Stability Parameters of Register File Bit Cell with Low Power Consumption Priority
DOI:
https://doi.org/10.18372/1990-5548.77.17963Keywords:
memory bit cell, memory compiler, butterfly curve, register file, power consumption, static noise marginAbstract
This research is dedicated to a transistor sizing method of an 8-transistor register file static random access memory bit cell aiming to create two-port register files and two-port static random access memory with reduced supply voltage to reduce power consumption. This method can also be applied to 6-transistor single-port static random access memory bit cells. The method is based on the analysis of butterfly curves and the search for such values of the sizes of transistors and margin of their threshold voltages, in which, for a given critical minimal supply voltage, the condition for the existence of one intersection and one touch of its curves is achieved for the butterfly curves. The obtained samples of the register files bit cell in silicon and its critical voltage were compared to the results of circuit simulation in the write and read mode depending on the supply voltage. Experimental register files chip samples were successfully tested in silicon at a voltage of 0.75 V.
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