The amplitude voltage of a signal input to a level shifter can be increased and then output by the level shifter circuit. Specifically, the amplitude voltage of the signal input to the level shifter can be increased to be output. This decreases the amplitude voltage of a circuit (a shift register circuit, a decoder circuit, or the like) which outputs the signal input to the level shifter. Consequently, power consumption of the circuit can be reduced. Alternatively, a voltage applied to a transistor included in the circuit can be reduced. This can suppress degradation of the transistor or damage to the transistor.

Voltage level shifter (VLS) circuits employing a pre-conditioning circuit for pre-conditioning an input signal to be voltage level shifted in response to a pre-charge phase are disclosed. A VLS circuit is configured to voltage level shift an input signal in a lower voltage domain on an output node in a higher voltage domain. The VLS circuit includes a pre-charge circuit configured to pre-charge the output node in a pre-charge phase. The VLS circuit also includes a pull-up circuit and a pull-down circuit that are configured to pull-up and pull-down the pre-charge phase of the output node, respectively, in an evaluation phase based on a logic state of the input signal to generate the output signal. To mitigate or avoid contention between the pull-up and pull-down circuits in the evaluation phase, the input signal is pre-conditioned such that the pull-down circuit is deactivated in response to the pre-charge phase.

A CMOS output circuit includes a first P-MOSFET having a source connected to a power supply terminal, a drain connected to an output terminal, and a back gate connected to a first potential terminal; a first N-MOSEFET having a drain connected to the output terminal, a source connected to the ground terminal, and a back gate connected to a second potential terminal; a first potential switching portion arranged to switch whether to connect the first potential terminal to the power supply terminal or to the output terminal; a second potential switching portion arranged to switch whether to connect the second potential terminal to the ground terminal or to the output terminal; a first gate switching portion arranged to switch whether or not to short-circuit the gate of the first P-MOSFET to the first potential terminal; a second gate switching portion arranged to switch whether or not to short-circuit the gate of the first N-MOSFET to the second potential terminal; a first driver arranged to drive the gate of the first P-MOSFET in accordance with a first input signal; a second driver arranged to drive the gate of the first N-MOSFET in accordance with a second input signal; and a control portion arranged to control individual portions of the circuit when turning off both the first P-MOSFET and the first N-MOSFET, so as to connect the first potential terminal to one of the power supply terminal and the output terminal, which has a higher potential, to connect the second potential terminal to one of the ground terminal and the output terminal, which has a lower potential, to short-circuit the gate of the first P-MOSFET to the first potential terminal, and to short-circuit the gate of the first N-MOSFET to the second potential terminal.

Level shifters, memory systems, and level shifting methods are described. According to one arrangement, a level shifter includes an input configured to receive an input signal in a first voltage domain, an output configured to output an output signal from the level shifter in a second voltage domain different than the first voltage domain, a plurality of pull-down devices, and wherein one of the pull-down devices is coupled with the input and the output, a plurality of cross-coupled devices coupled with the pull-down devices and configured to provide transitions in the output signal as a result of transitions in the input signal, a plurality of current limiting devices coupled with the cross-coupled devices and configured to limit a flow of current from a source to the cross-coupled devices, and a plurality of dynamic devices configured to selectively provide charging current from the source to the cross-coupled devices.

An operation speed of a voltage conversion circuit is improved without increasing an output level of the voltage conversion circuit. The voltage conversion circuit is provided with a high-voltage side transistor and a gate control unit. In this voltage conversion circuit, the high-voltage side transistor outputs a predetermined high voltage higher than a predetermined reference voltage. Also, in the voltage conversion circuit, the gate control unit generates a predetermined control voltage higher than a predetermined high voltage from an input signal and applies the same between a gate and a source of the high-voltage side transistor, thereby allowing the high-voltage side transistor to output a predetermined high voltage.

The amplitude voltage of a signal input to a level shifter can be increased and then output by the level shifter circuit. Specifically, the amplitude voltage of the signal input to the level shifter can be increased to be output. This decreases the amplitude voltage of a circuit (a shift register circuit, a decoder circuit, or the like) which outputs the signal input to the level shifter. Consequently, power consumption of the circuit can be reduced. Alternatively, a voltage applied to a transistor included in the circuit can be reduced. This can suppress degradation of the transistor or damage to the transistor.

A semiconductor device may include a first pad configured to provide a first voltage. The semiconductor device may include a second pad. The semiconductor device may include a connection circuit configured to couple the first pad to the second pad on the basis of a connection signal or electrically separate the second pad from the first pad on the basis of the connection signal. The semiconductor device may include a detection circuit configured to generate a defect detection signal on the basis of a test mode signal and a second voltage received from the second pad.

The present invention relates to a novel and inventive compound device structure, enabling a charge-based approach that takes advantage of sub-threshold operation, for designing analog CMOS circuits. In particular, the present invention relates to a solid state device based on a complementary pair of n-type and p-type current field-effect transistors, each of which has two control ports, namely a low impedance port and gate control port, while a conventional solid state device has one control port, namely gate control port. This novel solid state device provides various improvement over the conventional devices.

One aspect disclosed features an apparatus comprising: an input buffer configured to receive an input voltage pulse as an input, and to output, responsive to a leading edge of the input voltage pulse, a logic high voltage pulse at a first output of the input buffer and a logic low voltage pulse at a second output of the input buffer; an array of L active pull-up devices electrically coupled between a positive supply rail and an output node, each active pull-up device driven by the logic high voltage pulse as modulated by a corresponding bit of a series of N first L-bit binary words; and an array of L active pull-down devices electrically coupled between a negative supply rail and the output node, each active pull-down device driven by the logic low voltage pulse as modulated by a corresponding bit of a series of M second L-bit binary words.

Level shifters, memory systems, and level shifting methods are described. According to one arrangement, a level shifter includes an input configured to receive an input signal in a first voltage domain, an output configured to output an output signal from the level shifter in a second voltage domain different than the first voltage domain, a plurality of pull-down devices, and wherein one of the pull-down devices is coupled with the input and the output, a plurality of cross-coupled devices coupled with the pull-down devices and configured to provide transitions in the output signal as a result of transitions in the input signal, a plurality of current limiting devices coupled with the cross-coupled devices and configured to limit a flow of current from a source to the cross-coupled devices, and a plurality of dynamic devices configured to selectively provide charging current from the source to the cross-coupled devices.