ZUT - Polska Rama Kwalifikacji / Rok 2022/2023 / Administracja Centralna Uczelni / Wymiana międzynarodowa (S1) / Sylabus przedmiotu

Administracja Centralna Uczelni - Wymiana międzynarodowa (S1)

Sylabus przedmiotu Optoelectronic sensors:

Informacje podstawowe

Kierunek studiów	Wymiana międzynarodowa
Forma studiów	studia stacjonarne	Poziom	pierwszego stopnia
Tytuł zawodowy absolwenta
Obszary studiów	—
Profil
Moduł	—
Przedmiot	Optoelectronic sensors
Specjalność	przedmiot wspólny
Jednostka prowadząca	Katedra Telekomunikacji i Fotoniki
Nauczyciel odpowiedzialny	Grzegorz Żegliński <Grzegorz.Zeglinski@zut.edu.pl>
Inni nauczyciele	Grzegorz Żegliński <Grzegorz.Zeglinski@zut.edu.pl>
ECTS (planowane)	5,0	ECTS (formy)	5,0
Forma zaliczenia	zaliczenie	Język	angielski
Blok obieralny	—	Grupa obieralna	—

Formy dydaktyczne

Forma dydaktyczna	KOD	Semestr	Godziny	ECTS	Waga	Zaliczenie
laboratoria	L	1	30	1,0	0,30	zaliczenie
wykłady	W	1	15	2,0	0,40	zaliczenie
projekty	P	1	15	2,0	0,30	zaliczenie

Wymagania wstępne

KOD	Wymaganie wstępne
W-1	Academic courses: Mathematics, Physics.

Cele przedmiotu

KOD	Cel modułu/przedmiotu
C-1	At successful completion of this course the students will be familiar with optoelectronic and optical fiber sensors, modelling and design. The course will also provide the basic knowledge of modelling methods of IR optoelectronic sensor and their applications. The students will get ability to design of modern optoelectronic sensor systems with emphasis on advanced fiber-optic sensor systems.

Treści programowe z podziałem na formy zajęć

KOD	Treść programowa	Godziny
laboratoria
T-L-1	The sensor software tools- lab training.	4
T-L-2	The distance optical fiber sensor.	2
T-L-3	The Light intensity-modulated fiber-optic displacement sensor.	2
T-L-4	The fiber optic interferometric device.	2
T-L-5	The characteristics of VIS diode lasers.	2
T-L-6	The detector measurements for IR aplications.	2
T-L-7	The laser driver.	2
T-L-8	The amplificators for detectors.	2
T-L-9	Temperature measurements by pirometer.	2
T-L-10	The optical strain sensor based on fiber.	4
T-L-11	Optoelectronic sensors for arduino platform.	4
T-L-12	The subbsision tiime deadline for lab reports	2
		30
projekty
T-P-1	Project work- The simple microcontroler circuit with a optoelectronic sensor for industrial application.	15
		15
wykłady
T-W-1	Optoelectronic sensor technologies.	2
T-W-2	Multimode and singlemode fiber optic sensors.	1
T-W-3	The birefringe in optical fibers. PM fiber sensors.	1
T-W-4	Bragg fibers.	1
T-W-5	Holey and Photonic Crystal Fibers. Photonic Bandgap Guidance.	2
T-W-6	Diode lasers for sensors.	1
T-W-7	Detectors.	1
T-W-8	Electronic drivers for sensor transmitters and receivers.	1
T-W-9	Splitters and couplers for sensor systems.	1
T-W-10	Optoelectronic sensors in the medicial applications.	1
T-W-11	Industrial applications (The robotic industrial line, gas sensors, automotive sensors).	1
T-W-12	Sensor for IoT . Health monitoring.	1
T-W-13	New optoelectronic sensors for environment monitoring.	1
		15

Obciążenie pracą studenta - formy aktywności

KOD	Forma aktywności	Godziny
laboratoria
A-L-1	Participation in labs	25
		25
projekty
A-P-1	Numerical examples studies	20
A-P-2	The electronic circuit preparing and programming.	20
A-P-3	Final Report	10
		50
wykłady
A-W-1	Participation in lectures.	15
A-W-2	Individual work - (interent, books)	30
A-W-3	Consulations	5
		50

Metody nauczania / narzędzia dydaktyczne

KOD	Metoda nauczania / narzędzie dydaktyczne
M-1	Lectures- multimedia presentations
M-2	Lab exercises

Sposoby oceny

KOD	Sposób oceny
S-1	Ocena podsumowująca: Final report
S-2	Ocena podsumowująca: Test
S-3	Ocena formująca: Lab report

Zamierzone efekty uczenia się - wiedza

Zamierzone efekty uczenia się	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
WM-WE_1-_??_W01 At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.	—	—	C-1	T-W-10, T-W-3, T-W-4, T-W-6, T-W-7, T-W-11, T-W-12, T-W-13, T-W-5, T-W-1, T-W-2, T-W-8, T-W-9	M-1	S-2

Zamierzone efekty uczenia się - umiejętności

Zamierzone efekty uczenia się	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
WM-WE_1-_??_U01 At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.	—	—	C-1	T-L-1, T-L-12, T-L-9, T-L-11, T-L-8, T-L-2, T-L-3, T-L-4, T-L-5, T-L-6, T-L-7, T-L-10, T-P-1	M-2	S-1, S-3

Kryterium oceny - wiedza

Efekt uczenia się	Ocena	Kryterium oceny
WM-WE_1-_??_W01 At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.	2,0	The student received a score of less than 50% of the credit questions.
	3,0	The student received points in the range of 50-60% of credit questions.
	3,5	The student received points in the range of 61-70% of the credit questions.
	4,0	The student received a score in the range of 71-80% of the credit questions.
	4,5	The student obtained points in the range of 81-90% of the credit questions.
	5,0	The student obtained points in the range of 91-100% of the credit questions.

Kryterium oceny - umiejętności

Efekt uczenia się	Ocena	Kryterium oceny
WM-WE_1-_??_U01 At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.	2,0	The student received a score of less than 50% of the credit questions.
	3,0	The student received points in the range of 50-60% of credit questions.
	3,5	The student received points in the range of 61-70% of the credit questions.
	4,0	The student received a score in the range of 71-80% of the credit questions.
	4,5	The student obtained points in the range of 81-90% of the credit questions.
	5,0	The student obtained points in the range of 91-100% of the credit questions.

Literatura podstawowa

Giancarlo C Righini , Antonella Tajani, Antonello Cutolo, An Introduction to Optoelectronic Sensors, Series in Optics and Photonics: Volume 7 , World Scientific, Singapore, 2009
Asit Baran Maity, Optoelectronics and Optical Fiber Sensors, University Bookstore, B-74,New delhi, India, New delhi, India, 2013

Treści programowe - laboratoria

KOD	Treść programowa	Godziny
T-L-1	The sensor software tools- lab training.	4
T-L-2	The distance optical fiber sensor.	2
T-L-3	The Light intensity-modulated fiber-optic displacement sensor.	2
T-L-4	The fiber optic interferometric device.	2
T-L-5	The characteristics of VIS diode lasers.	2
T-L-6	The detector measurements for IR aplications.	2
T-L-7	The laser driver.	2
T-L-8	The amplificators for detectors.	2
T-L-9	Temperature measurements by pirometer.	2
T-L-10	The optical strain sensor based on fiber.	4
T-L-11	Optoelectronic sensors for arduino platform.	4
T-L-12	The subbsision tiime deadline for lab reports	2
		30

Treści programowe - projekty

KOD	Treść programowa	Godziny
T-P-1	Project work- The simple microcontroler circuit with a optoelectronic sensor for industrial application.	15
		15

Treści programowe - wykłady

KOD	Treść programowa	Godziny
T-W-1	Optoelectronic sensor technologies.	2
T-W-2	Multimode and singlemode fiber optic sensors.	1
T-W-3	The birefringe in optical fibers. PM fiber sensors.	1
T-W-4	Bragg fibers.	1
T-W-5	Holey and Photonic Crystal Fibers. Photonic Bandgap Guidance.	2
T-W-6	Diode lasers for sensors.	1
T-W-7	Detectors.	1
T-W-8	Electronic drivers for sensor transmitters and receivers.	1
T-W-9	Splitters and couplers for sensor systems.	1
T-W-10	Optoelectronic sensors in the medicial applications.	1
T-W-11	Industrial applications (The robotic industrial line, gas sensors, automotive sensors).	1
T-W-12	Sensor for IoT . Health monitoring.	1
T-W-13	New optoelectronic sensors for environment monitoring.	1
		15

Formy aktywności - laboratoria

KOD	Forma aktywności	Godziny
A-L-1	Participation in labs	25
		25

(*) 1 punkt ECTS, odpowiada około 30 godzinom aktywności studenta

Formy aktywności - projekty

KOD	Forma aktywności	Godziny
A-P-1	Numerical examples studies	20
A-P-2	The electronic circuit preparing and programming.	20
A-P-3	Final Report	10
		50

(*) 1 punkt ECTS, odpowiada około 30 godzinom aktywności studenta

Formy aktywności - wykłady

KOD	Forma aktywności	Godziny
A-W-1	Participation in lectures.	15
A-W-2	Individual work - (interent, books)	30
A-W-3	Consulations	5
		50

(*) 1 punkt ECTS, odpowiada około 30 godzinom aktywności studenta

Pole	KOD	Znaczenie kodu
Zamierzone efekty uczenia się	WM-WE_1-_??_W01	At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.
Cel przedmiotu	C-1	At successful completion of this course the students will be familiar with optoelectronic and optical fiber sensors, modelling and design. The course will also provide the basic knowledge of modelling methods of IR optoelectronic sensor and their applications. The students will get ability to design of modern optoelectronic sensor systems with emphasis on advanced fiber-optic sensor systems.
Treści programowe	T-W-10	Optoelectronic sensors in the medicial applications.
	T-W-3	The birefringe in optical fibers. PM fiber sensors.
	T-W-4	Bragg fibers.
	T-W-6	Diode lasers for sensors.
	T-W-7	Detectors.
	T-W-11	Industrial applications (The robotic industrial line, gas sensors, automotive sensors).
	T-W-12	Sensor for IoT . Health monitoring.
	T-W-13	New optoelectronic sensors for environment monitoring.
	T-W-5	Holey and Photonic Crystal Fibers. Photonic Bandgap Guidance.
	T-W-1	Optoelectronic sensor technologies.
	T-W-2	Multimode and singlemode fiber optic sensors.
	T-W-8	Electronic drivers for sensor transmitters and receivers.
	T-W-9	Splitters and couplers for sensor systems.
Metody nauczania	M-1	Lectures- multimedia presentations
Sposób oceny	S-2	Ocena podsumowująca: Test
Kryteria oceny	Ocena	Kryterium oceny
	2,0	The student received a score of less than 50% of the credit questions.
	3,0	The student received points in the range of 50-60% of credit questions.
	3,5	The student received points in the range of 61-70% of the credit questions.
	4,0	The student received a score in the range of 71-80% of the credit questions.
	4,5	The student obtained points in the range of 81-90% of the credit questions.
	5,0	The student obtained points in the range of 91-100% of the credit questions.

Pole	KOD	Znaczenie kodu
Zamierzone efekty uczenia się	WM-WE_1-_??_U01	At successful completion of this course the students will be familiar with special optical fiber and optolectronic devices - modelling and design. The course will also provide the basic knowledge of optoeletronic sensors and their applications.
Cel przedmiotu	C-1	At successful completion of this course the students will be familiar with optoelectronic and optical fiber sensors, modelling and design. The course will also provide the basic knowledge of modelling methods of IR optoelectronic sensor and their applications. The students will get ability to design of modern optoelectronic sensor systems with emphasis on advanced fiber-optic sensor systems.
Treści programowe	T-L-1	The sensor software tools- lab training.
	T-L-12	The subbsision tiime deadline for lab reports
	T-L-9	Temperature measurements by pirometer.
	T-L-11	Optoelectronic sensors for arduino platform.
	T-L-8	The amplificators for detectors.
	T-L-2	The distance optical fiber sensor.
	T-L-3	The Light intensity-modulated fiber-optic displacement sensor.
	T-L-4	The fiber optic interferometric device.
	T-L-5	The characteristics of VIS diode lasers.
	T-L-6	The detector measurements for IR aplications.
	T-L-7	The laser driver.
	T-L-10	The optical strain sensor based on fiber.
	T-P-1	Project work- The simple microcontroler circuit with a optoelectronic sensor for industrial application.
Metody nauczania	M-2	Lab exercises
Sposób oceny	S-1	Ocena podsumowująca: Final report
Sposób oceny	S-3	Ocena formująca: Lab report
Kryteria oceny	Ocena	Kryterium oceny
	2,0	The student received a score of less than 50% of the credit questions.
	3,0	The student received points in the range of 50-60% of credit questions.
	3,5	The student received points in the range of 61-70% of the credit questions.
	4,0	The student received a score in the range of 71-80% of the credit questions.
	4,5	The student obtained points in the range of 81-90% of the credit questions.
	5,0	The student obtained points in the range of 91-100% of the credit questions.