A circuit for providing back-up power includes a switching circuit configured to be coupled to a first power source and a second power source. The circuit includes a domain voltage level monitor circuit coupled with the first power source and the second power source and with output of the switching circuit. The circuit includes a dynamic level shifter circuit coupled with the first power source and the second power source and an output of the domain voltage level monitor. The circuit includes a double controlled latch circuit coupled with the first power source and the second power source and an output of the dynamic level shifter circuit. The double controlled latch circuit is configured to provide control signals to the switching circuit.

A data receiving circuit is provided. The data receiving circuit includes a data input circuit, a latch circuit, and a current source. The data input circuit is configured to receive an input signal. The latch circuit is configured to output an output signal in response to the input signal. The current source is configured to provide a current to the latch circuit. The current source is different from the data input circuit.

A frequency divider circuit and a frequency synthesizer circuit are presented, comprising:

first and second flip-flops;

a phase inverter, wherein an output electrode of the first flip-flop is connected to an input electrode of the second flip-flop and an output electrode of the phase inverter, an output electrode of the second flip-flop is connected to an input electrode of the phase inverter and an input electrode of the first flip-flop, a control electrode of the phase inverter is connected to a control signal; and

a control module, wherein the first flip-flop is connected to a voltage source through the control module, the control module is connected to the control signal and controls the connection between the first flip-flop and the voltage source. When the control signal is a first-mode signal, the first flip-flop is disconnected from the voltage source, providing a functionality of a N-division frequency divider. When both the control signal and an output signal of the second flip-flop are a second-mode signal, a functionality of a N+1-division frequency divider is provided.

A device includes a first driver circuit coupled to a first bus line, where the first driver circuit includes a first delay element. The first delay element is configured to receive a first input signal and generate a first output signal. The first output signal transitions logic levels after a first delay period when the first input signal transitions from a logic high level to a logic low level. The first output signal transitions logic levels after a second delay period when the first input signal transitions from the logic low level to the logic high level. The first delay element includes a sense amplifier. The first driver circuit is configured to transmit the first output signal over the first bus line. The device also includes a second driver circuit configured to transmit a second output signal over a second bus line.

An output driving circuit includes a pull-down driver and a voltage stabilizer. The pull-down driver includes first, second, and third transistors connected in series between a pad and a ground node. The voltage stabilizer generates a stabilization voltage based on a voltage of the pad and a power voltage, and outputs the stabilization voltage to a control terminal of the second transistor.

A level shifting circuit operates at a high voltage level without stressing the transistors. The circuit has the ability to swing between large supply domains. Multiple output voltage levels are supported for the level shifted signal. Additionally, output nodes are stably driven to supply voltage levels that do not vary with respect to process corner and temperature.

An input/output (I/O) circuit may be provided. The I/O circuit may include an input control circuit and an output control circuit. The input control circuit may be configured to apply a stress to a transmission path based on an input signal while in a test mode and buffer the input signal using a drivability changed by the stress applied to the transmission path to generate first and second transmission signals while in a normal mode after the test mode. The output control circuit may be configured to drive and output an output signal according to the first and second transmission signals based on a test mode signal.

A level shifter includes an input circuit configured to generate and output first and second intermediate signals based on an input signal that transitions between a first voltage level and a second voltage level. The level shifter includes a feed forward circuit configured to receive the first intermediate signal from the input circuit and generate and output a third intermediate signal enabled in a part of a period in which the first intermediate signal is enabled and to receive the second intermediate signal from the input circuit and generate and output a fourth intermediate signal enabled in a part of a period in which the second intermediate signal is enabled. Moreover, the level shifter includes a level shifting circuit configured to receive the first through fourth intermediate signals and to shift the input signal to an output signal that transitions between a third voltage level and the second voltage level.

Disclosed herein are silicon-on-insulator (SOI) switches and associated control circuits having level shifters configured to provide increased voltages (positive and/or negative) to the switches. The disclosed level shifters can be configured to provide increased voltages and can be used with high-linearity switches and/or can improve the linearity of switches. The improved switch performance can improve front end module performance for applications such as carrier aggregation (CA) and multiple input multiple output (MIMO) as well as with protocols such as Long-Term Evolution Advanced (or LTE-A).

An apparatus comprising a first voltage domain circuit including a first circuit component configured to provide a first digital output signal; a second voltage domain circuit comprising a second circuit component; a level shifter arrangement configured to receive the first digital output signal and generate a second digital output signal based thereon with an increased voltage level of the high state, and provide said second digital output signal to the second circuit component; wherein the level shifter arrangement comprises at least one stage, the at least one stage comprising an arrangement of one or more diode-connected PMOS transistors, coupled to a CMOS inverter arrangement; the CMOS inverter arrangement of a first of the at least one stages configured to receive the first digital output signal and the CMOS inverter arrangement of a final stage of the at least one stages configured to output said second digital output signal.