signals are logically correct and when the output signal is at a low level, and a third detection circuit that detects the stuck voltage state when the input and output signals are logically correct and when the output signal is at a high level.

A power switching circuit includes a first switch circuit, a second switch circuit, a control circuit, and a driver circuit. The first switch circuit receives a first power voltage and coupled to an output terminal. The first switch circuit includes a first P-type transistor and a second P-type transistor coupled in series. The second switch circuit receives a second power voltage and coupled to the output terminal. The second switch circuit includes a third P-type transistor and a fourth P-type transistor coupled in series. The control circuit generates a control signal according to an output voltage at the output terminal, a power state signal, and one of the first power voltage and the second power voltage. The driver circuit generates a first driving signal or a second driving signal according to the control signal to control the first switch circuit or the second switch circuit.

A power switching circuit includes a first switch circuit, a second switch circuit, a control circuit, and a driver circuit. The first switch circuit receives a first power voltage and coupled to an output terminal. The first switch circuit includes a first P-type transistor and a second P-type transistor coupled in series. The second switch circuit receives a second power voltage and coupled to the output terminal. The second switch circuit includes a third P-type transistor and a fourth P-type transistor coupled in series. The control circuit generates a control signal according to an output voltage at the output terminal, a power state signal, and one of the first power voltage and the second power voltage. The driver circuit generates a first driving signal or a second driving signal according to the control signal to control the first switch circuit or the second switch circuit.

A signal transmission circuit transmitting abnormality signals from a primary side circuit to a secondary side circuit is provided, in which the primary side circuit includes switching elements driven by drive circuits, the secondary circuit including a receiving unit receiving the abnormality signals transmitted from the primary side circuit.

The signal transmission circuit includes: a plurality of isolation elements that electrically isolate the primary side circuit and the secondary side circuit, and allows the abnormality signals to be transmitted therethrough; and a logic circuit that receives the abnormality signals from the isolation elements, outputting a predetermined signal indicating an occurrence of an abnormality when at least one of the switching elements shows the abnormality.

The isolation elements transmit the abnormality signals relative to a predetermined reference voltage in the secondary side circuit and the predetermined signal outputted by the logic circuit is received by the receiving unit.

An on chip leakage-current detection device including a first inverter where the magnitude of delay of the output signal of the first inverter is determined by a leakage current of a target device. The leakage-current detection device further includes: a capacitor that is charged by the output signal of the first inverter; a second inverter coupled to capacitor that switches states when the capacitor is charged to a switching level; an odd number of additional inverters coupled in a sequence with a second-inverter output. The output of the leakage-current detection device has a frequency proportional to the leakage of the target device.

A semiconductor module including a semiconductor element which is bonded to a wiring pattern part and connects or disconnects two main electrode terminals to or from each other according to a drive signal applied to a gate electrode terminal, includes a deterioration detecting circuit configured to use one main electrode terminal of the two main electrode terminals of the semiconductor element with an applied DC voltage, as a reference potential, and detect deterioration of a joining part of the semiconductor element on the basis of a gate voltage which is the voltage between the one main electrode terminal and the gate electrode terminal and an inter-main-electrode voltage which is the voltage between the one main electrode terminal and the other main electrode terminal, and outputs an alarm signal.

A delay-time correction circuit delays an input signal for generating a pre-drive signal to a drive unit generating a drive signal. A transition-change sensor senses a transition change in one of a turn-on operation and turn-off operation. A correction-signal generator generates a correction signal in response to the transition change sensed by the transition-change sensor and to the input signal. A delay output unit generates an output signal corresponding to the pre-drive signal by delaying the input signal using the correction signal. The delay output unit delays the output signal that instructs the other of a turn-on operation and turn-off operation, from the input signal, in accordance with a length of a period for the transition change in the one of a turn-on operation and turn-off operation that is performed immediately before the other of a turn-on operation and turn-off operation.

A delay-time correction circuit delays an input signal for generating a pre-drive signal to a drive unit generating a drive signal. A transition-change sensor senses a transition change in one of a turn-on operation and turn-off operation. A correction-signal generator generates a correction signal in response to the transition change sensed by the transition-change sensor and to the input signal. A delay output unit generates an output signal corresponding to the pre-drive signal by delaying the input signal using the correction signal. The delay output unit delays the output signal that instructs the other of a turn-on operation and turn-off operation, from the input signal, in accordance with a length of a period for the transition change in the one of a turn-on operation and turn-off operation that is performed immediately before the other of a turn-on operation and turn-off operation.