Abstract: A latch-based array includes a plurality of columns and rows. Each column comprises a plurality of slave latches that all latch in parallel a master-latched data output from the column's master latch during normal operation. In a fault-testing mode of operation, one of the slaves in the column latches an inverted version of the master-latched data output while the remaining slave latches in the column latch the master-latched data output. In this fashion, the slave latches are decorrelated in a single write operation.

Abstract: A circuit including a logic gate responsive to a clock signal and to a control signal. The circuit also includes a master stage of a flip-flop. The circuit further includes a slave stage of the flip-flop responsive to the master stage. The circuit further includes an inverter responsive to the logic gate and configured to output a delayed version of the clock signal. An output of the logic gate and the delayed version of the clock signal are provided to the master stage and to the slave stage of the flip-flop. The master stage is responsive to the control signal to control the slave stage.

Abstract: A latch-based memory includes a plurality of slave latches arranged in rows and columns. Each column of slave latches receives a latched data signal from a corresponding master latch. Each row includes a clock gating circuit and a corresponding reset circuit. If a row is active for a write operation, the active row's clock gating circuit passes a write clock to the active row's slave latches. Conversely, the clock gating circuit for an inactive row gates the write clock to the inactive row's slave latches by passing a held version of the write clock in a first clock state to the inactive row's slave latches. While a reset signal is asserted, each reset circuit gates the write clock by passing the held version of the write clock in the first clock state to the slave latches in the reset circuit's row.

Abstract: A particular method includes receiving a retention signal. In response to receiving the retention signal, the method includes retaining state information in a non-volatile stage of a retention register and reducing power to a volatile stage of the retention register. The non-volatile stage may be powered by an external voltage source. The volatile stage may be powered by an internal voltage source.

Abstract: A latch-based memory includes a plurality of slave latches arranged in rows and columns. Each column of slave latches receives a latched data signal from a corresponding master latch. Each row includes a clock gating circuit and a corresponding reset circuit. If a row is active for a write operation, the active row's clock gating circuit passes a write clock to the active row's slave latches. Conversely, the clock gating circuit for an inactive row gates the write clock to the inactive row's slave latches by passing a held version of the write clock in a first clock state to the inactive row's slave latches. While a reset signal is asserted, each reset circuit gates the write clock by passing the held version of the write clock in the first clock state to the slave latches in the reset circuit's row.

Abstract: Memory power management systems and methods are provided. One embodiment of the present invention includes a memory power management system. The system comprises a first low dropout (LDO) regulator that provides an active operating voltage that is derived from a first supply voltage to power a memory array during an active mode. The system further comprises a second LDO regulator that provides a minimum memory retention voltage that is derived from a second supply voltage to power the memory array in a standby mode, wherein the second supply voltage also powers at least one peripheral circuit for reading from and/or writing to the memory array.

Abstract: Memory power management systems and methods are provided. One embodiment of the present invention includes a memory power management system. The system comprises a first low dropout (LDO) regulator that provides an active operating voltage that is derived from a first supply voltage to power a memory array during an active mode. The system further comprises a second LDO regulator that provides a minimum memory retention voltage that is derived from a second supply voltage to power the memory array in a standby mode, wherein the second supply voltage also powers at least one peripheral circuit for reading from and/or writing to the memory array.

Abstract: Memory power management systems and methods are provided. One embodiment of the present invention includes a memory power management system. The system comprises a first low dropout (LDO) regulator that provides an active operating voltage that is derived from a first supply voltage to power a memory array during an active mode. The system further comprises a second LDO regulator that provides a minimum memory retention voltage that is derived from a second supply voltage to power the memory array in a standby mode, wherein the second supply voltage also powers at least one peripheral circuit for reading from and/or writing to the memory array.

Abstract: An apparatus for providing active mode power reduction for circuits having data retention includes a master slave flip flop (MSFF) for latching a data input. An output level shifter (OLS), coupled to the MSFF, retains the data input in response to the MSFF being operable in an active power saving mode (APSM) to reduce power. The OLS operating in the APSM provides a level shifter output having a configurable voltage, thereby providing output isolation. A change in an operating mode of the MSFF between an active mode and the APSM is independent of a retention (RET) mode input.

Abstract: An apparatus for providing active mode power reduction for circuits having data retention includes a master slave flip flop (MSFF) for latching a data input. An output level shifter (OLS), coupled to the MSFF, retains the data input in response to the MSFF being operable in an active power saving mode (APSM) to reduce power. The OLS operating in the APSM provides a level shifter output having a configurable voltage, thereby providing output isolation. A change in an operating mode of the MSFF between an active mode and the APSM is independent of a retention (RET) mode input.

Abstract: A computer system including a control logic and a storage coupled to the control logic. The storage includes a plurality of bitcells and bitlines used to transfer data between the control logic and the bitcells. The control logic provides an address of a target bitcell to the storage. Within a single clock cycle, the storage uses the address to activate the target bitcell, to precharge bitlines coupled to the target bitcell, and to access the target bitcell.

Abstract: A computer system comprising a control logic and a storage coupled to the control logic. The storage comprises a plurality of bitcells and bitlines used to transfer data between the control logic and the bitcells. The control logic provides an address of a target bitcell to the storage. Within a single clock cycle, the storage uses the address to activate the target bitcell, to precharge bitlines coupled to the target bitcell, and to access the target bitcell.