VLSI System Design
- Garant předmětu:
- Pavel Hazdra
- Pavel Hazdra
- Pavel Hazdra, Jakub Jirsa
- Department of Microelectronics
Introduction to basic building blocks, architecture and design methodologies of advanced VLSI systems. Structure and design of digital and analogue integrated circuit subsystems. Integrated system description and synthesis using cell libraries and IP cores. Synchronization, power consumption and parasitics reduction issues. Testing and reliability of integrated systems. In seminars and labs, the hardware description language VHDL will be explained and used for practical design, synthesis and testing of a system on chip.
Successful presentation of semestral project and pass in the final test.
- Syllabus of lectures:
1. VLSI system design, principles and hierarchy. Design methodology.
2. Levels of system description. Hardware description languages for behavioral and RTL description.
3. Code structure, semantics and syntax.
4. Assignments of hardware function, concurrent and sequential domains and their interpretation.
5. Hierarchy, design of parametric models and libraries. System description in SystemVerilog and SystemC.
6. Hardware platforms, target architectures, programmable and reconfigurable systems.
7. System on chip design, design re-use, Intellectual Property (IP) cores.
8. Behavioral synthesis: RTL model, algorithms and procedures. Logical synthesis: methods and constraints. Synthesis of topology. Control of system synthesis.
9. Models of integrated systems and structures, standards.
10. Testing and reliability. Fault models and methods of localization.
11. Verification flow and strategies.
12. Verification tools: simulators and models.
13. Test design and analysis: stimuli, responses and testbenches (design and architecture).
14. VLSI system project management, risk minimization, documentation, reviewing.
- Syllabus of tutorials:
1. Design system ISE: introduction into integrated system design - entry, synthesis, implementation.
2. Design system ISE: functional, logical and timing analysis. Digital system model in HDL
3.HDL - description of combinational (buffers, decoders, multiplexers) and sequential (counters) functions.
4. HDL - hierarchical design and verification models (testbenches).
5. HDL - state automata description and design of complex sequential systems.
6. State automata description in the StateCad environment, end of model project.
7. Migration of model design into different architectures, design reuse.
8. IP core libraries, design using IP core generators.
9. Floor planning and timing analysis, design of architecture specific blocks.
10. Description of course works, used IP modules, test.
11. Practical design of integrated system based on FPGA or SoC.
12. Practical design of integrated system based on FPGA or SoC.
13. Practical design of integrated system based on FPGA or SoC.
14. Presentation of course works, correction test, account.
- Study Objective:
The aim of the subject is introduction to basic building blocks, architecture and design methodologies of advanced VLSI systems.
- Study materials:
 Wayne Wolf : „Modern VLSI Design: System-on-Chip Design“, Prentice-Hall, 2002
 Samiha Mourad, Yervant Zorian: „Principles of Testing Electronic Systems“, John Wiley, 20002
 Bruce Wile, John C. Goss, Wolfgang Roesner: „Comprehensive Functional Verification“, Elsevier, 2005
 P. J. Ashenden, The Designer's Guide to VHDL, Morgan Kaufmann, 2008
 P. Chu, RTL Hardware Design Using VHDL: Coding for Efficiency, Portability, and Scalability, Wiley, 2006
 P.K.Lala, Principles of Modern Digital Design, Wiley, 2006
- Further information:
- Time-table for winter semester 2023/2024:
Wed Thu Fri
- Time-table for summer semester 2023/2024:
- Time-table is not available yet
- The course is a part of the following study plans:
- Electronics and Communications - Electronics (compulsory course in the program)
- Electronics and Communications - Photonics (compulsory elective course)
- Electronics and Communications - Technology of the Internet of Things (compulsory elective course)
- Electronics and Communications - Radio Communications and Systems (compulsory elective course)
In order to register for the course B2M34NSV, the student must have registered for the required number of courses in the group BEZBM no later than in the same semester.