Abstract: A digital voltage boost circuit, optionally working in parallel with an analog voltage regulator, periodically injects a constant amount of current each cycle into the bit line of a high density memory array to eliminate the bias voltage reduction which would otherwise occur. This results in a much faster recovery time and reduces the semiconductor real estate required. A pulse generator in the boost circuit generates one or more current modulation signals which control corresponding current supply devices in a current source. The boost circuit drives a constant amount of current to the bias voltage node each memory cycle.

Abstract: A novel and useful direct memory based ring oscillator (DMRO) circuit and related method for on-chip evaluation of SRAM delay and stability. The DMRO circuit uses an un-modified SRAM cell in each delay stage of the oscillator. A small amount of external circuitry is added to allow the ring to oscillate and detect read instability errors. An external frequency counter is the only equipment that is required, as there is no need to obtain an exact delay measurement and use a precise waveform generator. The DMRO circuit monitors the delay and stability of an SRAM cell within its real on-chip operating neighborhood. The advantage provided by the circuit is derived from the fact that measuring the frequency of a ring oscillator is easier than measuring the phase difference of signals or generating signals with precise phase, and delivering such signals to/from the chip. In addition, the DMRO enables monitoring of read stability failures.

Abstract: novel and useful SRAM restore tracking circuit adapted to improve the tracking of SRAM cell behavior for different PVT corners. The SRAM array access path is mainly influenced by two stages: (1) the wordline (WL) delay and (2) the SRAM cell delay. These two stages are usually the most sensitive for process variation in the memory access path. The restore tracking circuit incorporates two novel topologies for enhanced tracking to SRAM cell behavior. The first topology is a circuit that functions to mimic the wordline load and delay characteristics. The WL stage is very sensitive to process variation due to the large load it must drive and the usually relatively poor slope (i.e. depending on the number of cells the WL). The second topology is a circuit that mimics the SRAM cell load and delay characteristics. The SRAM cell is very sensitive to process variation due to its very small device features and the high number of cells in the memory array.

Abstract: Systems and methods for determining optimal memory device precharge voltages are provided herein. In addition, systems and methods for providing localized sense amplification and circuit assist circuitry are described herein. Embodiments provide for determining precharge multipliers that may be used to determine the optimal precharge voltage based on a precharge source voltage. According to embodiments, the precharge source voltage may be Vdd or Vcs. Optimizing the precharge voltage maximizes memory device performance and functional characteristics, including, but not limited to, stability, efficiency, power, writability, and reliability.

Abstract: A digital voltage boost circuit, optionally working in parallel with an analog voltage regulator, periodically injects a constant amount of current each cycle into the bit line of a high density memory array to eliminate the bias voltage reduction which would otherwise occur. This results in a much faster recovery time and reduces the semiconductor real estate required. A pulse generator in the boost circuit generates one or more current modulation signals which control corresponding current supply devices in a current source. The boost circuit drives a constant amount of current to the bias voltage node each memory cycle.

Abstract: A method of increasing a drain to source voltage measured at an access pass-gate to a SRAM circuit in a SRAM memory array, including increasing a low voltage from a low voltage source powering said SRAM circuit, and increasing a high voltage from a high voltage source powering the SRAM circuit.

Abstract: Systems and methods for determining optimal memory device precharge voltages are provided herein. In addition, systems and methods for providing localized sense amplification and circuit assist circuitry are described herein. Embodiments provide for determining precharge multipliers that may be used to determine the optimal precharge voltage based on a precharge source voltage. According to embodiments, the precharge source voltage may be Vdd or Vcs. Optimizing the precharge voltage maximizes memory device performance and functional characteristics, including, but not limited to, stability, efficiency, power, writability, and reliability.

Abstract: A method of increasing a drain to source voltage measured at an access pass-gate to a SRAM circuit in a SRAM memory array, including increasing a low voltage from a low voltage source powering said SRAM circuit, and increasing a high voltage from a high voltage source powering the SRAM circuit.