Applications of Microprocessors in Measurement
Kód | Zakončení | Kredity | Rozsah | Jazyk výuky |
---|---|---|---|---|
XE38MIP | Z,ZK | 4 | 2+2s |
- Předmět je náhradou za:
- Applications of Microprocessors in Measurement (E38MIP)
Mikroprocesory v přístrojové technice (X38MIP) - Přednášející:
- Cvičící:
- Předmět zajišťuje:
- katedra měření
- Anotace:
-
Basic methods of application of microprocessor and single-chip
microcontroller in the design of microprocessor controlled measurement
instrument are presented in this course. The operation of microprocessors,
memories, input/outputs and other hardware blocks and their interfacing is
explained. The laboratory exercises are oriented on the individual design
and experimental realisation of simple instruments controlled by
microprocessor 8051.
- Požadavky:
-
Students should feel comfortable programming and using computers. A basic knowledge of logic design and circuit theory is assumed. Additional circuit-level and architecture-level knowledge would be useful but is not essential.
- Osnova přednášek:
-
1. The architecture, functional blocks and parameters of an microprocessor
controlled instrument (MI)
2. Embedded processors and microcontrollers for instrumentation
3. Digital signal processors and their application in instrumentation
4. 8-bit microcontrollers, architecture, peripherals, the rules of their
application in instrumentation
5. Instruction set, macroassembler, pseudoinstructions, formal writing of a
program
6. MOS memories - ROM, PROM, EPROM, memory cell, the structure, programming,
application
7. R/W memories; SRAM, FIFO, dual- and multi-ported memory, their application
8. Microprocessor system bus, signals, timing
9. Interfacing of I/O circuits, memories and microprocessor, decoder design
10. The methods of I/O operation and the data transmission in a MI
11. Programmable I/O peripherals and watchdogs
12. The user interface, push-buttons, keyboards, the rotation handlers
13. Displays - LED, LCD, statically and dynamically controlled, parallel and
serial interfacing, A/D and D/A converters and their interfacing to a microprocessor
- Osnova cvičení:
-
1. Assembler, debugger
2. Design of software for UART
3. Project No.1; Design of a microprocessor-controlled 4-digit Ohmmeter
4. Project No.1 Realisation of the Ohmmeter on the contact board
5. Project No.1 Software design and debugging
6. Project No.1 The experimental verifications of the Ohmmeter and error
analysis, presentation
7. Project No.2 Design of a 4 1 digit microprocessor controlled integrating
voltmeter
8. Project No.2 Practical realisation of the V-meter on the contact board
9. Project No.2 Software design
10. Project No.2 Software debugging
11. Project No.2 Experimental verifications of the voltmeter and its error
analysis. Final presentation
12. Individual Project No. 3 Complete design and realisation of a simple
instrument with microcontroller
13. I.P. No. 3 Hardware realisation of the complete instrument the contact
board, software design
I.P. No. 3 Software debugging and final presentation of the realised
instrument
- Cíle studia:
- Studijní materiály:
-
1. Rafiquzzaman, M.: Fundamentals of Digital Logic and Microcomputer Design.
ISBN: 0966498011, 1999
2. Atmel: Microcontroller Handbook
3. www.atmel.com
- Poznámka:
-
Výuka v angličtině.
- Další informace:
- Pro tento předmět se rozvrh nepřipravuje
- Předmět je součástí následujících studijních plánů:
-
- Cybernetics and Measurements- structured studies (povinně volitelný předmět)