A static random-access memory (SRAM) circuit and associated read operation method and write operation method are provided. The SRAM circuit includes memory units arranged in M columns and N rows, M bit lines, N row-voltage selection lines, N word lines, and a control circuit. The control circuit includes a controller, a voltage source, a voltage selection module, a word-line driving module, and a bit-line driving module. The voltage source provides a first voltage and a second voltage. When the control circuit performs access to the memory unit located in the mth column and the nth row, the voltage selection module transmits one of the first voltage and the second voltage to an nth row-voltage selection line. The voltage selection module transmits the second voltage to the other (N-1) row-voltage selection lines. The variables M, N, m, and n are positive integers.

Systems and methods for processing commands at a random access memory. A series of commands are received to read data from the random access memory or to write data to the random access memory. The random access memory can process commands at a first rate when the series of commands matches a pattern, and at a second, slower, rate when the series of commands does not match the pattern. A determination is made as to whether the series of commands matches the pattern based on at least a current command and a prior command in the series of commands. A ready signal is asserted when said determining determines that the series of commands matches the pattern, where the random access memory is configured to receive and process commands faster than the second rate when the pattern is matched and the ready signal is asserted over a period of multiple commands.

Systems and methods for processing commands at a random access memory. A series of commands are received to read data from the random access memory or to write data to the random access memory. The random access memory can process commands at a first rate when the series of commands matches a pattern, and at a second, slower, rate when the series of commands does not match the pattern. A determination is made as to whether the series of commands matches the pattern based on at least a current command and a prior command in the series of commands. A ready signal is asserted when said determining determines that the series of commands matches the pattern, where the random access memory is configured to receive and process commands faster than the second rate when the pattern is matched and the ready signal is asserted over a period of multiple commands.

Conventional SRAM sense-amplifiers are replaced by small-footprint keeper circuits that enable single-ended SRAM readout without bitline precharge, simplifying and relaxing the timing of SRAM cell access and bitline sampling operations and thus enabling potentially faster readout operation and/or lower bit error rate.

Conventional SRAM sense-amplifiers are replaced by small-footprint keeper circuits that enable single-ended SRAM readout without bitline precharge, simplifying and relaxing the timing of SRAM cell access and bitline sampling operations and thus enabling potentially faster readout operation and/or lower bit error rate.

A memory device has a plurality of bit cells, each of which includes an SRAM cell having a storage node selectively connectable to a first bit line in response to a control signal received on a first word line. Each bit cell further includes an MRAM cell selectively connectable to the storage node of the SRAM cell in response to a control signal received on a second word line.

A memory device has a plurality of bit cells, each of which includes an SRAM cell having a storage node selectively connectable to a first bit line in response to a control signal received on a first word line. Each bit cell further includes an MRAM cell selectively connectable to the storage node of the SRAM cell in response to a control signal received on a second word line.

An apparatus and method for providing efficient floor planning, power, and performance tradeoffs of memory accesses. A dual read port and single write port memory bit cell uses two asymmetrical read access circuits for conveying stored data on two read bit lines. The two read bit lines are pre-charged to different voltage reference levels. The layout of the memory bit cell places the two read bit lines on an opposed edge from the single write bit line. The layout uses a dummy gate placed over both p-type diffusion and n-type diffusion between the edges. The layout has a same number of p-type transistors as n-type transistors despite using asymmetrical read access circuits. The layout also has a contacted gate pitch that is one more than the number of p-type transistors.

An apparatus and method for providing efficient floor planning, power, and performance tradeoffs of memory accesses. A dual read port and single write port memory bit cell uses two asymmetrical read access circuits for conveying stored data on two read bit lines. The two read bit lines are pre-charged to different voltage reference levels. The layout of the memory bit cell places the two read bit lines on an opposed edge from the single write bit line. The layout uses a dummy gate placed over both p-type diffusion and n-type diffusion between the edges. The layout has a same number of p-type transistors as n-type transistors despite using asymmetrical read access circuits. The layout also has a contacted gate pitch that is one more than the number of p-type transistors.

An apparatus and method for providing efficient floor planning, power, and performance tradeoffs of memory accesses. Adjacent bit cells in a column of an array use a split read port such that the bit cells do not share a read bit line while sharing a write bit line. The adjacent bit cells include asymmetrical read access circuits that convey data stored by latch circuitry of a corresponding bit cell to a corresponding read bit line. The layout of adjacent bit cells provides a number of contacted gate pitches per bit cell that is less than a sum of the maximum number of metal gates in layout of each of the adjacent bit cells divided by the number of adjacent bit cells.