Voltage island-driven floorplanning.

Ma, Qiang.Thesis (M.Phil.)--Chinese University of Hong Kong, 2008.Includes bibliographical references (leaves 78-80).Abstracts in English and Chinese.Abstract --- p.iAcknowledgement --- p.ivChapter 1 --- Introduction --- p.1Chapter 1.1 --- Background --- p.1Chapter 1.2 --- Floorplanning --- p.2Chapter 1.3 --- Motivations --- p.4Chapter 1.4 --- Design Implementation of Voltage Islands --- p.5Chapter 1.5 --- Problem Formulation --- p.8Chapter 1.6 --- Progress on the Problem --- p.10Chapter 1.7 --- Contributions --- p.12Chapter 1.8 --- Thesis Organization --- p.14Chapter 2 --- Literature Review on MSV --- p.15Chapter 2.1 --- Introduction --- p.15Chapter 2.2 --- MSV at Post-floorplan/Post Placement Stage --- p.16Chapter 2.2.1 --- """Post-Placement Voltage Island Generation under Performance Requirement""" --- p.16Chapter 2.2.2 --- """Post-Placement Voltage Island Generation""" --- p.18Chapter 2.2.3 --- """Timing-Constrained and Voltage-Island-Aware Voltage Assignment""" --- p.19Chapter 2.2.4 --- """Voltage Island Generation under Performance Requirement for SoC Designs""" --- p.20Chapter 2.2.5 --- """An ILP Algorithm for Post-Floorplanning Voltage-Island Generation Considering Power-Network Planning""" --- p.21Chapter 2.3 --- MSV at Floorplan/Placement Stage --- p.22Chapter 2.3.1 --- """Architecting Voltage Islands in Core-based System-on-a- Chip Designs""" --- p.22Chapter 2.3.2 --- """Voltage Island Aware Floorplanning for Power and Timing Optimization""" --- p.23Chapter 2.4 --- Summary --- p.27Chapter 3 --- MSV Driven Floorplanning --- p.29Chapter 3.1 --- Introduction --- p.29Chapter 3.2 --- Problem Formulation --- p.32Chapter 3.3 --- Algorithm Overview --- p.33Chapter 3.4 --- Optimal Island Partitioning and Voltage Assignment --- p.33Chapter 3.4.1 --- Voltage Islands in Non-subtrees --- p.35Chapter 3.4.2 --- Proof of Optimality --- p.36Chapter 3.4.3 --- Handling Island with Power Down Mode --- p.37Chapter 3.4.4 --- Speedup in Implementation and Complexity --- p.38Chapter 3.4.5 --- Varying Background Chip-level Voltage --- p.39Chapter 3.5 --- Simulated Annealing --- p.39Chapter 3.5.1 --- Moves --- p.39Chapter 3.5.2 --- Cost Function --- p.40Chapter 3.6 --- Experimental Results --- p.40Chapter 3.6.1 --- Extension to Minimize Level Shifters --- p.45Chapter 3.6.2 --- Extension to Consider Power Network Routing --- p.46Chapter 3.7 --- Summary --- p.46Chapter 4 --- MSV Driven Floorplanning with Timing --- p.49Chapter 4.1 --- Introduction --- p.49Chapter 4.2 --- Problem Formulation --- p.52Chapter 4.3 --- Algorithm Overview --- p.56Chapter 4.4 --- Voltage Assignment Problem --- p.56Chapter 4.4.1 --- Lagrangian Relaxation --- p.58Chapter 4.4.2 --- Transformation into the Primal Minimum Cost Flow Problem --- p.60Chapter 4.4.3 --- Cost-Scaling Algorithm --- p.64Chapter 4.4.4 --- Solution Transformation --- p.66Chapter 4.5 --- Simulated Annealing --- p.69Chapter 4.5.1 --- Moves --- p.69Chapter 4.5.2 --- Speeding up heuristic --- p.69Chapter 4.5.3 --- Cost Function --- p.70Chapter 4.5.4 --- Annealing Schedule --- p.71Chapter 4.6 --- Experimental Results --- p.71Chapter 4.7 --- Summary --- p.72Chapter 5 --- Conclusion --- p.76Bibliography --- p.8

Compiler-directed energy reduction using dynamic voltage scaling and voltage Islands for embedded systems

Cataloged from PDF version of article.Addressing power and energy consumption related issues early in the system design flow ensures good design and minimizes iterations for faster turnaround time. In particular, optimizations at software level, e.g., those supported by compilers, are very important for minimizing energy consumption of embedded applications. Recent research demonstrates that voltage islands provide the flexibility to reduce power by selectively shutting down the different regions of the chip and/or running the select parts of the chip at different voltage/frequency levels. As against most of the prior work on voltage islands that mainly focused on the architecture design and IP placement related issues, this paper studies the necessary software compiler support for voltage islands. Specifically, we focus on an embedded multiprocessor architecture that supports both voltage islands and control domains within these islands, and determine how an optimizing compiler can automatically map an embedded application onto this architecture. Such an automated support is critical since it is unrealistic to expect an application programmer to reach a good mapping correlating multiple factors such as performance and energy at the same time. Our experiments with the proposed compiler support show that our approach is very effective in reducing energy consumption. The experiments also show that the energy savings we achieve are consistent across a wide range of values of our major simulation parameters

VoltageIsland Driven Floorplanning Considering Level-Shifter Positions. GLSVLSI

ABSTRACT Power optimization has become a significant issue when the CMOS technology entered the nanometer era. MultipleSupply Voltage (MSV) is a popular and effective method for power reduction. Level shifters may cause area and Interconnect Length Overhead(ILO), and should be considered during floorplanning and post-floorplanning stages. In this paper, we propose a two phases framework VLSAF to solve voltage and level shifter assignment problem. At floorplanning phase, we use: a convex cost network flow algorithm to assign voltage; a minimum cost flow algorithm to assign level shifter. At post-floorplanning phase, a heuristic method is adopted to redistribute white spaces and calculate the positions and shapes of level shifters. Experimental results show VLSAF is effective