Apparatus, methods and systems to produce a protection voltage are disclosed. The apparatus includes circuitry to deliver a first supply voltage to a plurality of circuits, where the first supply voltage has a first magnitude, circuitry to deliver a second supply voltage to a part of the plurality of circuits, where the second supply voltage has a second magnitude, and circuitry to deliver a protection voltage to the part of the plurality of circuits when the second supply voltage is LOW and the first supply voltage is HIGH. The protection voltage has a magnitude that is a fraction of the magnitude of the first supply voltage. The apparatus includes circuitry that causes the delivery of the second supply voltage to the part of the plurality of circuits when the second supply voltage is turned HIGH subsequent to the second supply voltage being LOW when the first supply voltage is HIGH.

A semiconductor circuit is provided having a crossbar switch arrangement, which includes at least one multiplexer, an output of which corresponds to an output of the crossbar switch arrangement. The arrangement also includes: a set of input lines connected to data inputs of the multiplexer, the input lines extending along a first direction of the semiconductor circuit; and a set of select lines connected to select inputs of the multiplexer, the select lines extending along a second direction of the semiconductor circuit, where the second direction differs from the first direction. The multiplexer includes at least one multiplexing circuit for generating a multiplexed signal from signals present at the input lines and at least one primary output driver for generating an output signal from the multiplexed signal.

A wireless transceiver includes a receive path having a first switch and configured to receive an input signal when the first switch is in an open position, a first transmit path having a second switch and configured to provide a first output signal when the second switch is in a closed position and the first switch is in a closed position, and a second transmit path having a third switch and configured to provide a second output signal when the third switch is in a closed position, the first switch is in the closed position, and the second switch is in an open position. The first, second, and third switches are integrated together with the receive path, the first RF transmit path, and the second transmit path within a same integrated circuit.

A non-contact switch control system includes: a switch set, configured to receive a sensing signal from a sensed target, the switch set including a first non-contact switch and a second non-contact switch, the sensing signal including a first sensing signal and a second sensing signal; a storage unit, configured to store a control program; and a processing unit, connected to the switch set and the storage unit and configured to execute the control program and control the switch set based on the sensing signal. The control program includes: determining whether the first non-contact switch receives the first sensing signal and obtaining a first determination result; in the situation where the first determination result indicates Yes, determining whether the second non-contact switch receives the second sensing signal and obtaining a second determination result; and in the situation where the second determination result indicates Yes, disabling the second non-contact switch.

A selection circuit includes at least three control terminals; wherein: a first group of the at least three control terminals is configured to provide a first signal for controlling a first function; and a second group of the at least three control terminals is also configured to provide a second signal for controlling the first function.

An RF signal switch circuit that allows connection of any of N radio frequency (RF) input terminals to a switch output port, either in a low loss mode, in a bypass mode, or, optionally, in a signal function mode. Embodiments of the invention allow for both a single switch in the series input path to a target circuit while still having the ability to isolate the bypass path from the target circuit. In the low loss and bypass mode, the circuit simultaneously exhibits low input insertion loss (and thus a low noise factor) and high bypass mode isolation.

A delay circuit includes an electronic transmission element with a first input and a first output. The first input is coupled to the first output by two first switches wired in parallel. The first switches each have a control input, a second input and a second output. The second input is coupled to the second output by two second switches wired in parallel. The circuit further includes an input circuit to receive an input signal and feed the input signal to one of the transmission element inputs and feed the inverted input signal to the other of the transmission element inputs, and an output circuit. The output circuit is configured such that the output signal only changes in the case of a change in the input signal if the change in the input signal has brought about a change both at the first output and at the second output.

Provided are an electronic circuit and electronic timepiece that can initialize internal circuits even if chattering occurs when a battery is installed. In the electronic circuit, when the initialization state hold signal is input, the initialization control circuit continues outputting the initialization control signal at the first level until the clock signal is output; and when the initialization state hold signal is input and the clock signal is output, outputs the initialization control signal at the second level cancelling the initialization process to the initialization circuit.

A voltage detection circuit includes two detection capacitors, which are paired and configured differentially, first to third detection switches, a drive part, a minimum selector and a maximum selector. The first detection switch is formed of a pMOS transistor, which opens and closes a path between one of the detection capacitors and an input node. The second detection switch is formed of an nMOS transistor, which opens and closes a path between the other of the detection capacitors and an input node. The third detection switch is formed of a series circuit of a pMOS transistor and an nMOS transistor, which open and close a path between two detection capacitors. The driving part turns on and off complementarily between the first and second switches and the third detection switch. The minimum selector applies a lower one of voltages of the input nodes as a substrate potential of the nMOS transistor. The maximum selector applies a higher one of the voltages of the input nodes as a substrate potential of the pMOS transistor.

A die-to-die repeater circuit includes a transmit circuit coupled to a die-to-die interconnect, the transmit circuit including at least one flip flop to function as a part of a linear feedback shift register (LFSR) to transmit a value across the die-to-die interconnect for design for test (DFT) to check proper operation of the die-to-die interconnect, and a receive circuit coupled to the die-to-die interconnect, the receive circuit including at least one flip flop to function as part of a multiple input shift register (MISR).