A Simple General-purpose I-V Model for All Operating Modes of Deep Submicron MOSFETs

Scaling of InGaAs MOSFETs into deep-submicron

We have demonstrated high-performance deep-submicron inversion-mode InGaAs MOSFETs with gate lengths down to 150 nm with record Gm exceeding 1.1 mS/μm. Oxide thickness scaling is performed to improve the on-state/off-state performance and Gm is further improved to 1.3 mS/μm. HBr pre-cleaning, retro-grade structure and halo-implantation processes are first time introduced into III-V MOSFETs to s...

Issues in High Frequency Noise Simulation for Deep Submicron MOSFETs

This paper proposes issues in highly accurate high frequency noise simulation for deep submicron MOSFETs. Unlike classical RF design, in which a given device with fixed characteristics is used, CMOS RF design permits selection of user specified device geometries as well as matching elements and bias conditions. Therefore, an exhaustive intrinsic noise modeling of MOSFETs across the entire opera...

Gate and Substrate Currents in Deep Submicron MOSFETs

investigating the feasibility of a proposed model for geometric design of deployable arch structures

deployable scissor type structures are composed of the so-called scissor-like elements (sles), which are connected to each other at an intermediate point through a pivotal connection and allow them to be folded into a compact bundle for storage or transport. several sles are connected to each other in order to form units with regular polygonal plan views. the sides and radii of the polygons are...

Design Rationale for Psyche a General-Purpose Multiprocessor Operating System

The Psyche project at the University of Rochester aims to develop a high-performance operating system to support a wide variety of models for parallel programming. It is predicated on the conviction that no one model of process state or style of communication will prove appropriate for all applications, but that shared-memory multiprocessors (particularly the scalable ‘‘NUMA’’ variety) can and ...

Psyche: A General-Purpose Operating System for Shared-Memory Multiprocessors

The Psyche project at the University of Rochester aims to develop a high-performance operating system to support a wide variety of models for parallel programming on a shared-memory multiprocessor. It is predicated on the assumption that no one model of process state or style of communication will prove appropriate for all applications, but that a shared-memory machine can and should support al...