Title :
Optimizing gate reticle to silicon flow for variability in low power circuits
Author :
Parikh, Ashesh ; Kulkarni, Mak
Author_Institution :
Texas Instrum., Dallas, TX, USA
Abstract :
Ultra-low-power circuits for applications such as biomedical implants and environmental monitoring are being designed to operate in the subthreshold regime. CMOS circuits in this regime are extremely susceptible to manufacturing process variations due to the exponential relationship of transistor sub-threshold drive current (Id) with threshold voltage (Vt) variation. In this paper, we explore the behavior of an inverter ring oscillator that was manufactured using 130nm process technology and operated at low supply voltage (Vdd). We then explore the effects of variations induced due to different aspects of the manufacturing process. Finally, we define the box of safe operation using an existing 130nm CMOS process and the required precision to achieve high yields by optimizing the gate reticle to silicon (Si) flow for the same.
Keywords :
CMOS integrated circuits; invertors; low-power electronics; oscillators; CMOS circuit; biomedical implant; environmental monitoring; exponential relationship; gate reticle to silicon flow; inverter ring oscillator; low power circuit; manufacturing process variation; subthreshold regime; threshold voltage variation; transistor sub-threshold drive current; ultra-low-power circuit; Logic gates; Reactive power; SPICE; Semiconductor device modeling; Silicon; Stress; Transistors; Low power electronics; design automation; process variation; subthreshold;
Conference_Titel :
Circuits and Systems Workshop (DCAS), 2010 IEEE Dallas
Conference_Location :
Richardson, TX
Print_ISBN :
978-1-4244-9535-1
Electronic_ISBN :
978-1-4244-9534-4
DOI :
10.1109/DCAS.2010.5955032
