Cadence® University Program Member
The Department of Electrical and Computer Engineering at Toronto Metropolitan University (formerly Ryerson) is a Cadence University Program Member.
Whether for research, graduate or undergraduate instruction, the Cadence® products are used in various levels and degrees. Reference the specific courses/research pages where each area is explained in detail. Depending on the undergraduate course, graduate course or research project, the Cadence® products are used for:
- Custom IC
- Digital IC
- Verification
- SPB (PCB)
UNDERGRADUATE COURSES
The following undergraduate courses use Cadence® products in their respective laboratory component:
- COE 718 Hardware/Software Co-design of Embedded Systems
- ELE 734 Low Power Digital Integrated Circuits
- ELE 800 Electronic Design Project
- ELE 714 VLSI Circuit Testing
- ELE 724 CMOS Mised-Mode Circuits
- COE 818 Advanced Computer Architecture
- ELE 863 VLSI Circuits and Systems for Data Communications
- ELE 804 Radio-frequency Circuits and Systems
- COE 838 Systems-on-Chip Design
GRADUATE COURSES
The following graduate courses use Cadence® products:
- EE 8501 VLSI Circuits for Data Communications
- EE 8205 Embedded Software Systems
- EE 8208 Computer Aided Synthsis and Design of Digital Systems
- EE 8502 CMOS Mixed-Mode Circuits
- EE 8504 VLSI Design Automation and CAD Tools
- EE 8505 Digital Systems Testing
- EE 8123 Radio-frequency circuits and systems.
ACADEMIC RESEARCH
Cadence® products are used in the following research areas:
- Adaptive Reconfigurable Group Architecture
- Latency Hiding Algorithm for DRAM and SDRAM Page Misses
- No-Instruction Computer
- A Simple Virtual Architecture for Uniprocessor to Support Vector Operations
- Reconfigurable Parallel Computer System with Adaption on Processing Tasks and Reconfigurable FPGA-based Processing Module with Adaption on Processing Tasks
- High-Speed CMOS Integrated Circuits for Optical and Wireless Communications
- Computer-aided Analysis of Mixed Analog-Digital Circuits
- Algorithms and design methodologies to efficiently design digital CMOS IP blocks
- Low-power, low-voltage, and high-performance CMOS circuit design
- Deep-submicron CMOS cell library modeling for power consumption, timing noise immunity
- Virtual library generation and performance driven transistor sizing
- Hardware software codesign
- Real time and embedded computer systems
- High performance and distributed computing
- Simulation of mixed analog, digital and RF circuits
- VLSI design of high-speed, low-power circuits
- Modeling of analog circuit components using high-level language
- Digital circuits & systems
- Testing & design for testability
- Field-programmable gate arrays (FPGAs), FPGA Architectures
- Computer-aided design (CAD) Tools, CAD Tools for FPGAs
- Datapath-oriented FPGA Architectures, datapath-oriented CAD
- Tools for FPGAs, FPGA-based digital circuit design, very large scale integrated circuits
- CMOS transceivers for high-speed wireline data communications.
- VLSI circuits for radio-frequency indentification systems
- RF-powered microsystems for emerging applications
- CMOS imaging systems
DISCLAIMER
This is not a "Cadence® Homepage".
This page contains only Cadence®-related information
Information is provided "as is" without warranty or guarantee of any kind. No statement is made and no attempt has been made to examine the information, either with respect to operability, origin, authorship, or otherwise.
Please use this information at your own risk and any attempt to use this information is at your own risk we recommend using it on a copy of your data to be sure you understand what it does and under your conditions. Keep your master intact until you are personally satisfied with the user of this information within your environment.
Page maintained by: Jason Naughton