Biomedical Measurement Transducers for Internet of Things

Major: Biomedical Engineering (Internet of Things)
Code of subject: 6.163.03.E.051
Credits: 4.00
Department: Electronics and Information Technology
Lecturer: Roman Holyaka
Semester: 6 семестр
Mode of study: денна
Learning outcomes: By the end of the study, learners are expected to: - comprehend basics of concepts Internet of Everything (IoE),Web of Things (WoT), Internet of Things (IoT), Industrial Internet of Things (IIoT), Smart Environments (SE), Smart Home (SH), Augment Reality (AR), Smart Dust (SD), Telemedicine (TM); - know basics of structure and design of IoT and IIoT electronic devices, embedded system , smart sensors and actuators, signal transducers. - demonstrate knowledge and skills of IoT devices developing on the basis of IoT pointed microcontrollers and microconverters, open IoT platforms, in particular, Arduino, Raspberry Pi, Adafruit Feather. - know protocols of data transferring and theirs standards: USB, WiFi, IEEE 802.15.4, Bluetooth, Bluetooth low energy (BLE), ZigBee, 6LoWPAN, Low-power wide-area networking (LPWAN); - demonstrate knowledge and skills of IoT Software-Development Environments (IoT SDE), in particular, Intel XDK, Intel System Studio IoT Edition, Android Things, Google Cloud Interconnect; - demonstrate knowledge of recent trends in IoT and IIoT; - know requirements to electrical and mechanical parameters of biomedical electronic devices’ components, theirs biologic and electrical compatibility; - know types of biomedical sensors and actuators; - comprehend the physics and chemistry fundamentals of biomedical sensors and actuators; - demonstrate knowledge and skills of biomedical measurement transducers’ design and simulation; - demonstrate knowledge about structures and parameters of sensors for measurement of temperature, light, electric and magnetic fields, radiation, electric capacitance, force, acceleration, flux, gravitation, parameters of liquid and gas substances, - comprehend construction and technology features of MEMs structures for biomedical sensor and actuator transducers; - comprehend the concept of Lab-on-Chip; - demonstrate knowledge and skills of using signal measurement transducers and interfaces of sensor devices; - demonstrate knowledge of recent trends in measurement transducers for telemedicine and Internet of Things.
Required prior and related subjects: Components of biomedical devices Circuit technique of biomedical devices
Summary of the subject: Definitions and basics of concepts: Internet of Everything (IoE),Web of Things (WoT), Internet of Things (IoT), Industrial Internet of Things (IIoT), Smart Environments (SE), Smart Home (SH), Augment Reality (AR), Smart Dust (SD), Telemedicine (TM). Electronic devices of IoT and IIoT. Embedded system of IoT and IIoT. Smart sensors and actuators. Signal transducers. IoT devices’ power consumption strategies. Energy efficiency. Energy harvesting from environment. Noise immunity. IoT pointed microcontrollers and microconverters. Open IoT platforms: Arduino, Raspberry Pi, Adafruit Feather. Web Object identification. Radio-Frequency IDentification (RFID). Global Positioning System (GPS). GPS Inertial Navigation System (GPS/INS). Navigation device. Protocols of data transferring and theirs standards: USB, WiFi, IEEE 802.15.4, Bluetooth, Bluetooth low energy (BLE), ZigBee, 6LoWPAN, Low-power wide-area networking (LPWAN). IoT Software-Development Environments (IoT SDE). Intel XDK, Intel System Studio IoT Edition, Android Things, Google Cloud Interconnect. Requirements to electrical and mechanical parameters of biomedical electronic devices’ components. Biologic and electric compatibility. Receptors and sensors of living organisms. Types of sensors and actuators. Physics and chemistry fundamentals of sensors and actuators. Sensors and actuators for biomedical engineering. Sensors for measurement of temperature, light, electric and magnetic fields, radiation, electric capacitance, force, acceleration, flux, gravitation, parameters of liquid and gas substances. Biosensors. Concept of Lab-on-Chip. MEMs structure in sensor and actuator technique. Concept of intelligent (smart) sensors. Signal measurement transducers. Interfaces of sensor devices. Measurement transducers of telemedicine and Internet of Things.
Assessment methods and criteria: Current control: laboratory reports, oral interviewing, written tests – 40 points (40 %). Final control: control procedure - written and verbal examination – 60 points (60 %).
Recommended books: 1. Alessandro Bassi, Martin Bauer, Martin Fiedler. Enabling Things to Talk: Designing IoT solutions with the IoT Architectural Reference Model. Springer Heidelberg. -2013. 2. Ovidiu Vermesan, Peter Friess. Internet of Things: Converging Technologies for Smart Environments and Integrated Ecosystems // River Publishers. – 2013. 3. Мікросхемотехніка. Підручник за редакцією З.Ю.Готри / Гельжинський І.І, Голяка Р.Л., Готра З.Ю, Марусенкова Т.А. – Львів: Ліга-Прес. 2015. 4. Структури та параметри мікроелектронних гальваномагнітних сенсорів магнітного поля: монографія / Большакова І.А., Годинюк І.М., Голяка Р.Л., Готра З.Ю, Ільканич В.Ю., Марусенкова Т.А., Політанський Л.Ф.– Львів: Ліга-Прес, 2013. 5. Мікроелектронні сигнальні перетворювачі теплових сенсорів потоку: монографія / З.Ю.Готра, С.В.Павлов, Р.Л.Голяка та ін. – Вінниця: ВНТУ, 2012. 6. Войтович І.Д., Корсунський В.М. Інтелектуальні сенсори. – Київ. – Інститут кібернетики імені В.М.Глушкова НАН України.– 2007. 7. Основи біомедичного радіоелектронного апаратобудування: навчальний посібник. Злепко С.М., Павлов С.В., Коваль Л.Г. та ін. – Вінниця: ВНТУ. – 2011. 8. Мікроелектронні сенсори фізичних величин. В трьох томах / За ред. Готри З. - Львів: Вид. Ліга-Прес. Том 1– 2002, Том 2 – 2003, Том 3 – 2006. 9. Завадостійкі сигнальні перетворювачі оптичних сенсорних пристроїв: монографія / Вісьтак М., Голяка Р., Микитюк З. - Львів: Ліга-Прес, –2015.