Physical Design: Methodologies and Developments

TL;DR

This paper reviews methodologies and algorithms essential for developing efficient physical design flows in VLSI chip design, focusing on optimizing power, performance, and area through hierarchical design stages.

Contribution

It provides a comprehensive overview of physical design methodologies, highlighting recent developments and best practices for optimizing VLSI physical implementation.

Findings

Hierarchical flow is crucial for VLSI physical design.

Physical design involves placement and routing optimization.

Methodologies improve PPA parameters in chip design.

Abstract

The design and production of VLSI chips is a multilevel heirarchical process. As the demand for reduced die-area and technology nodes becomes prevalent, it gets increasingly challenging to optimize Power, Performance and Area (PPA) parameters to accommodate for the ever-increasing core logic on a chip. A well defined heirarchical flow is thus quintessential when it comes to VLSI design process. A robust heirarchical flow should encompass all stages, right from Gate-level RTL Synthesis (Front End Design) to Logic Placement and Verification (Back End Physical Design) and finally culminating with tapeout / production. Physical Design in this aforementioned flow is the process of translating logical circuit description into physically realizable GDSII form. This involves defining the best possible placement and routing for standard cells, macros and I/Os in the design to optimize PPA for any given netlist. This paper helps capture the nitty-gritty of methodologies and algorithms that are pertinent to the building and optimization of an efficient and robust physical design flow in VLSI chip-designing process.