Title :
A Wide Temperature, Radiation Tolerant, CMOS-Compatible Precision Voltage Referencefor Extreme Radiation Environment Instrumentation Systems
Author :
McCue, Benjamin M. ; Blalock, Benjamin J. ; Britton, Charles L. ; Potts, J. ; Kemerling, J. ; Isihara, K. ; Leines, M.T.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of Tennessee, Knoxville, TN, USA
Abstract :
Many design techniques have been incorporated into modern CMOS design practices to improve radiation tolerance of integrated circuits. Annular-gate NMOS structures have been proven to be significantly more radiation tolerant than the standard, straight-gate variety. Many circuits can be designed using the annular-gate NMOS and the inherently radiation tolerant PMOS. Bandgap reference circuits, however, typically require p-n junction diodes. These p-n junction diodes are the dominating factor in radiation degradation in bandgap reference circuits. This paper proposes a different approach to bandgap reference design to alleviate the radiation susceptibility presented by the p-n junction diodes.
Keywords :
CMOS integrated circuits; integrated circuit design; nuclear electronics; p-n junctions; radiation hardening (electronics); reference circuits; semiconductor diodes; CMOS-compatible precision voltage reference; annular-gate NMOS structures; bandgap reference circuits; design techniques; extreme radiation environment instrumentation systems; integrated circuits; modern CMOS design; p-n junction diodes; radiation degradation; radiation susceptibility; radiation tolerance; radiation tolerant PMOS; CMOS integrated circuits; Current density; MOSFET; P-n junctions; Photonic band gap; Temperature; Bandgap reference; CMOS; dynamic threshold MOSFET (DTMOS); radiation hardening by design (RHBD); total ionizing dose (TID) radiation;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2013.2257850
