Subthreshold Standard Cell Library

What is claimed is: 1 . A standard cell logic library for synthesizing an application specific integrated circuit (ASIC) using a TSMC 0.25 μm process, said library comprising: a plurality of logic gates for synthesizing application specific integrated component circuits, each of said logic gates having a rise and fall delay, and a propagation delay and operating in the subthreshold voltage region; said logic gates components each including different combinations and quantities of n-type and p-type metal oxide semiconductor field effect transistors (nMOS and pMOS) and further having a constant channel length and a nMOS to pMOS ratio R, said ratio R being chosen so that the rise and fall delay and the propagation delay of each said logic gate of said ASIC is substantially equal; an operating V dd component including positive supply voltages in the subthreshold voltage region for the respective integrated circuits said ASIC; a synthesis library input component including timing, temperature and physical characteristics of the respective integrated circuits for said ASIC; and a physical library component including symbol, schematic and mask layouts for the respective circuits said ASIC. 2 . The logic library of claim 1 wherein the subthreshold region includes a subthreshold voltage characterized by approximately 10-20% of nominal bias voltage. 3 . The logic library of claim 2 wherein the logic gates include one or more of the group of inverter, tri-state inverter, 3 input NAND, 2 input NAND, 2 input AND, 2 input NOR, 2 input OR, buffer, D latch, and a D flip flop logic gates. 4 . A method for manufacturing an application specific integrated circuit (ASIC) for operation in the subthreshold region, said method comprising the steps of: A) establishing a plurality of standard logic gates, each said logic gate having an assigned logic function and a plurality of n-type Metal Oxide Semiconductor (nMOS) and p-type Metal Oxide Semiconductor (pMOS) transistors, each said nMOS transistor having an channel width W n and a channel length L n , each pMOS transistor having a channel width W p , and a channel length L p ; B) for each said standard logic gate in said step A), determining a ratio R of W n /W p that will minimize the average power consumption, while at the same time maintaining channel length L n and said channel length L p constant and equal to each other; and, C) synthesizing said ASIC using said standard logic gates from said step B). 5 . The method of claim 4 , wherein each said nMOS transistor and each said pMOS transistor from said step B) has a rise delay, a fall delay, a propagation delay rise and a propagation delay fall, and wherein said R is chosen so that said rise delay is substantial to said fall delay, and so that said propagation delay rise is substantially equal to said propagation delay fall.