Open AccessError Immune Logic for Low-Power Probabilistic Computing
Author(s) -
Bo Marr,
Jason George,
Brian Degnan,
David V. Anderson,
P. Hasler
Publication year - 2010
Publication title -
vlsi design
Language(s) - English
Resource type - Journals
eISSN - 1065-514X
pISSN - 1026-7123
DOI - 10.1155/2010/460312
Subject(s) - probabilistic logic , adder , datapath , computer science , algorithm , energy (signal processing) , spice , power (physics) , theoretical computer science , computer engineering , mathematics , embedded system , artificial intelligence , electrical engineering , statistics , engineering , telecommunications , physics , quantum mechanics , latency (audio)
Two novel theorems are developed which prove that certain logic functions are more robust to errors than others. These theorems are used to construct datapath circuits that give an increased immunity to error over other naive implementations. A link between probabilistic operation and ultra-low energy computing has been shown in prior work. These novel theorems and designs will be used to further improve probabilistic design of ultra-low power datapaths. This culminates in an asynchronousdesign for the maximum amount of energy savings per a given error rate. Spice simulation results using a commercially available and well-tested 0.25 μm technology are given verifying the ultra-low power, probabilistic full-adder designs. Further, close to 6X energy savings is achieved for a probabilistic full-adder over the deterministic case
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