Abstract: A decoder circuit to decode an address for accessing a memory cell in a memory array includes address latch circuitry, inverter circuitry, and first address pre-decode circuitry. The address latch circuitry receives an address signal and generates address holding signals during a setup period. The address latch circuitry latches the address holding signals during an address hold period following the setup period. The inverter circuitry receives the address signal and generates a complementary address signal. The first address pre-decode circuitry decodes the address signal and the address holding signals during the setup period to generate a first pre-decode address signal at an output of the first address pre-decode circuitry. In addition, the first address pre-decode circuitry decodes the address holding signals during the address hold period to maintain the first pre-decode address signal at the output of the first address pre-decode circuitry.

Abstract: A memory includes a self-timed column imitating a bitline loading, a self-timed row imitating a self-timed word-line, a self-timed bitcell performing a dummy write in a write cycle, a writer driver coupled to the self-timed bitcell for an actual write, and an edge detection circuit coupled to the self-timed bitcell for tracking a write cycle time.

Abstract: In embodiments of the invention, a memory circuit includes a static random access memory (SRAM), rows of M sense amplifiers, a global read precharge tracking control circuit controlling a precharge of global read lines, a sense amplifier output tracking circuit generating a reset sense amplifier signal for the sense amplifier control circuits, and a read delay circuit generating a trigger signal for the global read precharge tracking control circuit and the sense amplifier output tracking circuit and performing a fixed delay tracking of a read operation in a read cycle. A dummy global read line is coupled to the global read precharge tracking control circuit and returns from a half way to the top of the SRAM forming a tracking dummy global read line that determines a completion of the precharge of the global read lines before the sense amplifiers start discharging the global read lines in the read cycle.

Abstract: In described embodiments, a circuit for providing a margin free PVT tolerant fast self-timed sense amplifier reset includes a sense amplifier coupled between a complementary pair of first and second bitlines in a memory cell, a first and second PMOS drivers connected to internal nodes of the sense amplifier, respectively, and outputting a first and second output signals, wherein the second output signal is inverted by an inverter to form an inverted output signal, a read detect block receiving the first and inverted output signals and generating a transition detect signal that is latched by a cross-coupled inverters and employed to generate a sense amplifier enable signal with a global sense amplifier enable signal, and a push-pull logic formed by a NMOS and a PMOS in series to generate an output of the circuit.

Abstract: A write-tracking circuit for a writable memory array has one or more dummy memory cells and is configured to write different values to the one or more dummy memory cells. Durations of pulses applied to word lines of the memory array during write operations are controlled based on durations of writing the different values to the one or more dummy memory cells. In at least some embodiments, the write-tracking circuit is configured to write the different values to the one or more dummy memory cells during a single write operation. In at least some embodiments, the write-tracking circuit is configured to write the different values to at least one of the one or more dummy memory cells during different write operations.

Abstract: A write-tracking circuit for a writable memory array has one or more dummy memory cells and is configured to write different values to the one or more dummy memory cells. Durations of pulses applied to word lines of the memory array during write operations are controlled based on durations of writing the different values to the one or more dummy memory cells. In at least some embodiments, the write-tracking circuit is configured to write the different values to the one or more dummy memory cells during a single write operation. In at least some embodiments, the write-tracking circuit is configured to write the different values to at least one of the one or more dummy memory cells during different write operations.

Abstract: In described embodiments, a memory circuit includes a static random access memory (SRAM) including N banks of memory cells, rows of M sense amplifiers, a controlled feedback latch storing a previous state of input data in a read cycle, a pull down select block coupled to the controlled feedback latch and the dummy sense amplifier, a dummy output latch coupled to the pull-down select block to store the read data, and a SRAM reset generation circuit coupled to the sense amplifier control circuits and the controlled feedback latch. The dummy output latch is a latch that is the same as a sense amplifier latch used in the local input/output circuit, thereby, no margin is involved between a reset of the sense amplifiers and the read data latched at the dummy output latch in the read cycle.

Abstract: In described embodiments, a memory circuit includes a static random access memory (SRAM) including N banks of memory cells, rows of M sense amplifiers, a controlled feedback latch storing a previous state of input data in a read cycle, a pull down select block coupled to the controlled feedback latch and the dummy sense amplifier, a dummy output latch coupled to the pull-down select block to store the read data, and a SRAM reset generation circuit coupled to the sense amplifier control circuits and the controlled feedback latch. The dummy output latch is a latch that is the same as a sense amplifier latch used in the local input/output circuit, thereby, no margin is involved between a reset of the sense amplifiers and the read data latched at the dummy output latch in the read cycle.

Abstract: In described embodiments, a circuit for providing a margin free PVT tolerant fast self-timed sense amplifier reset includes a sense amplifier coupled between a complementary pair of first and second bitlines in a memory cell, a first and second PMOS drivers connected to internal nodes of the sense amplifier, respectively, and outputting a first and second output signals, wherein the second output signal is inverted by an inverter to form an inverted output signal, a read detect block receiving the first and inverted output signals and generating a transition detect signal that is latched by a cross-coupled inverters and employed to generate a sense amplifier enable signal with a global sense amplifier enable signal, and a push-pull logic formed by a NMOS and a PMOS in series to generate an output of the circuit.

Abstract: In embodiments of the invention, a memory circuit includes a static random access memory (SRAM), rows of M sense amplifiers, a global read precharge tracking control circuit controlling a precharge of global read lines, a sense amplifier output tracking circuit generating a reset sense amplifier signal for the sense amplifier control circuits, and a read delay circuit generating a trigger signal for the global read precharge tracking control circuit and the sense amplifier output tracking circuit and performing a fixed delay tracking of a read operation in a read cycle. A dummy global read line is coupled to the global read precharge tracking control circuit and returns from a half way to the top of the SRAM forming a tracking dummy global read line that determines a completion of the precharge of the global read lines before the sense amplifiers start discharging the global read lines in the read cycle.

Abstract: A memory device comprises a memory array and associated control circuitry. The control circuitry comprises a clock generator configured to generate a clock signal for controlling timing of at least one of a read operation and a write operation directed to the memory array. The clock generator comprises a plurality of sets of address change detection circuits. The sets are configured to generate respective output signals as a function of respective subsets of address bits of an address signal identifying an address in the memory array. The clock generator further comprises logic circuitry coupled to the sets of address change detection circuits and configured to receive the respective output signals therefrom and to generate the clock signal as a function of said output signals.

Abstract: A memory includes a self-timed column imitating a bitline loading, a self-timed row imitating a self-timed word-line, a self-timed bitcell performing a dummy write in a write cycle, a writer driver coupled to the self-timed bitcell for an actual write, and an edge detection circuit coupled to the self-timed bitcell for tracking a write cycle time.

Abstract: A memory device includes a memory array comprising a plurality of memory cells, and control circuitry coupled to the memory array. The control circuitry comprises at least one dummy memory cell, a feedback-based controller having inputs coupled to respective internal nodes of the dummy memory cell, and write signal generation circuitry coupled to the feedback-based controller and configured to provide one or more write signals for controlling writing of data to portions of the memory array. The feedback-based controller generates a reset signal for application to a reset input of the write signal generation circuitry at least in part as a function of a logic level transition delay of a selected one of the first and second internal nodes of the dummy memory cell.