Suchergebnis: Katalogdaten im Frühjahrssemester 2021

Maschineningenieurwissenschaften Bachelor Information
6. Semester
Fokus-Vertiefung
Biomedizinische Technik
Fokus-Koordinator: Prof. Bradley Nelson
NummerTitelTypECTSUmfangDozierende
151-0515-00LContinuum Mechanics 2W4 KP2V + 1UE. Mazza, R. Hopf
KurzbeschreibungAn introduction to finite deformation continuum mechanics and nonlinear material behavior. Coverage of basic tensor- manipulations and calculus, descriptions of kinematics, and balance laws . Discussion of invariance principles and mechanical response functions for elastic materials.
LernzielTo provide a modern introduction to the foundations of continuum mechanics and prepare students for further studies in solid
mechanics and related disciplines.
Inhalt1. Tensors: algebra, linear operators
2. Tensors: calculus
3. Kinematics: motion, gradient, polar decomposition
4. Kinematics: strain
5. Kinematics: rates
6. Global Balance: mass, momentum
7. Stress: Cauchy's theorem
8. Stress: alternative measures
9. Invariance: observer
10. Material Response: elasticity
SkriptNone.
LiteraturRecommended texts:
(1) Nonlinear solid mechanics, G.A. Holzapfel (2000).
(2) An introduction to continuum mechanics, M.B. Rubin (2003).
151-0540-00LExperimentelle MechanikW4 KP2V + 1UJ. Dual, T. Brack
Kurzbeschreibung1. Allgemeines: Messkette, Frequenzgang, Schwingungen und Wellen in kontinuierlichen Systemen, Modalanalyse, Statistik, Digitale Signalanalyse, Phasenregelkreis 2. Optische Methoden 3. Piezoelektrizität 4. Elektromagnetische Erzeugung und Messung von Schwingungen und Wellen 5. Kapazitive Messaufnehmer
LernzielVerständnis, quantitative Modellierung und praktische Anwendung von experimentellen Methoden zur Erzeugung und Messung von mechanischen Grössen (Bewegung, Deformation, Spannungen)
Inhalt1. Allgemeines: Messkette, Frequenzgang, Frequenzgangmessung, Schwingungen und Wellen in kontinuierlichen Systemen, Modalanalyse, Statistik, Digitale Signalanalyse, Phasenregelkreis 2. Optische Methoden (Akustooptische Modulation, Interferometrie, Holographie, Spannungsoptik, Schattenoptik, Moiré Methoden) 3. Piezoelektrische Materialien: Grundgleichungen, Anwendungen Beschleunigungsaufnehmer, Verschiebungsmessung) 4. Elektromagnetische Erzeugung und Messung von Schwingungen und Wellen 5. Kapazitive Messaufnehmer, Praktika und Uebungen
Skriptja
Voraussetzungen / BesonderesVoraussetzungen: Mechanik I bis III, Physik, Elektrotechnik
151-0630-00LNanorobotics Information W4 KP2V + 1US. Pané Vidal
KurzbeschreibungNanorobotics is an interdisciplinary field that includes topics from nanotechnology and robotics. The aim of this course is to expose students to the fundamental and essential aspects of this emerging field.
LernzielThe aim of this course is to expose students to the fundamental and essential aspects of this emerging field. These topics include basic principles of nanorobotics, building parts for nanorobotic systems, powering and locomotion of nanorobots, manipulation, assembly and sensing using nanorobots, molecular motors, and nanorobotics for nanomedicine.
151-0641-00LIntroduction to Robotics and Mechatronics Information Belegung eingeschränkt - Details anzeigen
Number of participants limited to 45.

Enrollment is only valid through registration on the MSRL website (Link). Registrations per e-mail is no longer accepted!
W4 KP2V + 2UB. Nelson, N. Shamsudhin
KurzbeschreibungThe aim of this lecture is to expose students to the fundamentals of mechatronic and robotic systems. Over the course of these lectures, topics will include how to interface a computer with the real world, different types of sensors and their use, different types of actuators and their use.
LernzielAn ever-increasing number of mechatronic systems are finding their way into our daily lives. Mechatronic systems synergistically combine computer science, electrical engineering, and mechanical engineering. Robotics systems can be viewed as a subset of mechatronics that focuses on sophisticated control of moving devices.

The aim of this course is to practically and theoretically expose students to the fundamentals of mechatronic and robotic systems. Over the course of the semester, the lecture topics will include an overview of robotics, an introduction to different types of sensors and their use, the programming of microcontrollers and interfacing these embedded computers with the real world, signal filtering and processing, an introduction to different types of actuators and their use, an overview of computer vision, and forward and inverse kinematics. Throughout the course, students will periodically attend laboratory sessions and implement lessons learned during lectures on real mechatronic systems. By the end of the course, you will be able to independently choose, design and integrate these different building blocks into a working mechatronic system.
InhaltThe course consists of weekly lectures and lab sessions. The weekly topics are the following:
0. Course Introduction
1. C Programming
2. Sensors
3. Data Acquisition
4. Signal Processing
5. Digital Filtering
6. Actuators
7. Computer Vision and Kinematics
8. Modeling and Control
9. Review and Outlook

The lecture schedule can be found on our course page on the MSRL website (Link)
Voraussetzungen / BesonderesThe students are expected to be familiar with C programming.
151-0946-00LMacromolecular Engineering: Networks and GelsW4 KP4GM. Tibbitt
KurzbeschreibungThis course will provide an introduction to the design and physics of soft matter with a focus on polymer networks and hydrogels. The course will integrate fundamental aspects of polymer physics, engineering of soft materials, mechanics of viscoelastic materials, applications of networks and gels in biomedical applications including tissue engineering, 3D printing, and drug delivery.
LernzielThe main learning objectives of this course are: 1. Identify the key characteristics of soft matter and the properties of ideal and non-ideal macromolecules. 2. Calculate the physical properties of polymers in solution. 3. Predict macroscale properties of polymer networks and gels based on constituent chemical structure and topology. 4. Design networks and gels for industrial and biomedical applications. 5. Read and evaluate research papers on recent research on networks and gels and communicate the content orally to a multidisciplinary audience.
SkriptClass notes and handouts.
LiteraturPolymer Physics by M. Rubinstein and R.H. Colby; samplings from other texts.
Voraussetzungen / BesonderesPhysics I+II, Thermodynamics I+II
151-0980-00LBiofluiddynamicsW4 KP2V + 1UD. Obrist, P. Jenny
KurzbeschreibungIntroduction to the fluid dynamics of the human body and the modeling of physiological flow processes (biomedical fluid dynamics).
LernzielA basic understanding of fluid dynamical processes in the human body. Knowledge of the basic concepts of fluid dynamics and the ability to apply these concepts appropriately.
InhaltThis lecture is an introduction to the fluid dynamics of the human body (biomedical fluid dynamics). For selected topics of human physiology, we introduce fundamental concepts of fluid dynamics (e.g., creeping flow, incompressible flow, flow in porous media, flow with particles, fluid-structure interaction) and use them to model physiological flow processes. The list of studied topics includes the cardiovascular system and related diseases, blood rheology, microcirculation, respiratory fluid dynamics and fluid dynamics of the inner ear.
SkriptLecture notes are provided electronically.
LiteraturA list of books on selected topics of biofluiddynamics can be found on the course web page.
376-0022-00LImaging and Computing in Medicine Information Belegung eingeschränkt - Details anzeigen W4 KP3GR. Müller, C. J. Collins
KurzbeschreibungImaging and computing methods are key to advances and innovation in medicine. This course introduces established fundamentals as well as modern techniques and methods of imaging and computing in medicine.
Lernziel1. Understanding and practical implementation of biosignal processes methods for imaging
2. Understanding of imaging techniques including radiation imaging, radiographic imaging systems, computed tomography imaging, diagnostic ultrasound imaging, and magnetic resonance imaging
3. Knowledge of computing, programming, modelling and simulation fundamentals
4. Computational and systems thinking as well as scripting and programming skills
5. Understanding and practical implementation of emerging computational methods and their application in medicine including artificial intelligence, deep learning, big data, and complexity
6. Understanding of the emerging concept of personalised and in silico medicine
7. Encouragement of critical thinking and creating an environment for independent and self-directed studying
InhaltImaging and computing methods are key to advances and innovation in medicine. This course introduces established fundamentals as well as modern techniques and methods of imaging and computing in medicine. For the imaging portion of the course, biosignal processing, radiation imaging, radiographic imaging systems, computed tomography imaging, diagnostic ultrasound imaging, and magnetic resonance imaging are covered. For the computing portion of the course, computing, programming, and modelling and simulation fundamentals are covered as well as their application in artificial intelligence and deep learning; complexity and systems medicine; big data and personalised medicine; and computational physiology and in silico medicine.
The course is structured as a seminar in three parts of 45 minutes with video lectures and a flipped classroom setup: in the first part (TORQUEs: Tiny, Open-with-Restrictions courses focused on QUality and Effectiveness), students study the basic concepts in short video lectures on the online learning platform Moodle. At the end of this first part, students are able to post a number of questions in the Moodle forum or directly in the comments section of the video lecture that will be addressed in the second part of the lectures using a flipped classroom concept. For the flipped classroom, the lecturers may prepare additional teaching material to answer the posted questions and potentially discuss further questions (Q&A). Following the Q&A, the students will form small groups to acquire additional knowledge using online, interactive activities or additionally distributed material and discuss their findings in teams. Learning outcomes will be reinforced with weekly Moodle assignments, to be completed during the flipped classroom portion.
SkriptStored on Moodle.
Voraussetzungen / BesonderesLectures will be given in English.
376-0210-00LBiomechatronics
Primär für Gesundheitswissenschaften und Technologie Studierende ausgelegt.

Die Biomechatronics Vorlesung ist nicht für Studierende geeignet, welche bereits die Vorlesung "Physical Human-Robot Interaction"(376-1504-00L) besucht haben, da sie ähnliche Themen abdeckt.

Matlab Kenntnisse sind vorteilhaft -> online Tutorial Link
W4 KP3GR. Gassert, N. Gerig, O. Lambercy, P. Wolf
KurzbeschreibungDevelopment of mechatronic systems (i.e. mechanics, electronics, computer science and system integration) with inspiration from biology and application in the living (human) organism.
LernzielThe objective of this course is to give an introduction to the fundamentals of biomechatronics, through lectures on the underlying theoretical/mechatronics aspects and application fields. In the exercises, these concepts will be intensified and trained on the basis of specific examples. The course will guide students through the design and evaluation process of such systems, and highlight a number of applications.

By the end of this course, you should understand the critical elements of biomechatronics and their interaction with biological systems, both in terms of engineering metrics and human factors. You will be able to apply the learned methods and principles to the design, improvement and evaluation of safe and efficient biomechatronics systems.
InhaltThe course will cover the interdisciplinary elements of biomechatronics, ranging from human factors to sensor and actuator technologies, real-time signal processing, system kinematics and dynamics, modeling and simulation, controls and graphical rendering as well as safety/ethical aspects, and provide an overview of the diverse applications of biomechatronics technology.
SkriptSlides will be distributed through moodle before the lectures.
LiteraturBrooker, G. (2012). Introduction to Biomechatronics. SciTech Publishing.
Riener, R., Harders, M. (2012) Virtual Reality in Medicine. Springer, London.
Voraussetzungen / BesonderesNone
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