ging
| ECTS: 3
Responsible Instructor Prof.dr. G.Q. Zhang ([email protected]) Instructor W.D. van Driel ([email protected]) Contact Hours / Week
x/x/x/x 0/0/2/0 Exam Period none
Course Contents As the bridge between IC and various electronics systems, microelectronic packaging controls more than 90% of the size, 60% of the cost, and largely the system performance and reliability. It is one of the most fasci- nating and rapid developing technology and business fields of Semicon- ductors. Due to the recent progress of Cu/Low-k CMOS and advanced SiP technologies, microelectronic packaging is playing a dominant role in the development of future microelectronics and Microsystems.
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Course Contents (continued)
Course outline:
- Application needs (Ambient Intelligence drives) for Semiconductors - Technology and business development trends of Semiconductors - Overview of advanced CMOS process technologies (including Cu/Low-k), and advanced packaging technologies (covering the packaging glossary, design specification, materials and properties, process flows and process characteristics for both peripheral and Area Array interconnects, etc.) - Designing and qualification of advanced packages (QFN, BGA, FlipChip, CSP, WLP, three level SiP)
- Emerging packaging technologies, such as Cu/low-k packaging, Nano- packaging, MEMS packaging, opto-packaging and Bio-packaging - Second level assembly
- International technology roadmap and future packaging perspectives Education Method Lectures
Literature and Study Materials
Course material: Handout (presentations)
Book 'Mechanics of Microelectronics' by G.Q. Zhang, W.D. van Driel, and X.J. Fan
Excursion to Philips
Assessment Two possibilities of course assessment: 1) participating in real and mini industrial R&D project team, or 2) conducting literature study
WB2408
| Physiological Systems
| ECTS: 3
Responsible Instructor Prof.dr. J. Dankelman ([email protected])Instructor Ir. A.C. van der Eijk ([email protected]), Prof.dr.ir. C.A. Grim- bergen ([email protected])
Contact Hours / Week x/x/x/x
0/4/0/0 Exam Period 2, 3
Course Contents 1. Introduction to human physiology (human body, homeostasis, general organization of the circulatory system).
2. Central nerve system (nerve cells, synapses, sensory system, motor system, autonomic nerve system, reflexes).
3. Mechanics and excitation of the heart (contraction mechanism of cardiac muscle, action potentials).
4. Coronary circulation (control of coronary blood flow, influence of heart contraction on coronary blood flow, effect of stenoses).
5. Cardiac output and Frank-Starling mechanism (regulation, venous return, arterial pressure, pulmonary resistance).
6. Blood rheology and wave phenomena in the circulation (blood cells, blood flow, blood pressure, vascular compliance, clotting, Newtonian flow).
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7. Mass transport (diffusion, convection, osmosis, transport through cell membranes).
8. Kidneys (anatomy, glomerular filtration, reabsorption, regulation of blood volume, artificial kidneys).
9. Arterial pressure regulation (control system, baroreceptors, influence of nerve system, control by renal system).
10. Lungs (respiration, alveoli, transport of oxygen and carbon dioxide, artificial lung).
11. Pregnancy and human development (foetal circulation, oxygen trans- port in utero, umbilical cord, prematurity)
12. Measurement and imaging techniques (ECG, MRI, Röntgen, echo, Doppler, catheters, ultrasound).
13. Modelling of physiological control systems (identification, difficulties). 14. A practical course on Cell Physiology at LUMC.
Education Method 2 times per week 2 lectures of 45 minutes 1 excursion to Leiden University Medical Centre Literature and Study
Materials
Course material:
- Reader: 'Physiological Systems'
by J. Dankelman, C.A. Grimbergen, J.A.E. Spaan. - Powerpoint slides of lectures
Optional: - E.N. Marieb
Human Anatomy & Physiology 6th edition
Pearson; Benjamin-Cummings ISBN: 0321204131 - A.C. Guyton, J. E. Hall Textbook of Medical Physiology 11th Edition W B Saunders Co ISBN: 9780721602400 - W. Boron, E. Boulpaep Medical physiology Revised edition W B Saunders Co ISBN: 9781416023289 Assessment Written exam
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WB2414-09
| Mechatronic System Design
| ECTS: 4
Responsible Instructor Prof.ir. R.H. Munnig Schmidt ([email protected]) Contact Hours / Weekx/x/x/x 2/2/0/0 Exam Period 2, 3 Expected prior
knowledge
Bsc Mechanical Engineering, Electrical Engineering or Physics. Basic knowledge on electromagnetism, electricity, electronics, control and signal theory is very adviseable.
The most important aspect needed is the talent to match theory with practice. Translate a real system into a dynamic model and vice versa. Understand what a position control system really does. Observe a system top-down. Starting with a global overview and approximate calculations by hand and only as a last step calculate the details with the help of a (finite element) computer program.
Course Contents Mechatronic system design deals with the design of controlled motion systems by utilizing a multitude of disciplines. It starts with thinking how the required function of a machine can be achieved by utilizing its diffe- rent subsystems following a systems Engineering approach (V-model). Some supporting disciplines are not originally the working area of mecha- nical engineers like electronics, electromechanics and optics. This course aims to connect these disciplines to realise an optimally designed system. The target application of controlled motion systems explicitly includes the controlling of any movement ranging from perfectly standing still, slow motion precision manipulators to high speed applications with extreme precision to sub nm level.
Based on practical cases ranging from CD drives , active car suspension systems to waferscanners the following subjects will be dealt with.
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System design breakdown into subsystems and elements Mechatronic motion system characteristics
Dynamic behaviour in the time and frequency domain of actively controlled motion systems.
Transfer functions and position control(feedback,PID and feedforward). Vibration isolation
Electromechanical Actuators Active bearings
Analog electronics, operational amplifiers and power electronics used for driving actuators
Although embedded sofware is very relevant in mechatronic systems only limited attention will be given to the subject.
Education Method Lectures around practical mechatronic systems.
The theoretical part will concentrate on those supporting disciplines that are underexposed in the Bsc curriculum
The following disciplines are important aspects:
Dynamics, electronics, electromechanics, control engineering, dynamic error budgetting.
While these disciplines mostly are dealt with in separate specialized courses, in this course the mutual relationship in the application in controlled motion systems is the central theme.
Literature and Study Materials
A reader is in concept published on blackboard.
When possible in time it will be made available in printed form. The presentations will also be published on blackboard Assessment Written Examination (Closed book)
WB4438-05
| Technology and Sustainability
| ECTS: 3
Responsible Instructor Prof.dr.ir. A.H.M. Verkooijen ([email protected]) Contact Hours / Weekx/x/x/x 0/4/0/0 Exam Period 2, 3
Course Contents The course has been completely renewed and presents the world of energy on the basis of fact sheets, figures and tables. The following subjects are treated:
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Course Contents (continued)
Energy in our society: relation between energy, economy, environment and sustainability - Illustration of sustainability with examples Fundamentals and definitions of energy economy and conversion: forms of energy, thermodynamics like 1st and 2nd law, exergy, entropy, Carnot cycle, energy balances,
Energy supply and consumption in the world and in NL Fossil and renewable energy resources
Energy economics: static, dynamic cost calculation, calculation of electri- city production costs
Exploration and production of fossil fuels: exploration of oil and gas, oil and gas production technologies, surface and underground coal mining Nuclear energy conversion: physical principles of fusion and fison, nuclear power station technologies, safety aspects
Heat and power from fossil fuels: combustion and steam generation, coal fired steam power plant, gas turbine and combined cycles, combined cycles for solid fuels, fuel cells, combined heat and power, household heating systems, heat pumps, use of energy in the steel industry Renewable energy technologies: solar thermal, solar power, wind, water, biomass
Environmental aspects: targets for CO2 reduction, possibilities for imple- mentation, CO2 reduction and separation technologies, possibilities for disposal of CO2, NOx emissions, SO2 emissions, particulates, hydrocar- bons
Education Method Lectures Literature and Study
Materials
Lecture notes and sheets Prerequisites none
Assessment Written
WI4052
| Risk Analysis
| ECTS: 6
Responsible Instructor D. Kurowicka ([email protected]) Contact Hours / Week
x/x/x/x 2/2/0/0 Exam Period 2, 3 Expected prior
knowledge
Basic Probability and Statistics
Course Contents Risk modelling, life distributions, event trees, fault trees, reliability diagrams, reliability data bases, dependence modelling, software reliabi- lity, human error, decision-making under risk.
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Literature and Study Materials
Probabilistic Risk Analysis, Bedford & Cooke, Cam.U. press, 2001. Assessment Written.