A reset switch power supply on-off control circuit and system, used for reset switches. The reset switch power supply on-off control circuit includes a reset switch control circuit connected with a reset switch and is configured to collect a status of the reset switch and output a status signal and a first control signal; an MOS switch circuit connected with the reset switch control circuit and configured to receive the first control signal from the reset switch control circuit; and a main control chip connected with the reset switch control circuit and is configured to acquire the status signal from the reset switch control circuit and output a second control signal to the reset switch control circuit.

In one embodiment, a switching circuit includes a first switch coupled to a first switch terminal, the first switch comprising at least one gallium nitride high-electron mobility transistor (GaN HEMT); a second switch coupled in series with the first switch and a second switch terminal, the second switching comprising a GaN HEMT; and at least one power source configured to provide power to the first switch and the second switch; wherein the second switch is configured to drive the first switch ON and OFF.

In one embodiment, a switching circuit includes a first switch comprising one or more transistors operably coupled in series with a first terminal, wherein each of the one or more transistors has a corresponding diode, a drain of each of the one or more transistors being operably coupled to a cathode of the corresponding diode; and a second switch comprising one or more transistors operably coupled in series with a second terminal, wherein each of the one or more transistors has a corresponding diode, a drain of each of the one or more transistors being operably coupled to a cathode of the corresponding diode; wherein a source of the one or more transistors of the first switch is operably coupled to a source of the one or more transistors of the second switch.

Various systems may benefit from interfaces for handling multiple types of inputs. For example, a device with a trigger input from an external device may benefit from an isolated logic level trigger that is capable of addressing multiple types and values of voltage. An apparatus can include an input configured to receive an external trigger input signal having a trigger input voltage. The apparatus can also include circuitry configured to automatically adjust the trigger input voltage to a value configured to be compatible with a provided attached system. A working range of the trigger input voltage can exceed a compatible working range of the provided attached system.

The invention discloses a standby control circuit and a display device. The standby control circuit includes a standby module, at least one power board, and a transistor switch control module comprising at least one transistor switch whose number is equal to that of the at least one power board, each transistor switch is connected between one power board and a mains supply input terminal, the standby module is configured to generate a trigger signal and send the generated trigger signal to each transistor switch, and each transistor switch is configured to be turned on upon receipt of the trigger signal sent from the standby module so as to connect the power board connected thereto with the mains supply input terminal.

A power controller includes an input power terminal, an output power terminal, a power switching circuit connected between the input power terminal and the output power terminal, a detection circuit connected to the power switching circuit, one or more data interfaces, and a control device connected to the detection circuit and the one or more data interfaces. The detection circuit measures a load current and a current squared time (I.sup.2t) value between the input power terminal and the output power terminal. The control device automatically turns the power switching circuit OFF whenever the load current exceeds a first value or the current squared time value exceeds a second value or an OFF signal is received from the one or more data interfaces, and automatically turns the power switching circuit ON whenever an ON signal is received from the one or more data interfaces.

The present invention discloses an energy-saving electronic touch switch, comprising a touch sensing module, a power supply module and a switch driving module, wherein the touch sensing module is used for receiving a touch sensing signal inputted by a capacitive touch switch, and controlling the action of the switch driving module according to the touch sensing signal, so as to switch on a power supply circuit for the load; and the power supply module feeds power to the touch sensing module. The touch switch can drive various loads and has a wider range of possible loads including inductive, capacitive or purely resistive loads and high-frequency switch power supply loads, such as energy-saving lights, AC (Alternating Current) motors, LEDs (Light Emitting Diodes) new light sources, common fluorescent lamps, and the like. The energy-saving electronic touch switch overcomes the disadvantages of small load range and weak load capacity of conventional switches. The energy-saving electronic touch switch employs chips with low power consumption such as LDO (Low Dropout Regulator) voltage regulator chips, touch chips, and the like, which can reduce the overall power consumption, wherein the overall power consumption is less than 2.2 mW and the single static overall power consumption is less than 10 mW (measured under an indicator lamp). The energy-saving electronic touch switch simplifies circuits and improves the power supply utilization rate.

Disclosed is a large-range input circuit for digital signals in the range of extra-low voltage signals of 120 V and in the range of low voltage signals of <1500 V, said input circuit comprising series-connected Zener diodes that are polarized in the reverse direction, each one defining at least one switching threshold in the range of the extra-low voltage signals or in the range of the low voltage signals, and can be selected to be active by not being bridged, wherein a respective auxiliary optocoupler, which can be controlled by a microprocessor, is used to bridge the inactive Zener diode.

In one embodiment, a switching circuit includes a first switch comprising one or more transistors operably coupled in series with a first terminal, wherein each of the one or more transistors has a corresponding diode, a drain of each of the one or more transistors being operably coupled to a cathode of the corresponding diode; and a second switch comprising one or more transistors operably coupled in series with a second terminal, wherein each of the one or more transistors has a corresponding diode, a drain of each of the one or more transistors being operably coupled to a cathode of the corresponding diode; wherein a source of the one or more transistors of the first switch is operably coupled to a source of the one or more transistors of the second switch.

Various systems may benefit from interfaces for handling multiple types of inputs. For example, a device with a trigger input from an external device may benefit from an isolated logic level trigger that is capable of addressing multiple types and values of voltage. An apparatus can include an input configured to receive an external trigger input signal having a trigger input voltage. The apparatus can also include circuitry configured to automatically adjust the trigger input voltage to a value configured to be compatible with a provided attached system. A working range of the trigger input voltage can exceed a compatible working range of the provided attached system.