Title :
Magnetic Shadow RAM
Author :
Hass, K.J. ; Donohoe, G.W. ; Hong, Y.K. ; Choi, B.C. ; DeGregorio, K. ; Hayhurst, R.
Author_Institution :
Univ. of Idaho, Moscow, ID
Abstract :
We propose a new shadow RAM circuit, utilizing magnetic tunnel junctions and an independent-double-gate CMOS technology. A shadow RAM combines a conventional static RAM circuit with a non-volatile "shadow", and provides a means to quickly transfer data between them. Non-volatile magnetic storage offers several advantages over current technology for this application, with unlimited write endurance, very fast write time, low power consumption, and improved radiation tolerance. A novel circuit allows the shadow storage to be incorporated into a RAM cell using independent-double- gate transistors. The physical layout of the shadow RAM is unlike bulk MRAM, making it possible to embed the shadow RAM elements into computational logic without the X-Y grid decoding of the cell address. Accordingly, the micromagnetic structures have been optimized for writing with a new "one- wire" technique. We discuss proposed circuits and present circuit simulation results.
Keywords :
CMOS memory circuits; field effect transistors; low-power electronics; magnetic storage; magnetic tunnelling; random-access storage; RAM cell; circuit simulation; computational logic; conventional static RAM circuit; independent-double- gate transistors; independent-double-gate CMOS technology; low power consumption; magnetic shadow RAM circuit; magnetic tunnel junctions; micromagnetic structures; nonvolatile magnetic storage; one- wire technique; radiation tolerance; CMOS technology; Decoding; Embedded computing; Energy consumption; Grid computing; Logic; Magnetic circuits; Magnetic memory; Magnetic tunneling; Physics computing;
Conference_Titel :
Non-Volatile Memory Technology Symposium, 2006. NVMTS 2006. 7th Annual
Conference_Location :
San Mateo, CA
Print_ISBN :
0-7803-9738-X
DOI :
10.1109/NVMT.2006.378874
