Obálka

Beyond Vhdl Simulation To On Chip Testing

Uloženo v:
Vydáno v:Association for Engineering Education - Engineering Library Division Papers (Jun 22, 2008), p. 13.251.1
Hlavní autor: Hayne, Ronald
Vydáno:
American Society for Engineering Education-ASEE
Témata:
Digital mapping
Rapid prototyping
Programmable logic arrays
RISC
Hardware description languages
Microprocessors
Systems design
Debugging
Digital systems
Digital electronics
Program verification (computers)
Circuit design
Programmable logic devices
Wiring
Field programmable gate arrays
Instruction sets (computers)
Software
Computer simulation
Students
Software development tools
Prototypes
Computer assisted instruction > CAI
Circuits
Simulation
Mapping
Verification
Languages
Tests
Translation
Internet
Teaching
Polls & surveys
Access
Challenges
Logic
On-line přístup:Citation/Abstract
Full text outside of ProQuest
Tagy: Přidat tag
Žádné tagy, Buďte první, kdo vytvoří štítek k tomuto záznamu!
Abstrakt:Digital systems design relies heavily on hardware description languages and their associated software tools. While VHDL allows functional verification of designs, simulation alone cannot prepare our students for the technical challenges associated with the final translation to actual hardware. Field programmable gate arrays (FPGAs) allow rapid prototyping of digital designs on a single chip. This tight integration presents additional challenges when it comes to testing the final hardware, because access to internal signals is limited. ChipScope™ Pro integrates key logic analyzer components with the target design inside the FPGA. A program of instruction has been developed at The Citadel that uses VHDL, FPGAs, and ChipScope™ Pro to teach advanced digital systems design. Examples are modeled and simulated using VHDL, then synthesized to FPGAs with embedded logic analyzer cores. The final hardware implementations are demonstrated using ChipScope™ Pro to provide access to on-chip signals. Designs include a binary multiplier and a reduced instruction set computer (RISC) processor. These textbook examples are turned into functional prototypes, bridging the gap between theory and hardware. Ultimately, the use of these integrated design tools provides a more robust learning experience that moves beyond VHDL simulation to on-chip testing. Modern digital systems design relies heavily on hardware description languages, such as VHDL, and their associated software tools. Most important in an educational environment is logic simulation, which allows functional verification of designs without the need for hardware implementation. While this allows quick investigation of multiple design examples, simulation alone cannot prepare our students for the technical challenges associated with the final translation to actual hardware. Programmable logic devices provide an integrated platform for implementation of digital circuits. Mapping designs to hardware provides students additional experience and insights associated with synthesis and device programming tools. FPGAs allow rapid prototyping of digital designs on a single chip, eliminating the need for multiple devices and error-prone external wiring. This tight integration presents additional challenges when it comes to testing the final hardware. Access to internal signals is limited, often making debugging more difficult. Development Options A quick web survey of undergraduate digital systems design courses revealed two basic approaches, lecture and lab. Lecture courses taught hardware description languages and relied
Zdroj:Library Science Database