A memory device includes a level down shifting driver circuit. The level down shifting driver circuit include input circuitry having at least one input port, and a cross-junction circuitry electrically coupled to the input circuitry and configured to receive a first signal from the input circuitry to drive one or more devices included in the cross-junction circuitry. The level down shifting driver circuit further includes an output drive circuitry electrically coupled to the cross-junction circuitry and configured to receive a second signal from the cross-junction circuitry, wherein the output drive circuitry comprises an output line configured to deliver a first voltage output based on a first input voltage received by the input circuitry, and a second voltage output based on a second input voltage received by the input circuitry.

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.

Systems and methods are provided for a level shifter. A level shifter includes a network of transistors configured to receive a signal at a first node in a first voltage domain and to generate a corresponding signal at a second node in a second voltage domain during a transition period of time. A self timing circuit is configured to receive an initiation signal based on the signal at the first node and to generate a voltage transition accelerator signal that is used to pull up the second node prior to the expiration of the transition period of time.

The present invention discloses a voltage level conversion circuit. A first and a second N-type driving transistors turn on when a first power voltage source supplies a high state voltage. A voltage transmission circuit transmits a first and a second input voltages having opposite levels to sources of the first and the second N-type driving transistors. A current source operates according to a second supply voltage source and has a first and a second output terminals. A first and a second connection transistors respectively couple between the drain of the first N-type driving transistor and the second output terminal and between the drain of the second N-type driving transistor and the first output terminal. The first and the second connection transistors turn on and off when the first voltage supply source supplies the high state voltage and a low state voltage.

A level shifter including an input block that receives an input voltage swinging between a first ground voltage and a first power supply voltage and that connects one node of a first node and a second node to a first ground node, in response to the input voltage, a shifting block that mutually exchanges the voltage levels of third and fourth nodes in response to a current flowing through the one node, a pulse generator that generates a first pulse and a second pulse in response to the input voltage, a first transistor that directly connects the third node to the first ground node in response to the first pulse, and a second transistor that directly connects the fourth node to the first ground node in response to the second pulse.

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.

A multi-voltage, high voltage I/O buffer in low-voltage technology is disclosed. In one embodiment, the I/O buffer includes a logic circuit configured to generate a signal based on a data signal and a first control signal. A level shifter is coupled between a supply voltage terminal and a ground terminal, and the level shifter is generates first and second output signals in first and second voltage domains, respectively, at first and second nodes, respectively, based on the signal from the logic circuit. A control circuit is coupled between the second node and a third node. The control circuit transmits the second output signal to the third node when the first control signal is asserted, and the control circuit couples the third node to the ground terminal when the first control signal is not asserted.

A level shifter circuitry is provided. The level shifter circuitry includes a first sub-circuit connected to a first power supply voltage, a second sub-circuit connected to a second power supply voltage and a shifting circuit which is connected to the first and second sub-circuits and outputs the first power supply voltage or the second power supply voltage to an output terminal or an inverted output terminal in response to a signal applied to an input node in accordance with an enable signal.

A level shifter may include: a discharge circuit configured to receive an input signal on the basis of a first power supply voltage, and discharge an internal node on the basis of the input signal; a charge supply circuit configured to supply charge to an output node from which an output signal is outputted, on the basis of a second power supply voltage; and a voltage adjustment circuit including a first MOS transistor coupled between the internal node and the output node, and configured to adjust the voltage of the output node on the basis of a bias voltage applied to the first MOS transistor, and stop the operation of adjusting the voltage of the output node on the basis of the bias voltage, when the levels of the first and second power supply voltages are equal to each other.

A level shifter includes a compact bias generator. The compact bias generator generates a first bias signal and a second bias signal, in the absence of a buffer. The level shifter also includes a first latch in a first stage to translate a first voltage to a second voltage based on the first bias signal. The level shifter further includes a second latch in a second stage to translate the first voltage to a third voltage based on the second bias signal. The first bias signal is independent of the second bias signal.