A memory device is provided. The memory device includes a cell array having memory cells; n word lines sequentially arranged and including a first word line, an n-th word line, and word lines interposed between the first word line and the n-th word line; bit lines; a first power node located adjacent to the first word line; a second power node located adjacent to the n-th word line; a first switch connected between the first power node and the cell array; a write driver located adjacent to the n-th word line and connected to the bit lines; and a switch controller configured to control the first switch to isolate the first power node from the memory cells during a write operation on memory cells connected to the first word line.

A memory device is provided. The memory device includes a cell array having memory cells; n word lines sequentially arranged and including a first word line, an n-th word line, and word lines interposed between the first word line and the n-th word line; bit lines; a first power node located adjacent to the first word line; a second power node located adjacent to the n-th word line; a first switch connected between the first power node and the cell array; a write driver located adjacent to the n-th word line and connected to the bit lines; and a switch controller configured to control the first switch to isolate the first power node from the memory cells during a write operation on memory cells connected to the first word line.

A circuit includes a plurality of registers, each register including SRAM cells, a read port configured to receive a read address, a write port configured to receive a write address, a selection circuit, a latch circuit, and a decoder coupled in series between the read and write ports and the plurality of registers, and a control circuit. Responsive to a clock signal and read and write enable signals, the control circuit causes the selection circuit, the latch circuit, and the decoder to select a first register of the plurality of registers in a read operation based on the read address, and select a second register of the plurality of registers in a write operation based on the write address.

A circuit includes a plurality of registers, each register including SRAM cells, a read port configured to receive a read address, a write port configured to receive a write address, a selection circuit, a latch circuit, and a decoder coupled in series between the read and write ports and the plurality of registers, and a control circuit. Responsive to a clock signal and read and write enable signals, the control circuit causes the selection circuit, the latch circuit, and the decoder to select a first register of the plurality of registers in a read operation based on the read address, and select a second register of the plurality of registers in a write operation based on the write address.

Described herein are stacked memory devices that include some peripheral devices for controlling the memory in a separate layer from one or more memory arrays. The layers of the memory device are connected together using vias, which transfer power and data between the layers. In some examples, a portion of the peripheral devices are included in a memory layer, and another portion are included in a peripheral device layer. Multiple layers of memory arrays and/or peripheral devices may be included, e.g., one peripheral device layer may control multiple layers of memory arrays, or different layers of memory arrays may have dedicated peripheral device layers. Different types of memory arrays, such as DRAM or SRAM, may be included.

Described herein are stacked memory devices that include some peripheral devices for controlling the memory in a separate layer from one or more memory arrays. The layers of the memory device are connected together using vias, which transfer power and data between the layers. In some examples, a portion of the peripheral devices are included in a memory layer, and another portion are included in a peripheral device layer. Multiple layers of memory arrays and/or peripheral devices may be included, e.g., one peripheral device layer may control multiple layers of memory arrays, or different layers of memory arrays may have dedicated peripheral device layers. Different types of memory arrays, such as DRAM or SRAM, may be included.

A memory device includes a first memory array, a first isolation cell abutting a first side of the first memory array, a first edge cell array abutting a second side, opposite to the first side, of the first memory array, a second memory array arranged at a first side, opposite to the first memory array, of the first isolation cell, a second edge cell array, and multiple first word lines passing through the first edge cell array, the first memory array and being terminated at the first isolation cell. A first width of the first isolation cell is different from a second width of the first edge cell array. The second memory array is sandwiched between the second edge cell array and the first isolation cell.

A memory device includes a first memory array, a first isolation cell abutting a first side of the first memory array, a first edge cell array abutting a second side, opposite to the first side, of the first memory array, a second memory array arranged at a first side, opposite to the first memory array, of the first isolation cell, a second edge cell array, and multiple first word lines passing through the first edge cell array, the first memory array and being terminated at the first isolation cell. A first width of the first isolation cell is different from a second width of the first edge cell array. The second memory array is sandwiched between the second edge cell array and the first isolation cell.

A pseudo dual port memory device in which an operating speed is improved and stability is increased is provided. The pseudo dual port memory device may include a memory cell, a pair of bit lines connected to the memory cell, a write driver, a sense amp, and a column multiplexer which is connected to the bit lines, receives a write multiplexer control signal and a read multiplexer control signal, connects the bit lines to the write driver in response to the write multiplexer control signal, and connects the bit lines to the sense amp in response to the read multiplexer control signal. A precharge control signal generation circuit which is connected to the column multiplexer may generate a precharge control signal on the basis of the read and write multiplexer control signals, and a bit line precharge circuit may precharge the bit lines based on the precharge control signal.

A hardware memory includes at least one memory cell, peripheral circuitry and randomization circuitry. The memory cell(s) store data, which may be written to, read from and held in the hardware memory. The peripheral circuitry reads and writes data to the memory cell(s) and may perform other functions necessary for facilitating the data read, write and hold. The randomization circuitry randomizes operations performed by the peripheral circuitry to reduce a correlation between the data and the current consumed by the hardware memory.