Apparatus and methods are disclosed for providing a bias, comprising a bias generator circuit including a high voltage (HV) circuit configured to generate a regulated high voltage (HV) from an HV line and provide the regulated HV at an HV regulated line and a low voltage (LV) circuit configured to generate a low voltage (LV) differential from the HV line and to provide the LV differential at an LV line.

A semiconductor device includes a first pad, a comparison circuit, and a control circuit. A first voltage may be applicable to the first pad. The comparison circuit may include a first input terminal connected to the first pad, a second input terminal to which a second voltage is applicable, and an output terminal configured to output a comparison result between the first voltage and the second voltage. The control circuit may be configured to output, external to the semiconductor device, a signal based on the comparison result.

Operating a memory unit using a low-power DC source. The low-power DC source provides lesser power than that required to operate the memory unit. In an embodiment, charge from the low-power source is stored on a charge storage device in a first time interval. The memory unit is operated using the charge storage device as a second power source in a second time interval. A portion of one of the first time interval and the second time interval does not overlap with the other one of the first time interval and the second time interval.

A semiconductor device includes a first transistor; a first resistor; a second resistor; a first circuit configured to apply a first voltage to the first transistor. The first voltage is based on a difference between a reference voltage and an output voltage divided by the first and second resistors. A first current through the first circuit in a first mode is less than a second current through the first circuit in a second mode. The semiconductor device includes a capacitor connected to the output terminal; and a second circuit connected to the capacitor that: (a) disconnects the first circuit from the capacitor and apply a second voltage to the capacitor in a first mode, and (b) electrically connects the first circuit to the capacitor in the second mode.

A circuit includes a linear regulator coupled with a memory array and a pump regulator coupled with a charge pump, the charge pump to provide a supply voltage to the linear regulator. A digital-to-analog converter (DAC) has an output coupled with the pump regulator. Control logic is coupled with the DAC and is to perform operations including causing a digital input value to be provided to the DAC to selectively adjust the supply voltage based on a programmable offset value.

A voltage generation circuit includes a noise attenuation circuit configured to attenuate a noise of a second power voltage which has a level that is at least two times higher than that of a first power voltage, and a multi-stage voltage pump configured to receive a noise-attenuated second power voltage from the noise attenuation circuit and generate at least one of plural target voltages, each target voltage having a different level. The first and second power voltages are individually input from an external device via different pins or pads.

An electronic device and a semiconductor package structure are provided. The electronic device includes a plurality of semiconductor dies stacked vertically over each other and a power supply system. The plurality of semiconductor dies are stacked over the power supply system, and the power supply system includes: a voltage generating circuit configured to generate at least one voltage; and a die enabling circuit configured to generate a die enable signal according to the at least one voltage. The at least one voltage is provided to the plurality of semiconductor dies through a power interconnecting structure, and the die enable signal is configured to enable synchronous input of the at least one voltage to the plurality of semiconductor dies.

A memory device may include a phase driver circuit that may output a first voltage for refreshing a plurality of memory cells. The memory device may also include a plurality of word line driver circuits that may receive the first voltage via the phase driver circuit, such that each word line driver circuit of the plurality of word line driver circuits may provide the first voltage to a respective word line associated with a respective portion of the plurality of memory cells. In addition, each word line driver circuit may refresh the respective portion of the plurality of memory cells based on a respective word line enable signal provided to a first switch of the respective word line driver circuit.

Methods and apparatuses having an improved write assist scheme are presented. An apparatus includes a power supply node configured to provide power from a power supply to one memory cell to store data; a bitline configured to provide write data to the one memory cell in a write operation; and a discharge circuit configured to selectively discharge the power supply node to the bitline, based on the write data. A method to write into a memory cell with a write assist scheme includes providing power from a power supply to one memory cell via a power supply node, to store data; providing write data to the one memory cell via a bitline in a write operation; and discharging, selectively based on the write data, the power supply node to the bitline.

Provided a voltage generating circuits including assist circuits and operating methods thereof. The voltage generating circuit which includes an assist circuit that generates an assist signal indicating an enable mode or a disable mode. When a first power supply voltage is lower than an assist reference voltage, the assist signal indicates the enable mode, and a compensation circuit generates a compensation signal based on the first power supply voltage. An internal voltage converter generates a regulated voltage based on the first power supply voltage, and a charge pump circuit generates a pump voltage based on the regulated voltage. The compensation signal compensates for the regulated voltage.