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Navigation Systems
Abbreviation: NAVSUSLoad: 15(L) + 0(E) + 30(LE) + 0(CE) + 0(PEE) + 0(FE) + 0(S) + 0(DE) + 0(P) + 0(FLE) + 0()
Lecturers in charge: prof. dr. sc. Josip Stepanić
Lecturers: dr. sc. Jelena Ćosić Lesičar ( Laboratory exercises )
Course description: Course objectives:
Students will learn working principles of navigation systems.

Enrolment requirements and required entry competences for the course:
There are no prerequisites for this class.

Student responsibilities:
preparation of a seminar

Grading and evaluation of student work over the course of instruction and at a final exam:
continuous, multilevel testing of knowledge and developed understanding

Methods of monitoring quality that ensure acquisition of exit competences:
analysis of nonstructured classes" discussions
analisys seminar"s quality levels

Upon successful completion of the course, students will be able to (learning outcomes):
Competently use models of navigation systems for innovative applications.
Active and interdisciplinary application of basic features research and innovative development of navigation system.
Present the elements of social conditionality for development of navigation system.
Use the principles for underlying modern navigation systems.
Use the basic properties of the navigation system.
Estimate the mutual influence of different principles of navigation systems.

1. Structure, classifications and basic examples of navigation systems.
2. Development of navigation systems.
3. Navigation models of the Earth and its atmosphere.
4. Astorlabe, compass, sextant, octant and astrocompass.
5. Magnetic compass.
6. Magnetometer.
7. Optical birefringence.
8. Radio navigation.
9. Hyperbolic navigation.
10. Microwave navigation.
11. Satelyte navigation.
12. Navigation within a microlocation.
13. Inertial navigation.
14. Contemporary optical navigation systems.
15. Gudelines of navigation systems development.

1. Examples of structures of navigation measurements.
2. Examples of statistical analysis navigation measurements.
3. Examples of inertial navigation.
4. Examples of inertial navigation.
5. Examples of inertial navigation.
6. Examples of magnetostatic and electromagnetic induction in navigation.
7. Examples of propagation of electromagnetic waves.
8. Examples of polarisation.
9. Examples of interferometry.
10. Examples of radar.
11. Examples of satellite navigation systems.
12. Examples of development of sattelite navigation systems.
13. Examples of contemporary optical navigation systems.
14. Examples of contemporary optical navigation systems.
15. Examples of integrating navigation systems.
Lecture languages: en, hr
Compulsory literature:
1. Stepanić, J.: Razvoj metoda navigacije, bilješke za predavanja
Recommended literature:
2. Gurney, A.: Compass: A Story of Exploration and Innovation. W. W. Norton & Company, 2004.,
3. Mackenzie, D.: Inventing Accuracy. MIT Press, 1993.,
4. Groves, P.D.: Principles of GNSS, Inertial, and Multisensor Integrated Navigation Systems. Artech, 2008.
L - Lectures
FLE - Practical foreign language exercises
E - Exercises
LE - Laboratory exercises
CE - Project laboratory
PEE - Physical education excercises
FE - Field exercises
S - Seminar
DE - Design exercises
P - Practicum
* - Not graded
Copyright (c) 2006. Ministarstva znanosti, obrazovanja i športa. Sva prava zadržana.
Programska podrška (c) 2006. Fakultet elektrotehnike i računarstva.
Oblikovanje(c) 2006. Listopad Web Studio.
Posljednja izmjena 2019-06-07