Rapid System Prototyping with FPGAs: Accelerating the design process Benjamin F. Harding, RC Cofer
Publisher: Newnes

یک کتاب مفید برای علاقمندان FPGA. 2010 Survey data suggests a rapid increase in ASIC designs targeted below 65nm process node. Accelerating Sensor Development with Rapid Prototyping and Model-Based Design . This review is from: Rapid System Prototyping with FPGAs: Accelerating the design process (Embedded Technology) (Paperback). Lynx's open architecture is optimized for rapid, out-of-the-box deployment with Synopsys' Galaxy™ Design Platform and is inherently configurable to readily incorporate third-party technology. VLIW Microprocessor Hardware Design offers you a complete guide. Processor Design: System-On-Chip Computing for ASICs and FPGAs. Rapid System Prototyping with FPGAs: Accelerating the design process By RC Cofer, Benjamin F. Perhaps of greater interest is the rapid movement in chips To achieve these capabilities, chip manufactures must upgrade or replace existing equipment to systems that support the latest process nodes. Designed for scalable use in design organizations of all sizes, the Lynx Design System combines a production-proven RTL-to-GDSII design flow with productivity-enhancing features to accelerate chip development while mitigating the risks of designing at new process nodes. Accelerating the pace of engineering and science. Rapid System Prototyping with FPGAs: Accelerating the design process by RC Cofer, Benjamin F. Using the NI LabVIEW graphical system design platform, DARwIn achieved full range of motion and accurately imitated human movement so effectively that it was quickly modified to enter the RoboCup soccer competition (see Figure 1). Rapid System Prototyping with FPGAs: Accelerating the design process. NASA Langley's MATLAB based control system fully automates the welding process and produces complex components from a 3D CAD representation. This process is failing for a number of reasons, including the speed of software simulators when full chips are assembled and the difficulty in creating useful tests at the system level using constrained-random generation tools. Model-Based Design enables engineers to develop FPGA prototypes much faster and with a greater degree of confidence than with a traditional, manual workflow. Figure 1: Three-year trends in manufacturing process nodes for current ASIC/ASSP/SoC prototypes based on FPGAs.