The present application is directed to a level shifting circuit. In one form, a level shifting circuit includes a first inverter, a level shifting unit, and a fast driving unit. The first inverter is configured to invert an input signal received at an input node and to output an inverted input signal to a second input node. The level shifting unit is configured to perform amplitude up-shifting processing on a received input signal. The fast driving unit is configured to pull up an output signal of an output node of the level shifting unit by increasing a discharge current of the level shifting unit when receiving the input 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.

Circuits integrating OR logic and level shifting functionality and methods of operating the same are configured to accommodate different applications. One such circuit comprises first and second transistors coupled in parallel defining first and second nodes, the first transistor being responsive to a first input signal and the second transistor being responsive to a second input signal; a first resistor coupled between a power supply terminal of the circuit and the first node; and a second resistor coupled between the second node and a ground terminal of the circuit. The circuit generates an output signal having a voltage level that is lower than a voltage level of each of the first and second input signals.

According to one embodiment, 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.

Disclosed are level shifters and methods of performing level shifting. In one embodiment, a level shifter is disclosed comprising an input, cross-coupled/latch circuitry, a first reference node, a second reference node, and output circuitry coupled between the cross-coupled/latch circuitry and an output, wherein the output circuitry sets the output signal to high based on rising edge of a second reference node and sets the output signal to low based on the rising edge of the first reference node. Further, in some implementations, the first reference node and the second reference node may have signals that are inverse to each other.

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.

Methods and systems are provided for generating an oscillating signal for use as a clock in digital logic timing. The oscillating signal is generated via a differential RC relaxation oscillator including an oscillator core and biasing circuitry. The oscillator core may be configured such that the oscillating signal it generates is substantially sinusoidal or pseudo-sinusoidal and contains less harmonic content relative to a square wave signal. The biasing circuitry may be configured to have a reduced dependence on temperature so that the biasing values it provides vary less with temperature.

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

Embodiments disclosed herein relate to level shifters of a memory device. Specifically, the level shifters include a first series arrangement of transistors to offset a first transistor. The level shifters also include a second series arrangement of transistors to offset a second transistor. The first series arrangement of transistors is opposite the second series arrangement of transistors. The output of the first series arrangement of transistors is coupled to a first node and selectively couples the first node to a first voltage based on an input signal. The output of the second series arrangement of transistors is coupled to a second node and couples the second node to the first voltage based on an input signal. The first node and the second node are coupled to the first voltage at different times. The series arrangements of transistors enables faster level shifting over conventional level shifters.

An image sensor includes a shifting circuit shifting a first voltage that is applied to a first node, to a second voltage, and shifting the second voltage that is applied to a second node, to the first voltage, and a sub-circuit providing the first voltage to the shifting circuit. The image sensor further includes a source circuit enabling the sub-circuit to provide the first voltage to the shifting circuit, and an enable transistor that is gated by an enable signal, and enables the shifting circuit by providing the second voltage to the shifting circuit, based on the enable signal.