Device physics impact on low leakage, high speed DSP design techniques

Author

Scott, David ; Tang, Shaoping ; Zhao, Song ; Nandakumar, Mahalingam

Author_Institution

Texas Instruments Inc., TX, USA

fYear

2002

fDate

2002

Firstpage

349

Lastpage

354

Abstract

The limitations of implementing low leakage schemes and their application to current state of the art components is discussed In addition to source subthreshold leakage, both gate induced diode leakage current and tunneling gate leakage current must be comprehended A viable leakage reduction strategy requires extensive modeling of circuits in the standby mode as well as new demands on the understanding of transistor physics. The ramifications of the physics of the behavior of transistors under conditions of high electric fields apply not only at the circuit level but can also impact the chip level system. In the coming applications of mobile electronics, understanding of this concept is critical.

Keywords

CMOS digital integrated circuits; digital signal processing chips; high-speed integrated circuits; integrated circuit design; leakage currents; semiconductor device models; tunnelling; GIDL; gate current physics; gate induced diode leakage current; high electric fields; high speed DSP design techniques; leakage reduction strategy; low leakage DSP design techniques; low leakage schemes; modeling; source subthreshold leakage; standby mode; transistor physics; tunneling gate leakage current; Circuits; Digital signal processing; Electron traps; Leakage current; Physics; Semiconductor diodes; Subthreshold current; Temperature dependence; Threshold voltage; Tunneling;

fLanguage

English

Publisher

ieee

Conference_Titel

Quality Electronic Design, 2002. Proceedings. International Symposium on

Print_ISBN

0-7695-1561-4

Type

conf

DOI

10.1109/ISQED.2002.996771

Filename

996771