A memory device including memory cells and edge cells is described. In one example, the memory device includes: an array of memory cells used for data storage; a plurality of first edge cells not used for data storage; and a plurality of second edge cells not used for data storage. The plurality of first edge cells and the plurality of second edge cells are arranged respectively at two opposite sides of the array of memory cells. At least one edge cell, among the plurality of first edge cells and the plurality of second edge cells, comprises a circuit configured for controlling the array of memory cells to enter or exit a power down mode.

A memory module may include: a battery; a plurality of devices including a first memory, a second memory, and a controller; and a power management integrated circuit configured to adjust a level of a battery power, received from the battery, and configured to supply a power supply voltage to each of the plurality of devices.

Methods, systems, and devices for sequential voltage control for a memory device are described. A memory device may have various voltage sources that support different voltage levels used in various operations of the memory device. Voltage sources of a memory device may be disabled under some circumstances, such as when the memory device is idled, or operated in a low-power or powered-down mode, among other circumstances. In accordance with examples as disclosed herein, voltage sources of a memory device or memory die may be sequentially enabled or sequentially disabled. For example, voltage sources may be enabled in an order from voltage sources having relatively higher nominal voltages to voltage sources having relatively lower voltages, or disabled in an order from voltage sources having relatively lower nominal voltages to voltage sources having relatively higher voltages.

A device includes a master latch, a slave latch and a retention latch coupled to each other. The retention latch includes first and second active areas, first and second gate structures. The first and second active areas extend in a first direction. The first gate structure extends in a second direction, the first gate structure including first and second portions that are separated from each other. The first portion is arranged over the first active area, and the second portion is arranged over the second active area. The second gate structure extends in the second direction, and is arranged over the first active area. The second gate structure is separated from the second active area and the first gate structure in a layout view. An end portion of the second active area is between the first gate structure and the second gate structure.

Circuits and methods are described herein for controlling a bit line precharge circuit. For example, a control circuit includes a first latch circuit and a second latch circuit. The first latch circuit is configured to receive a first light sleep signal. The first latch circuit generates a second light sleep signal according to a clock signal. The second latch circuit is configured to receive the second light sleep signal. The second latch circuit generates a third light sleep signal according to a sense amplifier enable signal. The second latch circuit provides the third light sleep signal to a bit line reading switch, so the bit line reading switch is cutoff after a sense amplifier is enabled.

An electronic device includes a flag generation circuit and a delay circuit. The flag generation circuit is configured to generate a flag signal, wherein a level of the flag signal changes based on a first internal command. The delay circuit is configured to generate a delay signal by delaying one of an operation signal and the flag signal by a predetermined period according to whether a predetermined operation is performed.

A power management circuit that has multiple sets of circuits to provide certain same power management functionalities in different power modes, such as voltage, current and temperature sensing and/or measuring, generating of reference states or biases to effectuate circuit protection in various conditions, such as under voltages, over voltages, etc. One set of circuits is configured to operate during a normal mode and is optimized for performance, speed and/or accuracy. Another set of circuits is configured to operate during a sleep mode and is optimized for reduced power consumption where the performance, speed and/or accuracy may be inferior to the circuits for the normal mode but the functionality is maintained within the low power consumption constraint.

A system for dual mode operation having power saving and active modes in a stacked circuit topology having logic preservation is provided. The system includes a pre-charge circuit and a sleep mode control circuit for providing a signal to disable a plurality of circuit elements and switching a mode of the system, the sleep mode control circuit being coupled to the pre-charge circuit and further being coupled to a logic function circuit, wherein the plurality of circuit elements comprise logic gates and transistor devices. The system also includes a keeper circuit coupled to the global bitline, and the logic function circuit coupled to a solar bitline, wherein the logic function circuit preserves a state of the solar bitline, the state of the global bitline determines the state of the solar bitline. The system includes an effective pull-up transistor coupled to the sleep mode control circuit and the logic function circuit.

A semiconductor memory device includes a plurality of static random access memory (SRAM) cells connected to a bit line pair comprising a first bit line and a second bit line. An equalizer circuit controls a connection between the first bit line and the second bit line. A timing control circuit controls the equalizer circuit such that the equalizer circuit disconnects the first bit line from the second bit line during a first mode and connects the first bit line to the second bit line during a second mode. The first mode permits data to be read from or written to the SRAM cells, and the second mode is a retention mode during which data is not read from or written to SRAM cells.

Methods, systems, and devices for architecture-based power management for a memory device are described. Aspects include operating a first memory bank within a memory device in a first mode and a second memory bank within the memory device in a second mode. The memory device may receive a power down command for the first memory bank while operating the first memory bank in the first mode and the second memory bank in the second mode and switch the first memory bank from the first mode to a first low power mode while maintaining the second memory bank in the second mode. The first low power mode corresponds to less power consumption by the first memory bank than the first mode. In some cases, switching the first memory bank from the first mode to the first low power mode includes deactivating circuitry dedicated to the first memory bank.