A Sensor to Detect Normal or Reverse Temperature Dependence in Nanoscale CMOS Circuits

Author

Wolpert, David ; Ampadu, Paul

Author_Institution

ECE Dept., Univ. of Rochester, Rochester, NY, USA

fYear

2009

fDate

7-9 Oct. 2009

Firstpage

193

Lastpage

201

Abstract

The temperature dependence of MOSFET drain current varies with supply voltage. Two distinct voltage regions exist-a normal dependence (ND) region where an increase in temperature decreases drain current, and a reverse dependence (RD) region where an increase in temperature increases drain current. Knowledge of the temperature dependence is critical for avoiding overheating and wasted performance from excessive guardbands. In this paper, we present the first temperature dependence sensor to detect whether a system is operating in the ND or RD region. The dependence sensor occupies an area of 985 NAND2 equivalent gates. The sensor consumes 15.9 pJ per sample at a supply voltage of 1 V, with a 1Â°C resolution over the military-specified temperature range of -55Â°C to 125Â°C.

Keywords

CMOS integrated circuits; MOSFET; logic gates; temperature sensors; MOSFET drain current; NAND2 equivalent gates; military-specified temperature range; nanoscale CMOS circuits; normal temperature dependence; reverse temperature dependence; temperature -55 degC to 125 degC; temperature dependence sensor; voltage 1 V; Circuits; Delay; Neodymium; Oscillators; Power system reliability; Sensor systems; Temperature dependence; Temperature sensors; Timing; Voltage; Temperature sensor; reverse temperature dependence; temperature variation;

fLanguage

English

Publisher

ieee

Conference_Titel

Defect and Fault Tolerance in VLSI Systems, 2009. DFT '09. 24th IEEE International Symposium on

Conference_Location

Chicago, IL

ISSN

1550-5774

Print_ISBN

978-0-7695-3839-6

Type

conf

DOI

10.1109/DFT.2009.47

Filename

5372256