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Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description _____________________________________________________________________________________________________________
Subject Title: Analysis of Biomedical Data
Scientific Area: Mathematics
Course: Master Course in Biomedical Instrumentation
Code: 664801
Year/Semester: 1º/1st
ECTS: 6
Department: Physics and mathematics
Instructor: Maria Filomena Palmeira de Araújo Canova (MSc), Luís Manuel Margalho (MSc)
Study plan: Introduction
Study Design on health research
Descriptive and Analytical Studies
Diagnostic Tests and clinical trial measurements
Statistical tests
Statistical Modeling. Regression
Longitudinal Analysis
Survival Analysis
Software for statistical analysis
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2
Theoretical-Practical
28 2
Practical
Tutorial guidance
Learning objectives:
The main goal is to present statistical methods applied to health sciences, with emphasis on statistical modeling and survival analysis
Generic learning outcomes and competences:
Students should be able to understand and apply statistical techniques to biomedical data analysis, in order to support clinical research.
Bibliography: Notes from lectures and Worksheets.
Giolo S.R., Colosimo E.A., Análise de Sobrevivência Aplicada. Editora Edgard Blucher Ltda, São Paulo, 2006.
Gouveia de Oliveira, Bioestatística, Epidemiologia e Investigação. Teoria e Aplicações, 2009, Lidel.
Wayne W. Daniel, Bioestatística: A Fundação para a Análise em Ciências da Saúde, 9ª edição, 2009, Wiley.
D. Chen, K. Peace, “Clinical Trial Data Analysis Using R”, Chapman & Hall.
Master in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description __________________________________________________________________________________________________________________
Subject Title: MAINTENANCE OF EQUIPMENTS AND FACILITIES
Scientific Area: ELECTROTECHNICAL ENGINEERING
Course: 6648 - Master in Biomedical Instrumentation
Code: 664812 - MAINTENANCE OF EQUIPMENTS AND FACILITIES
Year/Semester: Second year / first semester
ECTS: 6
Department: Department of Electrical Engineering
Instructor: Inácio Fonseca
Study plan: Reliability theory; Maintenance; Park organization; Electrical Power Quality; Fault diagnosis; Inspection equipment’s; electrical protection devices.
Language: Portuguese ((English if foreign students are attending the course))
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Classroom
Theoretical-
Practical 26 2 Classroom / Laboratory
Practical -- -- 2 hours for Seminar
Tutorial
guidance -- --
Students have weekly support
through the office hours of teachers
Learning objectives:
Understand and implement techniques of organization and management of an industrial maintenance department; Perform audits to diagnose the status of maintenance service; Know how to organize an equipment park; Develop and implement machinery and equipment maintenance plans; Perform the management of internal and subcontracted work; Apply fault diagnostic techniques; Assess the costs and maintenance time; Develop and monitor the maintenance control indicators;
Generic learning outcomes and competences:
Reliability theory (distributions, series and parallel circuits, main reliability indicators). Corrective, periodic and predictive maintenance and Maintenance planning. Inspection equipment (noise, vibration, thermography and tribology). Quality power supply. Systems / electrical protection devices. Uninterrupted electric supply. Basic techniques of fault diagnosis in the power supply of electrical equipment. Maintenance of structured cabling networks (Ethernet) of electrical and computer equipment. Seminar: to perform on one of the above syllabus.
Bibliography: FERREIRA, Luís Andrade - Uma Introdução à Manutenção, Publindústria, Porto, 1998. ISBN: 972-95794-4-X ASSIS, Rui - Manutenção Centrada na Fiabilidade, Lidel, Lisboa, 1997. ISBN: 972-757-037-2
Progress assessment:
Written exam quoted for 12 values. Practical work for 8 values.
Coimbra Institute of Engineering Course Unit Description
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Subject Title: Support Technology for Persons with Special Needs
Scientific Area: Electrical Engineering
Course: Master’s Degree in Biomedical Instrumentation
Code: 664811
Year/Semester: 2nd year / 1st semester
ECTS: 6
Department: Electrical Engineering
Instructor: Frederico Miguel do Céu Marques dos Santos Study plan:
Language: Portuguese Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 1 14
Theoretical-Practical
Practical 3 40
Tutorial guidance
Seminar 2
Learning objectives:
The vast majority of people with special needs are affected its capacity to a greater or lesser degree, in four main areas: communication, mobility, manipulation and orientation.
Generic learning outcomes and competences:
Knowledge about the use of assistive technologies requires, on the one hand, the understanding of their more technical aspects (technical components), and on the other a deep knowledge of the human being who will use the technology (human components) as well as contested needs the physical and economic environment in which it operates (socio-‐economic components).
Bibliography: • F. Moita, R. Oliveira, V. Santos, and M. Silva, “EyeSEC Project, Development of Interfaces for impaired users”, 10th Portuguese-‐Spanish Congress in Electrical Engineering-‐XCLEEE, Portugal, July 2011 • G. Matos, M. Ferreira, T. Neves, Relatório de Projecto, orientação F. Moita, “Bengala para deficientes audiovisuais”, ISEC 1997 • M. Carvalho, N. Ribeiro, Relatório de Projecto, orientação F. Moita, “Sistema Multimédia em PDA para apoio à comunicação de doentes com Afasia”, ISEC 2005 • R. Oliveira, A. Ferreira, F. Gaspar, Relatório de Projecto, orientação F. Moita, “EyeSEC Project – Technology for Disabled People”, ISEC 2010 • Relatório de Projecto, orientação F. Moita e M. Silva, “Instrumentação de Cadeira de Rodas Eléctrica com sensores de Ultra-‐sons, Laser e GPS”, ISEC 2011 • Relatório de Projecto, orientação F. Ferreira, “SAM – Sistema de Accionamento de Membros Protésicos”, ISEC 2011 • http://en.wikipedia.org/wiki/Assistive_technology
Coimbra Institute of Engineering Course Unit Description
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Progress assessment:
The evaluation consists of three components: • Lectures: Evaluation by final exam. Accessible to all students who pass the laboratory component. The exam has a weight of 6 points, with a minimum of 3. • Research: Presentation and discussion of an article in an international scientific journal of the area or alternatively to submit a detailed and current view of the technologies available for the following areas: communication, mobility, manipulation and orientation. This work has a final weight of 6 points. • Laboratory Project: Preparation, execution and reporting of a laboratory project, with a final weight of 8 points with a minimum of 4 points.
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description
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Subject Title: Information Systems in Healthcare
Scientific Area: Information Systems and Technologies for Health
Course: Masters in Biomedical Instrumentation
Code: 664810
Year/Semester: 1º year/2ºsemester
ECTS: 3
Department: Escola Superior Tecnologia da Saúde de Coimbra / Coimbra Health School
Instructor: António Manuel Rodrigues Carvalho Santos (PhD)/ Joana Margarida Santos (PhD)
Study plan: Patient data flow in a healthcare: • Diagnostic and therapeutically procedures; • The diagnosis/therapy cycle and is relationship with information systems; • The use of informatics in health; • Clinical records in paper and electronic; • Information systems in health care (primary health care and hospitals); • Characteristics of information systems dedicated to use by different health
professionals; • Systems to support clinical decision; • Technologies and existing information systems and its language; • Information networks operation; • File systems and availability of medical images; Telemedicine and e-health • Introduction and definitions • Telecommunications in care • Current Applications • Evolution of telemedicine to e-health • Examples of clinical applications and their benefits • Some problems with e-health • Privacy and confidentiality • Security and Data Integrity • Legal and ethical aspects
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2
Theoretical-
Practical
Practical 28 2
Tutorial
guidance
Learning objectives:
Knowledge and understanding of the importance of information systems to diagnosis and therapeutic decision cycle. knowledge and understanding health information systems. Know and understand the aspects of telemedicine and e-health, including the evolution, applications and benefits.
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description
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Knowledge and perception of the information systems impact, clinical research and management in healthcare.
Generic learning outcomes and competences:
Analyse the health information systems and the associated technologies in clinical and research context. Evaluate and follow a procedure since the patient is registered on the
computer system of the health institution until the distribution and storage of information. Put into practice the safety standards on data manipulation in health. To know the telemedicine and e-health procedures as requirements.
Bibliography: Laudon, K. et al. (2006). Management information systems: managing the digital firm. Upper Saddle River: Prentice-Hall, Inc.Spackman K., & Elevitch, F. (2004). Standardization of clinical terminology to support information technology in health. Business Briefing: Global Healthcare - Advanced Medical Technologies. Disponível em: http://www.touchbriefings.com/pdf/950/spackman_book.pdf RCR. (2008). Radiology information systems. London: The Royal College of Radiologists. Disponível em: http://www.rcr.ac.uk/docs/radiology/pdf/IT_guidance_RISApr08.pdf Pressman, R. S. (2010). Software engineering: a practitioner's approach (7th ed.). New York: McGraw-Hill Higher Education. Pereira, A., Giest, S., Dumortier, J., & Artmann, J. (2010). eHealth strategies, country brief: Portugal. Disponível em: http://ehealth- strategies.eu/database/documents/Portugal_CountryBrief_eHStrategies.pdf Langley, J., & Beasley, C. (2007). Health information technology for improving quality of care in primary care settings: Agency for Healthcare Reseach and Quality. Disponível em: http://praxisinformatik.ch/cd/Daten/fileadmin/Kundendaten/Allgemein/Literatur/AHR Q_HIT_Primary_Care_July07.pdf Kushniruk, A. W., Borycki, E. M., Kuwata, S., & Kannry, J. (2011). Emerging approaches to usability evaluation of health information systems: towards in-situ analysis of complex healthcare systems and environments. Stud Health Technol Inform, 169, 915-919. Disponível em: http://www.ncbi.nlm.nih.gov/pubmed/21893879 DICOM. (2012). DICOM Strategic Document. ACSS. (2011). Classificação internacional de cuidados de saúde primários: Administração Central do Sistema de Saúde. Disponível em: http://www.acss.min-
saude.pt/Portals/0/apmcg_ICPC%20v%201.7.pdf Plano Nacional de Saúde 2011-2016 “Tecnologias de Informação e Comunicação” Disponível em: http://www.dgs.pt
Progress assessment:
For the purposes of exploitation in the course the student can choose to do: -Continuous assessment: the student in this type of assessment can choose one of two methods: Method A
- Oral presentation and discussion of a scientific paper (15min), selected from the list of topics proposed by the teacher performed individually.
- Oral presentation and discussion of a working group (2 students - 20 min) with a theme proposed by the students in the framework of UC.
The calculation of the final grade will be held according to the following parameters: - Oral presentation and discussion of a scientific paper - weighting 0.6 - Oral presentation and discussion of a working group - weighting 0.4
Method B - Examination with written component and oral (on the same day); -Non continuous assessment - Examination with written and oral component. Students of special procedures should informed the Professors at the first class in order to define its evaluation methodology, according to the Portuguese law and recommendations.
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description
Subject Title: Biomedical Signal and Image Processing
Scientific Area: Electrical Engineering
Course: Master Course in Biomedical Instrumentation
Code: 664809
Year/Semester: 1st / 2nd
ECTS: 7
Department: Electrical Engineering
Instructor: Fernando Lopes, PhD; Helena Marto, MSc; Verónica Vasconcelos, MSc
Study plan: Part I – Signal Processing Fourier Series; Fourier Transform; Signal sampling, decimation and interpolation; Z Transform; Wavelet Transform; Signal conditioning and noise reduction; Digital Filters; Stochastic Processes. Part II – Image Processing Computer-Assisted Diagnosis - Introduction to Picture Archiving and Communication Systems (PACS) and the Digital Imaging and Communications in Medicine (DICOM) standard. - Main characteristics and features of Computer-Aided Diagnostic Systems (CAD) - Architecture of a CAD System - Commercial CAD Systems Image Processing for CAD - Image and colour space representation - Methodologies: pre-processing, segmentation, feature extraction and selection, biomedical image classification; - Performance evaluation - Applications
Language: Portuguese and English
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Classroom, Lectures
Theoretical-
Practical
Practical 42 3 Classroom, Laboratory Work
Tutorial
guidance
Learning objectives:
The main aims of this course unit are: - To understand the main concepts and theoretical knowledge in the signal processing area, more specifically the digital signal processing, most commonly used in the processing of biomedical signals. To apply this knowledge to various biomedical signals such as EEG and ECG.
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description
- To know the principles of Computer Aided Diagnosis (CAD) systems and the DICOM standard. - To understand the principles and know the main image processing techniques that allow the student to development of methodologies for processing, analysis and classification of biomedical images, with application in the development of CAD systems.
Generic learning outcomes and competences:
At the end of this course unit the learner is expected to be able to: - Using computational tools, utilize signal processing techniques applied to biomedical signals, within the diagnosis, therapy, rehabilitation and research fields. - develop and implement techniques for processing, analysis and classification of biomedical images, with application in the development of CAD systems.
Bibliography: - Lecture slides - E. N. Bruce, Biomedical Signal Processing and Signal Modeling, John Wiley & Sons, 2000 - K. Najarian ; R. Splinter, Biomedical Signal and Image Processing, Taylor & Francis, 2006 - J. L. Semmlow, Biosignal and Medical Image Processing, Second Edition (Signal Processing and
Communications), CRC Press, 2008 - A. V Oppenheim; R. W Schafer, Digital Signal Processing. Ohio: Prentice Hall, 2001 - DICOM: http://medical.nema.org/standard.html - R. C. Gonzalez, R. E. Woods, Digital image processing, Pearson/Prentice Hall, 3rd Ed., 2008 - Gonzalez, R. C., R. E. Woods, et al. (2004). Digital Image Processing Using MATLAB, Prentice
Hall. - Guyon, I. (2006). Feature extraction: foundations and applications, Springer. - Duda, R. O., P. E. Hart, et al. (2001). Pattern Classification, 2nd ed. New York, NY: John Wiley
and Sons.
Progress assessment:
Final written exam (60%); Two laboratory projects (40%).
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation
Course Unit Description
Subject Title: Robotic Systems
Scientific Area: Electrical Engineering
Course: Master in Biomedical Instrumentation
Code: 664808
Year/Semester: 1st / 2nd
ECTS: 6
Department: Department of Electrical Engineering
Instructor: João Paulo Morais Ferreira, PhD; Fernanda Madureira Coutinho , PhD.
Study plan: 1. Introduction to Robotics 2. Main configurations of robots 3. Fundamentals of robotics 4. Sensors for industrial robots 5. Safety systems for the protection of robotic cells 6. Teleoperation and telepresence 7.Paths planning 8. Mobile robotic systems 9. Robots programming languages 10. Simulation tools for robotics systems
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Classroom, Lectures
Theoretical-
Practical
Practical 26 2 Classroom, Laboratory work
Seminar 2 Specific topic industrial seminar
Tutorial
guidance
Students have weekly voluntary support through instructor’s office hours (6 hours availability, overall)
Learning objectives:
This course on Robotic Systems aims to provide students with an overview of issues and technologies involved in designing and implementing robots in industrial systems. Students examine and evolve on the understanding of these topics through the implementation of real systems.
Generic learning outcomes and competences:
At the end of this course unit the learner is expected to be able to: Program robots; Develop control of a existing robot in the robotic simulator; Identify the more adequate robot, safety systems, sensors and tools for different applications. The teaching method is conventional, based on the exposure of the subjects in lectures, problem solving in practical classes and laboratory demonstrations. As basic text book [1] in the bibliography is used. In addition to being an easy reading text, it covers the entire course. Exposure of the topics is preferably carried out in the blackboard. The study of topics is accompanied by laboratory work performed on PC, so students can execute numerous control experiments.
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation
Course Unit Description
Bibliography: 1. Fu, K.-S., Gonzalez, R. C., and Lee, C. S. G. Robotics: Control, Sensing, Vision and Intelligence. McGraw-Hill series in CAD/CAM, robotics and computer vision. McGraw-Hill, 1987. 2 Robotics Industries Association. American national standard for industrial robots and robot systems—Safety requirements, ANSI/RIA R15.06, 1992. 3. John j. Craig, “Introduction to Robotics Mechanics and Control”, Addison-Wesley Publishing Company, 1989. 4. L. Sciavicco. B. Siciliano, ”Modelling and Control of Robot Manipulators”, Springer, ISBN 1-85233-221-2, 2001. 5. Introduction to Robotics Mechanics & Control, John Craig, Addisson-Wesley. 6. Introduction to Robotics, Phillip John Mckerrow. 7. J. Ferreira, Notes of the lectures and practices. 8. Inform manual and Motoman guide.
Progress assessment:
Practical work carried out represents 50% of the final grade. The remaining 50%, result from a written exam. In any of these assessments it is necessary to obtain a rating equal to or higher than 8 (in a scale of 20). There are two opportunities to complete the written exam, 1st call and time of appeal within the time limits set by the Pedagogical Council. Each written test will include theoretical and theoretical-practical questions and will last for 2 hours.
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation Course Unit Description
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Subject Title: Life Support Systems
Scientific Area: Electrical Engineering
Course: Master Course in Biomedical Instrumentation
Code: 664807
Year/Semester: 1st / 2nd
ECTS: 7
Department: Electrical Engineering
Instructor: Victor Daniel Neto dos Santos, PhD; João Cândido Baptista Santos, MSc; Joaquim Alberto Pereira, MSc
Study plan: Introduction to Life Support Systems Basic and advanced life support (BLS and ALS);
Defibrillators and pacemakers Operation principles of and block diagram; Lown and biphasic defibrillators; Transients in RC and RLC circuits, H bridge; Timers in monostable and astavel operation modes (555); Power sources: DC-DC converters; Signal processing: QRS complex detection; Pacemakers: synchronous and asynchronous; block diagram.
Vital signs monitors ECG: Signal conditioning; Arterial blood pressure: invasive and non-invasive methods; Pulse oximetry: SPO2 sensors and technologies; Body Temperature: thermistors (NTC/PTC) and RTD sensors; Pressure sensors: strain Gauge and inductive sensors; Signal conditioning, Wheatstone bridge, Instrumentation amplifier.
Ventilators Fundamentals of respiration; Respiratory physiology; Fundamentals of ventilation; Controlled ventilation (volume and pressure).
Incubators Basic principles of control; Temperature control.
Electromedical Equipment Maintenance Forms of maintenance; Maintenance management; Supporting equipment and tools.
Language: Portuguese (English if foreign students are attending the course)
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation Course Unit Description
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Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Classroom, Lectures
Theoretical-
Practical
Practical 38 3 Classroom, Laboratory work
Seminar 4
Tutorial
guidance
Students have weekly voluntary
support through instructor’s office
hours (6 hours availability, overall)
Learning objectives:
The main aims of this course unit are: To understand defibrillators operation and its main block diagrams; To understand RC and RLC transients in order to design Lown and biphasic defibrillators; To understand and design timer circuits; To understand the underling theory and sensor technology needed to obtain the vital signals monitoring: ECG; arterial blood pressure (IBP and NiBP), SpO2 and corporal temperature; To understand the operation principles of the most common ventilators.
Generic learning outcomes and competences:
The course aims to provide training and specific knowledge in the area of electrical engineering underlying the operation of support equipment and support for life. It is intended that students acquire fundamental knowledge regarding the design, implementation and maintenance of such equipment. Furthermore, it is encouraged on students R&D activities, which result on the proposal of new approaches, topologies, circuits devoted to the analyzed devices in comply with the laws and safety regulation.
Bibliography: • Joseph D. Bronzino, The Biomedical Engineering Handbook: Second Edition, .2 Volume Set, CRC Press 1999. • John G. Webster, Medical Instrumentation Application and Design, 4th edition, Wiley 2010. • Anthony W C Chow, Alfred E Buxton, Implantable Cardiac Pacemakers and Defibrillators: All You Wanted to Know, Bmj Publishing Group. • Shakti Chatterjee, Aubert Miller, Biomedical Instrumentation Systems, Cengage Learning; 1 edition 2010. • Robert L. Chatburn, Fundamentals of Mechanical Ventilation: A Short Course on the Theory and Application of Mechanical Ventilators, Mandu Press Ltd, 2003. • Baxter Larmon; Heather Davis; Basic Life Support Skills, Prentice Hall 2004. • J. D. Irwin, R. Mark Nelms, "Basic Engineering Circuit Analysis", 10th ed., Wiley, 2011.
Progress assessment:
Student progress assessment is performed taken into account the score obtained in the exercises, attendance level and final exam grade. The results retrieved from the work developed on the laboratory are also included in the final grade. Final Grade: Exam (50%); Laboratorial works (25%); Final project (25%).
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description ___________________________________________________________________________________________________________
Subject Title: Radiation protection and dosimetry
Scientific Area: Physics
Course: Biomedical Instrumentation (Master)
Code: 664806
Year/Semester: 1st/2nd
ECTS: 7
Department: Physics and Mathematics
Instructor: José António Matias Lopes, PhD
Study plan: Atomic and nuclear physics fundaments; Radioactive sources; Radiation interaction with matter; Dosimetry units; Radiation and dosimetry instrumentation; Radio protection.
Language: Portuguese/English
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Lectures
Theoretical-
Practical - - -
Practical 38 3 Laboratory work
Seminars 4 - -
Learning objectives:
This curricular unit provides theoretical and applied fundamentals on radiation and dosimetry in the context of medical physics and biomedical engineering.
Generic learning outcomes and competences:
Ionizing and non-ionizing radiation: 1) nature, description and quantification; 2) physical and technological origin; 3) absorption and shielding; 4) biological effects; 5) maximum exposure limits.
Bibliography: C. J. Martin, D. G. Sutton (eds.), “Practical Radiation Protection In Health Care”, Oxford University Press, 2002
B. J. Klauenberg, D. Miklavčič, “Radio Frequency Radiation Dosimetry and its Relationship to the Biological Effects of Electromagnetic Fields”, Springer, 2000
A. Vorst, A. Rosen, Y. Kotsuka, “RF/Microwave Interaction with Biological Tissues”, John Wiley & Sons, 2006
IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, WHO, International Agency for Research on Cancer, “Non-Ionizing Radiation: Static and Extremely Low-Frequency (ELF) Electric and Magnetic Fields”, Part 1, IARC Press, Lyon, 2002
Glenn F. Knoll, “Radiation Detection and Measurement”, John Wiley & Sons, 2000
Progress assessment:
The evaluation comprehends: Presence in pratical activities and seminars (5%), seminar report (5%), bibliographical research work (10%), laboratorial work (10%), final exam (70%)
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation
Course Unit Description _____________________________________________________________________________________________________________
Subject Title: COMMUNICATION NETWORKS IN BIOMEDICINE
Scientific Area: Electrical and Electronics Engineering
Course: Master Course in Biomedical Instrumentation
Code: 664805
Year/Semester: 1st Year / 1st Semester
ECTS: 6
Department: Electrical and Electronics Engineering
Instructor: João Perdigoto (MSc)
Study plan: Power budget in guided and wireless transmission systems. Introduction to communication networks. Standardization. OSI model. Ethernet networks technology and equipment. TCP / IP protocols. Configuration of wired and wireless networks with TCP / IP. Wireless sensor networks. Energy budget of wireless sensor networks. Applications of wireless sensor networks: the Zigbee protocol. Introduction to RFID applications. Biomedical applications of networks: body networks. Tracking systems in Hospitals.
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2
Theoretical-
Practical
Practical 28 2 Includes a 2h seminar
Tutorial
guidance
Learning objectives:
To know and understand the technologies available in the market. To choose, design, implement and maintain small communication networks, using commercially available equipment. To choose, design, implement and maintain wireless network communication systems using commercially available equipment. To understand and perform troubleshooting in local networks. To understand and perform troubleshooting in wireless sensor networks.
Generic learning outcomes and competences:
Bibliography: Guang-Zhong Yang, “Body Sensor Networks”, Springer-Verlag Reynders, D., Mackay , S., Wright , E., “Practical Industrial Data Communications”, Newnes Publications E. Monteiro, F. Boavida, “Engenharia de redes informáticas”, FCA - Editora de Informática
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation
Course Unit Description _____________________________________________________________________________________________________________
Lammle, Todd, "CCNA Cisco certified network associate: study guide", Sybex, Spurgeon, C., "Ethernet: the definitive guide", O´Reilly, Geier, Jim, "Wireless Lans: implementing interoperable networks", MacMillan, Shahin Farahani , “Zigbee Wireless Networks and Transceivers”, Eady, F., “Hands-on Zigbee: implementing 802.15.4 with microcontrollers”, Newnes Publications
Progress assessment:
Final exam. Laboratory work and reporting. Synthesis text on the topics covered in the program and / or related content, with individual presentation during the contact hours. Approval for the UC is dependent on obtaining a minimum of 10 (of 20) values, taking into account the following weights:
Final exam – 14 (at least 6);
Labororatory work and report – 4 (at least 2);
Synthesis text – 2.
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation Course Unit Description
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Subject Title: Data Acquisition and Virtual Instrumentation
Scientific Area: Electrical Engineering
Course: Master Course in Biomedical Instrumentation
Code: 664804
Year/Semester: 1 st / 1st
ECTS: 6
Department: Electrical Engineering
Instructor: Victor Daniel Neto dos Santos, PhD; Helena Jorge da Silva Marto, MSc
Study plan: Data Acquisition:
Basic concepts: sampling; aliasing; quantization; quantization noise; etc.
Digital-analog converter (DAC) and Analog-to-digital converter (ADC) - Binary-weighted current ladder DACs; R-2R Ladder; Multiplying DACs. - Flash ADC; successive approximations; counting and integrating ADCs; dual slope ADC, etc.
Signal conditioning - OPAMPS circuits: inverter; non-inverter; adder; integrator; differentiator; difference, etc. - Instrumentation amplifier; common and differential gain; CMRR.
Filters - Filters types and classification; transfer function; analog filters analysis and design; active and passive implementations; Introduction to IIR and FIR digital filters; etc.
Data acquisition boards - Number of digital input channels; resolution; dynamic range; sampling rate; bandwidth, etc.
Electromagnetic compatibility - Eddy current; magnetic interference; - 50 Hz interference suppression including its harmonics.
Virtual Instrumentation / LabVIEW programming principles:
Introduction to LabVIEW: Virtual instrument (vi) components; programming tools, etc.
Implementation of a VI: - Loops; data structures; subroutines; timing; graphs and charts; error handling techniques.
Modular application development – SubVIs
Common Design Techniques and Patterns: - Sequential programming; state programming; state machines; parallelism.
Use of variables: - Local Variables; global variables; functional global variables; race conditions.
Projects in LabVIEW. Labview Synchronization Tools: Notifiers; queues; semaphores.
Event-driven programming.
Coimbra Institute of Engineering Master Course in Biomedical Instrumentation Course Unit Description
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User Interface. File I/O; instrument I/O and communication.
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Classroom, Lectures
Theoretical-
Practical
Practical 28 2 Classroom, Laboratory work
Tutorial
guidance
Students have weekly voluntary
support through instructor’s office
hours (6 hours availability, overall)
Learning objectives:
The main aims of this course unit are: To understand the data acquisition principles including analog-to-digital and digital-analog conversion , signal conditioning and filtering; To understand the underling theory of analogue filters including its analysis and design; To understand the main features associated with the data acquisition boards; To understand the common virtual instrumentation tools; Develop applications using LabView for biomedical signals data acquisition purposes.
Generic learning outcomes and competences:
The course aims to provide training and specific knowledge in the area of Data Acquisition and Virtual Instrumentation. Students must acquire fundamental knowledge regarding the design, implementation and maintenance of such systems. Furthermore, it is encouraged on students R&D activities, in order to develop new solutions, circuits, programs and applications devoted to the biomedical signals analysis and processing.
Bibliography: • S. Sumathi; P. Surekha, LabVIEW based advanced instrumentation systems, Springer, 2007 • John Essik, Hands-on introduction to LabVIEW for scientists end engineers, Oxford University Press,ISBN978-019-537395-0, 2009 • S. Wolf, R. Smith, Student Reference Manual for electronic Instrumentation laboratories, Prentice-Hall International., ISBN 0-13-117605-6, 2004 • Robert H. Bishop, LabVIEW 2009 student edition, Pearson - Prentice Hall, ISBN 978-0-13-214129-1, 2010 • Gary W. Johnson, Richard Jennings, graphical programming, McGraw-Hill, fourth edition ISBN 0-07-145146-3, 2006 • Leonard Sokoloff, Applications in LabVIEW, Pearson - Prentice Hall, 2004.
Progress assessment:
Student progress assessment is performed taken into account the score obtained in the exercises, attendance level and final exam grade. The results retrieved from the work developed on the laboratory are also included in the final grade.
Coimbra Institute of Engineering Master in Biomedical Instrumentation Course Unit Description
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Subject Title: Optical Instrumentation for Diagnostics and Therapeutics
Scientific Area: Physics
Course: Master in Biomedical Instrumentation
Code: 664803
Year/Semester: 1st / 1st
ECTS: 6
Department: Physics and Mathematics
Instructor: Milton Augusto Morais Sarmento Pato de Macedo, PhD
Study plan: 1. Fundamentals of radiometry and photometry; 2. Light Sources; 3. Fiber optics; 4. Detectors; 5. Main Optical Components of Biomedical Optical Instrumentation; 6. Light – Tissue Interaction; 7. Optical Instrumentation for Diagnostics and Therapeutics: some examples and its
operating principles 8. Light Applications for Diagnostics and Therapeutics: study of some specific commercial
instrumentation.
Language: Portuguese (English if foreign students are attending the course)
Type of instruction: Activities Total Hours Hours/week Comments
Theoretical 28 2 Lectures; Seminars/Webinars
Theoretical-
Practical 28 2
Illustrative application examples;
Problem solving;
Practical
Tutorial
guidance
Learning objectives:
To characterize the main components of optical instrumentation: light source (particularly the LASER); fiber optics; light detectors/sensors; other optical and mechanical components frequently used in this type of instrumentation; To depict the main light – tissue interaction mechanisms in order to understand the interface of optical instrumentation with biological tissues ; To know the main types of optical instrumentation used in this application field, their operating principles and the most important features of each type.
Generic learning outcomes and competences:
1. Development of student skills that enable them to an easier integration in work-market (practising the interchanging of ideas and the discussion of problems and solutions and developing a professional attitude in his relation to work); 2. Ability to combine all knowledge in order to face any problem, being able to make their own judgments; 3. Satisfaction in researching as well as in achieving explanations; 4. Ability to communicate in oral and written form the results of their own research as well as the main issues from an attended seminar.
Coimbra Institute of Engineering Master in Biomedical Instrumentation Course Unit Description
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Bibliography: - Lihong v Wang, Hsin-I Wu, Biomedical Optics: Principles and Imaging, John Wiley & Sons, USA, 2007 - Rongguang Liang, Optical design for biomedical imaging, SPIE Press, USA, 2010 - R Splinter and B A Hooper, An introduction to biomedical optics, Taylor & Francis, USA, 2007 - Bahaa E. A. Saleh, MC Teich, Fundamentals of photonics, John Wiley & Sons, USA, 1991 - MV Klein, TE Furtak, Optics, John Wiley & Sons, USA, 1986 - FL Pedrotti, LS Pedrotti, Introduction to optics, 2nd ed, Prentice-Hall International Inc. USA, 1993 - James M. Palmer and Barbara B. Grant, The Art of Radiometry, SPIE Press,USA, 2010 - David W. Ball, Field Guide to Spectroscopy, SPIE Press,USA, 2006 - Rudiger Paschotta, Field Guide to Optical Fiber Technology, SPIE Press,USA, 2010 - Rudiger Paschotta, Field Guide to Lasers, SPIE Press,USA, 2008 - Barbara B. Grant, Field Guide to Radiometry, SPIE Press, USA, 2011 - Joseph D Bronzino Editor, The Biomedical Engineering Handbook – Medical Devices and - Systems, 3rd Edition, Taylor & Francis, USA, 2006; - John G Webster Editor, Medical Instrumentation: Application and Design, 4th Edition, John Wiley & Sons, USA, 2010; - J Enderle, S Blanchard, J Bronzino, Introduction to Biomedical Engineering, 2nd Ed., Elsevier Academic Press, USA, 2005; - Datasheets of commercial devices; - Scientific journals; - Teacher notes (theory, exercises, practical examples).
Progress assessment:
- Final written exam (50%); - Seminar/Webinar report (20%); - Research work (30%).
Coimbra Institute of Engineering
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Master Course in Biomedical Instrumentation
Course Unit Description
Subject Title: Decision Support and Diagnosis Models
Scientific Area: Mathematics
Course: Master Course in Biomedical Instrumentation
Code: 664802
Year/Semester: 1st, 1st
ECTS: 6
Department: Department of Physics and Mathematics
Instructor: Deolinda Maria Lopes Dias Rasteiro, PhD
Study plan: I. Linear programming with one or more goals:
• Models
• Assumptions of linear programming
• Methods of resolution
• Examples
II. Nonlinear Programming:
• Models
• Optimization without constraints to one or more variables
• KKT optimization with nonlinear constraints
• Quadratic Programming
• Separable Programming
• Convex Programming
• Non-convex Programming
III. Network Optimization;
• Terminology and data structure
• Shortest path problem
• Least-cost support tree problem
• Maximum flow problem
• Minimum cost flow problem
• Projects planning and control with PERT-CPM
IV. Support vector machines: • Concepts • Classification of linearly and non-linearly separable patterns • Multi-class classification V. Data Mining • Alternative approaches to knowledge discovery Regression / Classification versus Knowledge Discovery • The methodological process of data mining • Definition of problems and data collection • Preparation and pre-processing data • Decision trees • Neural networks
Language: Portuguese (English if foreign students are attending the course)
Coimbra Institute of Engineering
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Master Course in Biomedical Instrumentation
Course Unit Description
Type of instruction:
Activities Total Hours Hours/week Comments
Theoretical 26+2 2 Classroom, Lectures, 2h seminar
Theoretical-Practical
28 2 Self-Work / Work Group
Practical:
Tutorial guidance
Students have weekly voluntary
support through instructor’s office
hours (6 hours availability, overall)
Learning objectives:
Present the potential of decision support methods and diagnosis in the context of Control, Operations Research, Diagnosis and Management, with particular emphasis on the formulation of decision problems within the Biomedical Engineering and particularly useful tools to optimize solutions.
Generic learning outcomes and competences:
Through the problem formulation / modeling students, based on skills acquired in different modules of the syllabus, will be able to solve the potential problems using the methods that decision support and management and operational research potentiate. Students also gain knowledge that they will be indispensable for understanding the last two chapters. There are databases with vast amounts of information; the use of data mining goes from the display of information to the forecast. We highlight the application in medicine, the diagnostic phase to identify the best therapies, the search for new forms of treatment. With the acquisition of knowledge contained in Chapters IV and V students will be better able to provide, with more certainty, useful information for a diagnosis / treatment. This information will be based, for example, on a function that needs to be determined, which makes the mapping of data into predefined classes (e.g. diagnosis of a given disease from a set of symptoms).
Bibliography: • L. Valadares Tavares, "Operational Research", 1996, McGraw Hill. • F. Hillier, G. Lieberman, "Introduction to Operations Research," 2004, McGraw Hill. • Carlos Henggeler Antunes, Luís Valadares Tavares, (coordinators), Cases of Application of Operations Research, Mc Graw-Hill, 2000. • EQVMartins, MMBPascoal, DMLDRasteiro, JLESantos. The Optimal Path Problem, Operational Research, Vol 19, No 1, June 1999, pp. 43-60. • LORRAINE, A. C., CARVALHO, A. C. P. L. of. Introduction to Support Vector Machines. São Carlos - SP, April 2003. • Hand, D., Mannil, H., Smyth, P., "Principles of Data Mining '. MIT Press. 2001. ISBN 026208290X. • Course Notes TM Enterprise Miner: Applying Data Mining Techniques, SAS Institute. • Support material prepared by the teachers responsible for the course (texts and practical exercises).
Progress assessment:
The problems formulation / modeling have a strong component in the evaluation since from it depends a consistent resolution and consequent decision-making and analysis. Assessment method: • Report with oral discussion of a proposed project by the course’s teachers (may be in a group - maximum of 3 students) - Rating 8 values; • Written exam - 12 rating values.
Master Course in Biomedical Instrumentation
Coimbra Institute of Engineering Course Unit Description _____________________________________________________________________________________________________________
Progress assessment:
Continuous assessment consists of a report with oral discussion of a proposed project (may be in a group -maximum of three students) - Rating 6 values and a final exam - Rating 14 values.
Alternatively, the assessment is made through a final examination (20 values).
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