Supply and substrate noise tolerance using dynamic tracking clusters in configurable memory designs

This work develops a hidden clustered source line control (HCSLC) technique to reduce the standby current of an embedded SRAM with zero area overhead. The HCSLC scheme utilizes meshed multiple source line control to reduce the fluctuations of virtual ground voltages that are caused by IR drops and process variations. A clustered device-hidden layout scheme is employed to produce compact SRAM layout and attenuate the effects of location/direction-dependent process variations on source line control circuits. A 512Kb HCSLC SRAM testchip was fabricated using the 0.18um CMOS process. The HCSLC SRAM achieves 69%~77% reductions of standby current for various processes, supply voltages and temperatures (PVT). The data retention voltage in sleep mode is 0.1V~0.15V higher than that in normal mode for the HCSLC SRAM.

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Supply and substrate noise tolerance using dynamic tracking clusters in configurable memory designs

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Cited by 12 publications

References 21 publications

Code-pattern insensitive embedded ROMs using dynamic bitline shielding technique

Code-pattern insensitive embedded ROMs using dynamic bitline shielding technique

A low supply noise content-sensitive ROM architecture for SOC

Experiments on reducing standby current for compilable SRAM using hidden clustered source line control

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