Design method for numerical function generators using recursive segmentation and EVBDDs

IEICE Transaction on Fundamentals of Electronics, Communications and Computer Sciences, Vol.E90-A, No.12, Dec. 2007, pp.2752-2761.This publication is a work of the U.S. Government as defined in Title 17, United States Code, Section 101. As such, it is in the public domain, and under the provisions of Title 17, United States Code, Section 105, may not be copyrighted.Numerical function generators (NPGs) realize arithmetic functions, such as ex, sin p(piex), and the square root of x, in hardware. They are used in applications where high-speed is essential, such as digital signal or graphics applications. We introduce the edge-valued binary decision diagram (EVBDD) as a means of reducing the delay and memory requirements in NFGs. We also introduce a recursive segmentation algorithm, which divides the domain of the fuction to be realized into segments, where the given function is realized as a polynomial. This design reduces the size of the multiplier needed and thus reduces delay. It is also shown that an adder can be replaced by a set of 2-input AND gates, further reduceing delay. We compare our results to NFGs designed and multi-terminal BDDs (MTBDDs). We show that EVBDDs yield a design that has, on the average, only 39% of the memory and 58% of the delay of NFGs designed using MTBDDs.This research is partly supported by the Grant in Aid for Scientific Research of the Japan Society for the Promotion of Science (JSPS), funds from Ministry of Education, Culture, Sports, Science, and Technology (MEXT) via Kitakyushu innovative cluster project, a contract with the National Security Agency, the MEXT Grant-in-Aid for Young Scientists (B), 18700048, 2007 and Hiroshima City University Grant for Special Academic Research (General Studies), 6101, 2007

Proceedings of the Second NASA Formal Methods Symposium

This publication contains the proceedings of the Second NASA Formal Methods Symposium sponsored by the National Aeronautics and Space Administration and held in Washington D.C. April 13-15, 2010. Topics covered include: Decision Engines for Software Analysis using Satisfiability Modulo Theories Solvers; Verification and Validation of Flight-Critical Systems; Formal Methods at Intel -- An Overview; Automatic Review of Abstract State Machines by Meta Property Verification; Hardware-independent Proofs of Numerical Programs; Slice-based Formal Specification Measures -- Mapping Coupling and Cohesion Measures to Formal Z; How Formal Methods Impels Discovery: A Short History of an Air Traffic Management Project; A Machine-Checked Proof of A State-Space Construction Algorithm; Automated Assume-Guarantee Reasoning for Omega-Regular Systems and Specifications; Modeling Regular Replacement for String Constraint Solving; Using Integer Clocks to Verify the Timing-Sync Sensor Network Protocol; Can Regulatory Bodies Expect Efficient Help from Formal Methods?; Synthesis of Greedy Algorithms Using Dominance Relations; A New Method for Incremental Testing of Finite State Machines; Verification of Faulty Message Passing Systems with Continuous State Space in PVS; Phase Two Feasibility Study for Software Safety Requirements Analysis Using Model Checking; A Prototype Embedding of Bluespec System Verilog in the PVS Theorem Prover; SimCheck: An Expressive Type System for Simulink; Coverage Metrics for Requirements-Based Testing: Evaluation of Effectiveness; Software Model Checking of ARINC-653 Flight Code with MCP; Evaluation of a Guideline by Formal Modelling of Cruise Control System in Event-B; Formal Verification of Large Software Systems; Symbolic Computation of Strongly Connected Components Using Saturation; Towards the Formal Verification of a Distributed Real-Time Automotive System; Slicing AADL Specifications for Model Checking; Model Checking with Edge-valued Decision Diagrams; and Data-flow based Model Analysis