CTU FEE Moodle
Microsystems
B232 - Summer 23/24
This is a grouped Moodle course. It consists of several separate courses that share learning materials, assignments, tests etc. Below you can see information about the individual courses that make up this Moodle course.
Microsystems - BE2M34MST
Main course
| Credits | 6 |
| Semesters | Summer |
| Completion | Assessment + Examination |
| Language of teaching | English |
| Extent of teaching | 2P+2L |
Annotation
The course deals with system integration applied in the design of digital and analog systems. It demonstrates the new possibilities of implementation and application of integrated microelectronic devices based on various physical and biochemical principles. It presents primarily MEMS technology that increases reliability with all its attributes. The course presents the modern action elements and microactuators, whose operation is based on fundamental physical and biochemical principles, including basic applications in micromanipulation, microrobots, microdrives, microsurgery, multimedia, medical, industrial control, automotive, etc. In the course are presented the principles of touch screens, microgenerators of electrical energy. There are mentioned basic elements of the use of nanotechnology and nanoelectronic structures and basic microsystem technologies.
Study targets
Gaining knowledge about the current and future development of systems on a chip, the integration of on-chip, electrical and non-electrical action systems, usage of basic physical phenomena for applications in electronics, optics, communications, medicine and aviation, in the realization of miniature generators from renewable energy sources - excluding the photovoltaics.
Course outlines
1. Microsystems structures, energy domains, importance, interdisciplinary, applications, system integration of digital and analog systems, multi-chip configuration
2. Physical phenomena, design methods, interconnection of systems-on-chip and external devices, process control, communication and evaluation, system reliability and its increasing by integration
3. Micro-actuators parameters, scaling
4. Tactile sensors and touch screens, biometric devices, from graphite to graphene
5. Basic mechanisms and structures used in micro-actuators
6. Electrostatic linear and rotary actuators components - basic physical principles and application
7. Electrostatic micromanipulators and micro-motors
8. Piezoelectric micro-actuators mechanisms, micro-motors and micromanipulators
9. Heat and magnetic principle - micro-actuators mechanisms
10. Mechanical Systems and micro-actuators mechanisms
11. Chemical and biochemical principles - micro-actuators mechanisms, intelligent microsystems structures for chemical and biochemical analysis, Lab-on-Chip
12. RF MEMS and MOEMS structures, (electronic switches, filters, optical switches, optical mirrors, tunable capacitors, etc.)
13. Micro-generators based on Energy Harvesting
14. Nanoscale systems
2. Physical phenomena, design methods, interconnection of systems-on-chip and external devices, process control, communication and evaluation, system reliability and its increasing by integration
3. Micro-actuators parameters, scaling
4. Tactile sensors and touch screens, biometric devices, from graphite to graphene
5. Basic mechanisms and structures used in micro-actuators
6. Electrostatic linear and rotary actuators components - basic physical principles and application
7. Electrostatic micromanipulators and micro-motors
8. Piezoelectric micro-actuators mechanisms, micro-motors and micromanipulators
9. Heat and magnetic principle - micro-actuators mechanisms
10. Mechanical Systems and micro-actuators mechanisms
11. Chemical and biochemical principles - micro-actuators mechanisms, intelligent microsystems structures for chemical and biochemical analysis, Lab-on-Chip
12. RF MEMS and MOEMS structures, (electronic switches, filters, optical switches, optical mirrors, tunable capacitors, etc.)
13. Micro-generators based on Energy Harvesting
14. Nanoscale systems
Exercises outlines
1. Introduction, organization of the seminars, introduction to safety in work
2. Semester project selection, registration for excursion
3. Introduction to the programs Coventor and Ansys
4. Simulation and modeling of basic MEMS structures in Ansys
5. Simulation and modeling of basic MEMS structures in Ansys
6. Simulation and modeling of basic MEMS structures in Ansys, Preparation for excursion
7. Excursion, practical exercise in clean rooms
8. Simulation and modeling of basic MEMS structures in Ansys
9. Laboratory exercise - Application of the material printer
10. Laboratory exercise - Characterization of the fabricated structures
11. Measurement - practical applications of the MEMS structures
12. Presentation of semester projects
13. Presentation of semester projects
14. Additional measurements: completion of missing measurement tasks, assessment
2. Semester project selection, registration for excursion
3. Introduction to the programs Coventor and Ansys
4. Simulation and modeling of basic MEMS structures in Ansys
5. Simulation and modeling of basic MEMS structures in Ansys
6. Simulation and modeling of basic MEMS structures in Ansys, Preparation for excursion
7. Excursion, practical exercise in clean rooms
8. Simulation and modeling of basic MEMS structures in Ansys
9. Laboratory exercise - Application of the material printer
10. Laboratory exercise - Characterization of the fabricated structures
11. Measurement - practical applications of the MEMS structures
12. Presentation of semester projects
13. Presentation of semester projects
14. Additional measurements: completion of missing measurement tasks, assessment
Literature
1. Fraden,J.: Handbook of modern sensors. American institut of physics, Woodbury 1997
2.Tuller,H.L, Microactuators, Kluwer 1998
2.Tuller,H.L, Microactuators, Kluwer 1998
Requirements
No data.
Microsystems - AE2M34MST
| Credits | 5 |
| Semesters | Winter |
| Completion | Assessment + Examination |
| Language of teaching | Czech |
| Extent of teaching | 2P+2L |
Annotation
The course deals with system integration applied in the design of digital and analog systems. It demonstrates the new possibilities of implementation and application of integrated microelectronic devices based on various physical and biochemical principles. It presents primarily MEMS technology that increases reliability with all its attributes. The course presents the modern action elements and microactuators, whose operation is based on fundamental physical and biochemical principles, including basic applications in micromanipulation, microrobots, microdrives, microsurgery, multimedia, medical, industrial control, automotive, etc. In the course are presented the principles of touch screens, microgenerators of electrical energy. There are mentioned basic elements of the use of nanotechnology and nanoelectronic structures and basic microsystem technologies.
Study targets
Gaining knowledge about the current and future development of systems on a chip, the integration of on-chip, electrical and non-electrical action systems, usage of basic physical phenomena for applications in electronics, optics, communications, medicine and aviation, in the realization of miniature generators from renewable energy sources - excluding the photovoltaics.
Course outlines
1. Microsystems structures, energy domains, importance, interdisciplinary, applications, system integration of digital and analog systems, multi-chip configuration
2. Physical phenomena, design methods, interconnection of systems-on-chip and external devices, process control, communication and evaluation, system reliability and its increasing by integration
3. Micro-actuators parameters, scaling
4. Tactile sensors and touch screens, biometric devices, from graphite to graphene
5. Basic mechanisms and structures used in micro-actuators
6. Electrostatic linear and rotary actuators components - basic physical principles and application
7. Electrostatic micromanipulators and micro-motors
8. Piezoelectric micro-actuators mechanisms, micro-motors and micromanipulators
9. Heat and magnetic principle - micro-actuators mechanisms
10. Mechanical Systems and micro-actuators mechanisms
11. Chemical and biochemical principles - micro-actuators mechanisms, intelligent microsystems structures for chemical and biochemical analysis, Lab-on-Chip
12. RF MEMS and MOEMS structures, (electronic switches, filters, optical switches, optical mirrors, tunable capacitors, etc.)
13. Micro-generators based on Energy Harvesting
14. Nanoscale systems
2. Physical phenomena, design methods, interconnection of systems-on-chip and external devices, process control, communication and evaluation, system reliability and its increasing by integration
3. Micro-actuators parameters, scaling
4. Tactile sensors and touch screens, biometric devices, from graphite to graphene
5. Basic mechanisms and structures used in micro-actuators
6. Electrostatic linear and rotary actuators components - basic physical principles and application
7. Electrostatic micromanipulators and micro-motors
8. Piezoelectric micro-actuators mechanisms, micro-motors and micromanipulators
9. Heat and magnetic principle - micro-actuators mechanisms
10. Mechanical Systems and micro-actuators mechanisms
11. Chemical and biochemical principles - micro-actuators mechanisms, intelligent microsystems structures for chemical and biochemical analysis, Lab-on-Chip
12. RF MEMS and MOEMS structures, (electronic switches, filters, optical switches, optical mirrors, tunable capacitors, etc.)
13. Micro-generators based on Energy Harvesting
14. Nanoscale systems
Exercises outlines
1. Introduction, organization of the seminars, introduction to safety in work
2. Semester project selection, registration for excursion
3. Introduction to the programs Coventor and Ansys
4. Simulation and modeling of basic MEMS structures in Ansys
5. Simulation and modeling of basic MEMS structures in Ansys
6. Simulation and modeling of basic MEMS structures in Ansys, Preparation for excursion
7. Excursion, practical exercise in clean rooms
8. Simulation and modeling of basic MEMS structures in Ansys
9. Laboratory exercise - Application of the material printer
10. Laboratory exercise - Characterization of the fabricated structures
11. Measurement - practical applications of the MEMS structures
12. Presentation of semester projects
13. Presentation of semester projects
14. Additional measurements: completion of missing measurement tasks, assessment
2. Semester project selection, registration for excursion
3. Introduction to the programs Coventor and Ansys
4. Simulation and modeling of basic MEMS structures in Ansys
5. Simulation and modeling of basic MEMS structures in Ansys
6. Simulation and modeling of basic MEMS structures in Ansys, Preparation for excursion
7. Excursion, practical exercise in clean rooms
8. Simulation and modeling of basic MEMS structures in Ansys
9. Laboratory exercise - Application of the material printer
10. Laboratory exercise - Characterization of the fabricated structures
11. Measurement - practical applications of the MEMS structures
12. Presentation of semester projects
13. Presentation of semester projects
14. Additional measurements: completion of missing measurement tasks, assessment
Literature
1. Tuller,H.L, Microactuators, Kluwer 1998
2. Busch-Vishniac,I.,J.: Electromechanical Sensors and Actuators, Springer, 2003
3. Fraden,J.: Handbook of modern sensors. American institut of physics, Woodbury 1997
2. Busch-Vishniac,I.,J.: Electromechanical Sensors and Actuators, Springer, 2003
3. Fraden,J.: Handbook of modern sensors. American institut of physics, Woodbury 1997
Requirements
No data.