A voltage level shifter device an input stage and an output stage. The input stage is configured to lower one of the first and second output terminals to the low level according to the level of the input voltage. A latch circuit includes a first branch having a first PMOS transistor and a second PMOS transistor coupled in series coupled between a shifted-high-level voltage supply terminal and the first output terminal and a second branch having a third PMOS transistor an a fourth PMOS transistor coupled in series between the shifted-high-level voltage supply terminal and the second output terminal. The first output terminal is a gate of the second PMOS transistor and to a gate of the third PMOS transistor. The second output terminal is coupled a gate of the fourth PMOS transistor and to a gate of the first PMOS transistor.

A circuit includes a level shifter circuit, an output circuit, an enable circuit, a first and a second feedback circuit. The level shifter circuit is coupled to a first voltage supply, and is configured to generate at least a first and a second signal responsive to at least the first enable signal or the first input signal. The output circuit is coupled to at least the level shifter circuit and the first voltage supply, and configured to receive the first and the second signal. The enable circuit is configured to generate a second enable signal responsive to the first enable signal. The first feedback circuit is configured to receive the first enable signal, the second enable signal and the first feedback signal. The second feedback circuit is configured to receive the first enable signal, the second enable signal and the second feedback signal.

To provide a miniaturized data holding circuit. First and second MOS transistors respectively transmit a data signal and an inverted data signal to inputs of first and second inverting gates that constitute a state holding circuit when a clock signal is at a first level. Fifth and sixth MOS transistors are respectively inserted in a feedback path from an output of the second inverting gate to the input of the first inverting gate and a feedback path from an output of the first inverting gate to the input of the second inverting gate, and respectively transmit the outputs of the second and first inverting gates when the clock signal is at a second signal level. Seventh and eighth MOS transistors are constituted in a channel of a conductive type different from the first MOS transistor and connected in parallel to the fifth and sixth MOS transistors, respectively, and transmit the output of the second inverting gate and the output of the first inverting gate on the basis of the inverted data signal and the data signal, respectively.

A level shifting circuit includes negative voltage shifting circuitry including a first leg and a second leg. The first leg includes a first plurality of NMOS transistors in series with a first input node and a negative amplified voltage, and the second leg includes a second plurality of NMOS transistors in series with a second input node and the negative amplified voltage. The level shifting circuit further includes positive voltage shifting circuitry including a first plurality of high voltage transistors in series with a positive amplified voltage and an output node of the level shifting circuit, and a second plurality of high voltage transistors in series with a first intermediate node of the first leg of the negative voltage shifting circuitry and the output node of the level shifting circuit. The level shifting circuitry further includes input circuitry including a plurality of inverters.

A level shifter includes an input circuit having first and second input terminals configured to receive complementary input signals at a first voltage level and a second voltage level. A cross-latch circuit is coupled to the input circuit, and has first and second output terminals configured to provide complementary output signals at a third voltage level and a fourth voltage level. The input circuit includes first and second control nodes configured to output first and second control signals at the first voltage level and the fourth voltage level based on the input signals. A tracking circuit is coupled to the input circuit and the cross-latch circuit, and is configured to input first and second tracking signals to the cross-latch circuit based on the first and second control signals, wherein the first tracking signal is the greater of the first control signal and the third voltage level, and the second tracking signal is the greater of the second control signal and the third voltage level.

The present document relates to a level shifter circuit configured to transform an input voltage at an input of the level shifter circuit into an output voltage at an output of the level shifter circuit. The level shifter circuit may comprise a first switching element coupled between an output supply voltage and a positive output terminal, wherein a control terminal of the first switching element is coupled to a negative output terminal. The level shifter circuit may comprise a second switching element coupled between the output supply voltage and the negative output terminal, wherein a control terminal of the second switching element is coupled to the positive output terminal. The level shifter circuit may comprise a drive circuit configured to drive the control terminals of the first and the second switching element based on the input voltage at the input of the level shifter circuit.

One or more examples relate to voltage level shifting. An example apparatus may include first and second inputs, an output, and a circuit. The first and second inputs may receive compliments of a signal represented by first voltage levels. The output may provide the signal represented by second voltage levels. The circuit may change voltage levels utilized to represent the signal from first voltage levels to second voltage levels. The circuit may include cross-coupled first high voltage switches, a pair of series coupled switches, and a pair of voltage clamping switches. The cross-coupled first high voltage switches may selectively couple the output to a high voltage node responsive to a high voltage level of the signal. The pair of series coupled switches may comprising respective second high voltage switches, and the pair of series coupled switches may selectively couple the output to a first voltage supply. The pair of voltage clamping switches may increase OFF-resistance of the respective second high voltage switches of the pair of series coupled switches responsive to a low voltage level at the respective input.

Examples described herein generally relate to integrated circuits that include a latch-based level shifter circuit with self-biasing. In an example, an integrated circuit includes first and second latches and an output stage circuit. Each of the first and second latches includes a bias circuit electrically connected to a respective latch node and configured to provide a bias voltage at the respective latch node, which is electrically coupled to a signal input node. The output stage circuit has first and second input nodes electrically connected to first and second output nodes of the first and second latches, respectively, and a third output node. The output stage circuit is configured to responsively pull up and pull down a voltage of the third output node in response to respective voltages of the first and second input nodes.

A level shifter includes a self-initialization circuit. The self-initialization circuit judges whether the input signal and the inverted input signal received by the level shifter are invalid while a power supply voltage is powered up. If the self-initialization circuit confirms that the input signal and the inverted input signal received by the level shifter are invalid, the self-initialization circuit controls the level shifter to be maintained in a self-initializing power up state. Consequently, the output signal from the level shifter has the specified voltage level.

A semiconductor device includes an I/O circuit configured to be supplied with a first voltage, a second voltage higher than the first voltage, and a third voltage higher than the second voltage, and to receive an input signal based on the first voltage. The I/O circuit includes an enabler circuit configured to be supplied with the second voltage, and to generate a first signal based on the second voltage, and a first level shifter circuit coupled to the enabler circuit, and configured to, based on the first signal, level-shift a signal based on the second voltage to a signal based on the third voltage.