Electronic Instrumentation Electronic Instrumentation Systems

By the end of this content area, students will be able to have: 1. A coherent knowledge of their branch of engineering including some at the forefront of the branch in optoelectronic instrumentation. 2. The ability to apply their knowledge and understanding of optoelectronic instrumentation to identify, formulate and solve engineering problems using established methods. 3. The ability to apply their knowledge and understanding to develop and realise designs to meet defined and specified requirements. 4. An understanding of design methodologies, and an ability to use them in the design of optoelectronic systems. 5. The ability to design and conduct appropriate experiments, interpret the data and draw conclusions. 6. Workshop and laboratory skills. 7. The ability to select and use appropriate equipment, tools and methods. 8. The ability to combine theory and practice to solve problems of optoelectronic instrumentation. 9. An understanding of applicable techniques and methods in optoelectronic instrumentation, and of their limitations.

1. Introduction to light. Basic magnitudes. Basic laws of optics 2. Optical sources. Semiconductor devices. Electronic circuits. VLC systems 2.1 Working principle of optical emitters based on semiconductors; Energy bands. Absorption, emission processes spontaneous and stimulated emission 2.2 Types of optical emitters: LED and LASER. Comparison of basic characteristics. Efficiencies 2.3 Electrooptic characteristic curves; Optical power-current curve; Spectral response curve. Bandwidth; Operation dependence on temperature 2.4 Application circuits 2.5 LED-based VLC systems: basic principles 2.6 Mono and multicarrier modulations 2.7 Applications in different environments: vehicles, infoentretainment, etc. 3. Photodetectors and optocouplers. Electronic conditioning circuits 3.1 Absorption process in sc. Principle of operation of photodetectors 3.2 Types of photodetectors: p-n, pin, APD, phototransistors 3.3 Responsivity and efficiency. Spectral and E/O characteristic curves 3.4 Concept of noise in photodetectors: types and evaluation 3.5 Conditioning circuits in photodetectors 4. Electro-optical materials, optical and electrical properties. Devices. Applications 4.1 Electro-optical effects on radiation / matter interaction 4.2 E / O materials: Liquid crystals, Electrochromic and Electrophoretic. Operating principles and characteristic E/O curves 4.3 Electrical equivalent circuits. 4.4 Applications: sensing, privacy control, communications, biomedical, etc. 5. Propagation of light. Optical Fibers: Attenuation and Dispersion 5.1 Propagation in guided media: wave equation 5.2 Characteristic parameters F.O: Singlemode and multimode fibers 5.3 Attenuation in F.O. Communications windows 5.4 Dispersion in F.O.: intermodal, chromatic and PMD 5.5 Bandwidth 6. Optical sensors and fiber optic sensors. Applications 6.1 Introduction. General characteristics of optical sensors. 6.2 Types of sensors depending on the magnitude: T, pressure, stress, etc. 7. Optoelectronic instrumentation systems in industrial applications. 7.1 Basic components of instrumentation systems 7.2 S.I. for applications in environment, space, etc.

The teaching methodology will include: - Theoretical-practical classes where the knowledge that students must acquire will be presented. The students will have at their disposal the class notes and will have basic reference texts to facilitate the follow-up of the classes and the development of the subsequent work. - Problem classes, in which the problems proposed to the students are developed and discussed. - Laboratory practices where the student analyses, implements and measures characteristic parameters of electronic circuits of real application, using instrumentation and measurement techniques in the laboratory. - Tutorials. Individual assistance (individual tutorials) or group (collective tutorials) to students by the teacher. - Individual or group work of the student