Module also offered within study programmes:
General information:
Name:
Computer measurement systems
Course of study:
2017/2018
Code:
IES-1-503-s
Faculty of:
Computer Science, Electronics and Telecommunications
Study level:
First-cycle studies
Specialty:
-
Field of study:
Electronics and Telecommunications
Semester:
5
Profile of education:
Academic (A)
Lecture language:
English
Form and type of study:
Full-time studies
Course homepage:
 
Responsible teacher:
Baszczyk Mateusz (baszczyk@agh.edu.pl)
Academic teachers:
prof. zw. dr hab. inż. Kucewicz Wojciech (kucewicz@agh.edu.pl)
Module summary

Description of learning outcomes for module
MLO code Student after module completion has the knowledge/ knows how to/is able to Connections with FLO Method of learning outcomes verification (form of completion)
Social competence
M_K001 The student understands and knows the need for continuous training opportunities, improving professional skills, personal and social Activity during classes
Skills
M_U001 The student is able to analyze signals in the time and frequency domain using appropriate software tools Execution of laboratory classes
M_U002 The student is able to present the results in the form of numerical and graphical, to interpret them and draw the right conclusions Execution of laboratory classes
M_U003 The student has the ability to self-learning, including in order to improve professional competence Execution of laboratory classes
Knowledge
M_W001 The student has a basic knowledge of the design of measurement systems Execution of laboratory classes
M_W002 The student has a basic knowledge of the methodology and programming techniques in a graphical programming language using the LabView programming environment Execution of laboratory classes
M_W003 The student has a basic knowledge of the organization of computer-based systems, measuring cards, extensive measurement systems built on the basis of computer networks, measuring systems based on GPIBbus bus (IEEE-488.1, 488.2) Execution of laboratory classes
FLO matrix in relation to forms of classes
MLO code Student after module completion has the knowledge/ knows how to/is able to Form of classes
Lecture
Audit. classes
Lab. classes
Project classes
Conv. seminar
Seminar classes
Pract. classes
Zaj. terenowe
Zaj. warsztatowe
Others
E-learning
Social competence
M_K001 The student understands and knows the need for continuous training opportunities, improving professional skills, personal and social + - + - - - - - - - -
Skills
M_U001 The student is able to analyze signals in the time and frequency domain using appropriate software tools + - + - - - - - - - -
M_U002 The student is able to present the results in the form of numerical and graphical, to interpret them and draw the right conclusions + - + - - - - - - - -
M_U003 The student has the ability to self-learning, including in order to improve professional competence + - + - - - - - - - -
Knowledge
M_W001 The student has a basic knowledge of the design of measurement systems + - + - - - - - - - -
M_W002 The student has a basic knowledge of the methodology and programming techniques in a graphical programming language using the LabView programming environment + - + - - - - - - - -
M_W003 The student has a basic knowledge of the organization of computer-based systems, measuring cards, extensive measurement systems built on the basis of computer networks, measuring systems based on GPIBbus bus (IEEE-488.1, 488.2) + - + - - - - - - - -
Module content
Lectures:
Lectures

1. Measuring systems based on LabView graphical package. – Basic blocks LabView package. The rules for creating the program. Control of measuring devices steering from your computer. Saving data. Analysis and presentation of data. Graphical user interface.

2. GPIB bus – bus structure. Interface functions and messages. Addressing and transmission protocol.
SCPI standard.

3. Fieldbus bus (CAN) – Construction of the bus and its properties. The frame format. Error handling. CAN bus standards. Examples apikacje.

5. Measuring systems of large physics experiments

Laboratory classes:

1. Introduction to programming techniques in a graphical programming language development environment using LabView – 3 hours – read the LabView environment, the implementation of the first program.
2. Digital Oscilloscope – 5 hours – designing the structure of a digital oscilloscope LabView program, the implementation of computer communication with the external circuit of analog – digital. Presentation of signals in a graphical manner. Measurements of the frequency of the signals generated by different methods, using the features available in the program. Analysis and interpretation of results.
3. Communication with a digital multimeter – 5 hours – designing the structure of the application in LabView program, the implementation of computer communication using a digital multimeter VISA package. Data formatting, presentation of signals in a way that text and graphics.
4. Consultation and evaluation of projects – 2 hours – based on the selected topic the student performs independently design classes according to preset criteria.

Student workload (ECTS credits balance)
Student activity form Student workload
Summary student workload 56 h
Module ECTS credits 2 ECTS
Participation in lectures 18 h
Participation in laboratory classes 14 h
Completion of a project 14 h
Realization of independently performed tasks 10 h
Additional information
Method of calculating the final grade:

1.To obtain a positive final assessment is to get good ratings from the lab
and the final test of the lecture.
2.The weighted average of the ratings from the laboratory (50%) and lectures (50%)
3.The final grade based on the relationship:
f sr> 4.75 then OK: = 5.0 else
f sr> 4.25 then OK: = 4.5 else
f sr> 3.75 then OK: = 4.0 else
f sr> 3.25 then OK: = 3.5 else OK: = 3

Prerequisites and additional requirements:

Basic knowledge of metrology.

Recommended literature and teaching resources:

Waldemar Nawrocki – „Komputerowe systemy pomiarowe”
Johnson Gary W. – “LabVIEW Graphical Programming : Practical Applications in Instrumentation and Control”;
Anthony J. Caristi – „IEEE-488 General Purpose Instrumentation Bus Manual”;
Wade D. Peterson – „The VMEbus Handbook”
Nawrocki W.: Sensory i systemy pomiarowe. WPPozn. Poznań 2001.

Scientific publications of module course instructors related to the topic of the module:

Additional scientific publications not specified

Additional information:

The staff has improved communications skills, which have been developed during English language trainings in the POWR.03.04.00-00-D002/16 project, carried out by the Faculty of Computer Science, Electronics and Telecommunications under the Smart Growth Operational Programme 2014-2020.