Faculty of Civil Engineering / INFRASTRUCTURES / ENGINEERING GEOLOGY

Course:

ENGINEERING GEOLOGY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11922	Obavezan	1	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	None.
Aims	This Subject enables acqusition of basic information in fields of engineering geology .
Learning outcomes	After having passed the exam, students will be able to: 1. Explain engeneering-geologial terms ; 2. Explain phases of engeneering-geologial investigations for the construction of roads and hydro-technical facilities; 3. Create engeneering-geologial sections; 4. Understand engeneering-geologial maps; 5. Understand engeneering-geologial projects; 6. Understand engeneering-geologial reports.
Lecturer / Teaching assistant	Prof. Dr. Milan Radulović - lecturer
Methodology	Lectures, exercises, consultation, field work.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Igneous, sedimentary and metamorphic rocks.
I week exercises	Identification of rocks.
II week lectures	Tectonics. Geological, hydrogeological and engineering geological maps (adapted to the study program INFRASTRUCTURE).
II week exercises	Geological and hydrogeological maps.
III week lectures	Engineering-geological types of rocks. Geological and engineering-geological characteristics of Montenegro (adapted to the study program INFRASTRUCTURE).
III week exercises	Engineering-geological maps.
IV week lectures	Methodology of engineering-geological ground investigation for the design and construction of roads and hydrotehnical facilities.
IV week exercises	Engineering-geological section according to drilling data.
V week lectures	Engineering-geoloical processes (landslides, escarpments).
V week exercises	Engineering-geoloical section over a landslide.
VI week lectures	Investigations of landslides.
VI week exercises	Elements of a landslide.
VII week lectures	Technical measures to improve properties of a ground: compaction, piles, anchors, injection, drainage.
VII week exercises	Plate loading test.
VIII week lectures	I Test, I Colloquium.
VIII week exercises	I Test, I Colloquium.
IX week lectures	Engineering-geological conditions for the construction of roads and pipelines.
IX week exercises	An example of engineering-geological report for the construction of a road and pipeline.
X week lectures	Engineering-geological conditions for tunnels and roads (open route) construction.
X week exercises	RMR classification.
XI week lectures	Engineering-geological conditions for construction of bridges and dams.
XI week exercises	Engineering-geological section for a bridge construction.
XII week lectures	Investigation of geological building material deposits.
XII week exercises	Engineering-geological section over a deposit and reserves assessment.
XIII week lectures	Eurocode 7 - Geotechnical design, Part 2: Ground investigation and testing
XIII week exercises	Finalisation of graphic works.
XIV week lectures	Field visit.
XIV week exercises	Field visit.
XV week lectures	II Test, II Colloquium.
XV week exercises	II Test, II Colloquium.

Student workload	Weekly Lectures: 3.5 credits x 40/30 = 4h 40min Total workload for the Subject 3.5x30 = 105h
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance of lectures and exercises, homework and testing.
Consultations	Friday 11.00-13.00
Literature	Mićko Radulović, Basic Geology, Textbook (2003), University of Montenegro; Mićko Radulović, Engeneering Geology, Script (2003), University of Montenegro.
Examination methods	- Attendance to lectures and exercises: max 5 pt; - Graphic works: max 5 pt; - Tests: max 20 pt; - Colloquiums: max 40 pt; - Final exam: max 30 pt; - Pass requires minimum 50 pt.
Special remarks
Comment	Further information about the Subject can be required from the lecturer, assistant, head of the study program and vice dean of academic affairs.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / ENGINEERING GEODESY

Course:

ENGINEERING GEODESY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11937	Obavezan	1	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	This course is not conditional on other courses.
Aims	Through this course, students are introduced to geodetic engineering tasks in the design and construction of buildings.
Learning outcomes	After passing this exam student will be able to: 1. Know the methods and instruments used in the design of basis for the designing and construction of roads. 2. Know the process of making operational polygon. 3. Know the making of the project of overground and underground tunnel triangulation. 4. Design the network of bridge triangulation. 5. Contract making of the Elaborate of expropriation. 6. Contract and control all surveying tasks related to creating the basis for the design of roads, marking and control of stability of all parts of road.
Lecturer / Teaching assistant	Đurović Radovan, PhD, MSc.geod.eng. Associate Professor
Methodology	Lectures, exercises, demonstrations for working with maps, topographic base maps and instruments. Studying and doing homework. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Application of geodesy in engineering. Geodetic networks.
I week exercises	Introduction. Application of geodesy in engineering. Geodetic networks.
II week lectures	Geodesy in construction. The basic goals and tasks of geodesy in the design and construction of construction projects. Cadastral topographic plan as a basis for the development of spatial planning projects and roads. The project of marking construction objects.
II week exercises	Geodesy in construction. The basic goals and tasks of geodesy in the design and construction of construction projects. Cadastral topographic plan as a basis for the development of spatial planning projects and roads. The project of marking construction objects.
III week lectures	Data collection. Characteristic points. Data collection methods - polar and photogrammetric.
III week exercises	Data collection. Characteristic points. Data collection methods - polar and photogrammetric.
IV week lectures	Operating polygon, essence, how to develop and determine coordinates, application in the design and construction of roads.
IV week exercises	Operating polygon, essence, how to develop and determine coordinates, application in the design and construction of roads.
V week lectures	Vertical terrain representation, accuracy, interpolation of isohypsies. Digital terrain model, way of realization, application in construction with a special reference to the design of roads.
V week exercises	Vertical terrain representation, accuracy, interpolation of isohypsies. Digital terrain model, way of realization, application in construction with a special reference to the design of roads.
VI week lectures	I COLLOQUIUM
VI week exercises	I COLLOQUIUM
VII week lectures	Marking project. 1D, 2D and 3D marking. The polar method of marking axis and other points of various objects from the operating range. Marking errors and accuracy.
VII week exercises	Marking project. 1D, 2D and 3D marking. The polar method of marking axis and other points of various objects from the operating range. Marking errors and accuracy.
VIII week lectures	Area calculation. Calculating volumes using the method of cross profiles, using isohypsies, using a network of regular geometric figures and from a digital terrain model. Diagram of leveling of earth masses.
VIII week exercises	Area calculation. Calculating volumes using the method of cross profiles, using isohypsies, using a network of regular geometric figures and from a digital terrain model. Diagram of leveling of earth masses.
IX week lectures	Analytical development of the geometry of the designed object. Marking the direction between points that cannot be seen. Road geometry. Clothoids. Calculation of the coordinates of crossing points and circular curves in the polygonal train.
IX week exercises	Calculation of the coordinates of the main points of a symmetrical clothoid with a circular curve
X week lectures	Geodetic networks of engineering objects - special purpose networks. Purpose and way of designing. Transformation of special-purpose geodetic networks into the national coordinate system. Quality assessment. Geodetic works during the construction of bridges.
X week exercises	Geodetic networks of engineering objects - special purpose networks. Purpose and way of designing. Transformation of special-purpose geodetic networks into the national coordinate system. Quality assessment. Geodetic works during the construction of bridges.
XI week lectures	Tunnels. Tunnel networks, underground and above ground, their connection, calculation of penetration accuracy. Geodetic works during tunnel excavation. Convergence measurements and observation of tunnel movement during construction and exploitation.
XI week exercises	Tunnels. Tunnel networks, underground and above ground, their connection, calculation of penetration accuracy. Geodetic works during tunnel excavation. Convergence measurements and observation of tunnel movement during construction and exploitation.
XII week lectures	II COLLOQUIUM
XII week exercises	II COLLOQUIUM
XIII week lectures	Modern measuring technique. GNSS method. Remote detection. Unmanned aerial vehicles and the LIDAR method. Radar recording of terrain. Satellite images.
XIII week exercises	Modern measuring technique. GNSS method. Remote detection. Unmanned aerial vehicles and the LIDAR method. Radar recording of terrain. Satellite images.
XIV week lectures	Observation of roads and buildings during construction and exploitation. Expropriation. Geodetic works for the purposes of developing the expropriation project.
XIV week exercises	Observation of roads and buildings during construction and exploitation. Expropriation. Geodetic works for the purposes of developing the expropriation project.
XV week lectures	Work with geodetic instruments, examples from practice.
XV week exercises	Work with geodetic instruments, examples from practice.

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature	Lectures - ppt presentations, material from the website of the Faculty of Civil Engineering, Primena geodezije u saobraćajnicama, Ašanin, S., Bajat, B., Belgrade, 2015, Inženjerska geodesija 1, Ašanin, S., Belgrade, 2003.
Examination methods	- 5 homework tasks total 5 points (each homework task 1 point) – Two colloquiums 20 points each (total 40 points). – Regular attendance 5 points (each absence –1 point) – Final exam 50 points. – Students get the passing mark if they cumulatively collect 50 points.
Special remarks
Comment	Additional information can be obtained at the present teaching staff, with Dean for Academic Affairs.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / PROJECT MANAGEMENT

Course:

PROJECT MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11938	Obavezan	1	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	None
Aims	Students should learn the basic concepts and methods of projects management with the special application in the field of civil engineering
Learning outcomes	After passing this exam, the student will be able to: Actively participate in managing all phases of technical documentation development in the field of civil engineering. Practically apply acquired knowledge in the area of legal regulations related to civil engineering and actively participate in the preparation of construction site documentation. Apply acquired knowledge directly on the construction site.
Lecturer / Teaching assistant	Dr Miloš Knežević - professor Mr Mladen Gogic
Methodology	Lectures, consultations

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction; Definition, specific quantity and division of investment projects, meaning of some terms; Participants in the realization of investment projects; Phases of investment projects
I week exercises	Introduction; Definition, specific quantity and division of investment projects, meaning of some terms; Participants in the realization of investment projects; Phases of investment projects
II week lectures	Project like cybernetic system. Role of consultant in projects management (in structures building ):consultants’ services, consultants’ services towards FIDIC; models of giving consult. services.
II week exercises	Project like cybernetic system. Role of consultant in projects management (in structures building ):consultants’ services, consultants’ services towards FIDIC; models of giving consult. services.
III week lectures	Project conceiving. Previous feasibility study.
III week exercises	Project conceiving. Previous feasibility study.
IV week lectures	Feasibility study. Revision. Decision of acceptance of study. Obtaining of financial funds.
IV week exercises	Feasibility study. Revision. Decision of acceptance of study. Obtaining of financial funds.
V week lectures	Project definition (making of technical documents): conditions and bases and contents .
V week exercises	Project definition (making of technical documents): conditions and bases and contents .
VI week lectures	Types of documents; teh. doc. For previous and preparatory works; ceding of making techn doc.(choice of designer); making and control of tech. doc.; agree. and keep. tec. doc.
VI week exercises	Types of documents; teh. doc. For previous and preparatory works; ceding of making techn doc.(choice of designer); making and control of tech. doc.; agree. and keep. tec. doc.
VII week lectures	FREE WEEK
VII week exercises	FREE WEEK
VIII week lectures	FIRST TEST
VIII week exercises	FIRST TEST
IX week lectures	Management of realization of investment project: getting the proofs on rights of property or usage of building site; building license, ceding of structure building
IX week exercises	Management of realization of investment project: getting the proofs on rights of property or usage of building site; building license, ceding of structure building
X week lectures	Documents on the structure. Way of keeping documents, tech-economic study paper, monthly operative plan, building diary, measurement book, controllers’ book, protocols: marking of urban lot, on control of foundation pit, on control of foundation, on cate
X week exercises	Documents on the structure. Way of keeping documents, tech-economic study paper, monthly operative plan, building diary, measurement book, controllers’ book, protocols: marking of urban lot, on control of foundation pit, on control of foundation, on cate
XI week lectures	Way of keeping documents –protocols on control: anchors in marking the axis of columns, of steel columns, crane lanes and tracks, hidden works, study paper on quality control,
XI week exercises	Way of keeping documents –protocols on control: anchors in marking the axis of columns, of steel columns, crane lanes and tracks, hidden works, study paper on quality control,
XII week lectures	Documents on the structure: keep a record of techn.doc., official reports, commissions’ minutes, reports on work and results, requests’ of constructors, correspondence
XII week exercises	Documents on the structure: keep a record of techn.doc., official reports, commissions’ minutes, reports on work and results, requests’ of constructors, correspondence
XIII week lectures	Technical review: preparation, procedure, usage license, statement of account and takeover of structure; Guarantee deadline. Management of the test production.
XIII week exercises	Technical review: preparation, procedure, usage license, statement of account and takeover of structure; Guarantee deadline. Management of the test production.
XIV week lectures	Organization of projects management; models of management and direction by Investors and Constructors
XIV week exercises	Organization of projects management; models of management and direction by Investors and Constructors
XV week lectures	SECOND TEST
XV week exercises	SECOND TEST

Student workload	Weekly 4.0 credits x 40/30 = 5 hours 20min Total workload for the course 4.0x30 = 120 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	To regularly attend lectures and exercises, take tests
Consultations	Throughout the semester continuously
Literature	1. P. Đuranović: Upravljanje investicionim projektima, Građevinski fakultet, Podgorica, 2003. 2. P. Đuranović: Projektovanje organizacije građenja, Građevinski fakultet i Kulturno prosvjetna zajednica, Podgorica, 1995. 3. P. Đuranović: Menadžment u građevinarstvu, skripta, Građevinski fakultet, Podgorica, 2000. 4. B. Ivković, B. Popović: Upravljanje projektima u građevinarstvu, Jugoimport- SDPR i IP Nauka, Beograd, 1995.
Examination methods	- Attendance at the lectures = 3 points - Seminar paper = 7 points - Preliminary exam 2x 20 = 40 points - Final exam = 50 points - Sufficient mark is got if you collect 51 points
Special remarks
Comment	Further information can be got at the subject teacher, manager of the study program, and at the vice-dean for teaching courses

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / ENGINEERING HYDROLOGY

Course:

ENGINEERING HYDROLOGY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11939	Obavezan	1	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims	Acquiring basic knowledge of hydraulics with emphasis on application in construction
Learning outcomes	1. After completing this course, the student will be able to: 2. Calculate the hydrostatic force on flat and curved surfaces 3. Calculate the friction force and all energy losses in the pipeline 4. Perform hydraulic calculation of short structures: foundations, sharp-edged spillways, practical profile spillways, evacuation organ overflows 5. Calculates the hydraulics of a wide threshold, manhole overflow, bridge narrowing 6. Calculates various types of rapid flow, as well as lateral overflow
Lecturer / Teaching assistant
Methodology	Lectures, exercises, colloquiums

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Characteristics of fluids.
I week exercises	Introduction. Characteristics of fluids.
II week lectures	Hydrostatics. Change in pressure depending on the position. Pressure measurements.
II week exercises	Hydrostatics. Change in pressure depending on the position. Pressure measurements.
III week lectures	Hydrostatic forces on solid boundary surfaces.
III week exercises	Hydrostatic forces on solid boundary surfaces.
IV week lectures	The effect of pressure on flat and curved surfaces - pressure force.
IV week exercises	The effect of pressure on flat and curved surfaces - pressure force.
V week lectures	Basic concepts of fluid dynamics. The equation of conservation of mass. Dynamic equation (Equation of momentum).
V week exercises	The equation of conservation of mass. The momentum equation.
VI week lectures	Energy equation.
VI week exercises	Energy equation.
VII week lectures	Friction. Energy losses.
VII week exercises	Friction. Energy losses.
VIII week lectures	Friction during uniform flow in a pipe. Local energy losses.
VIII week exercises	Friction during uniform flow in a pipe. Local energy losses.
IX week lectures	COLLOQUIUM I
IX week exercises	COLLOQUIUM I
X week lectures	Hydrodynamic resistances.
X week exercises	Hydrodynamic resistances.
XI week lectures	Shape resistances.
XI week exercises	Shape resistances.
XII week lectures	Flow in open streams. Hydraulic jump. ​
XII week exercises	Flow in open streams. Hydraulic jump. ​
XIII week lectures	Uneven flow. Level line shapes.
XIII week exercises	Uneven flow. Level line shapes.
XIV week lectures	Highlighting below the constitution. Overflow over a wide threshold.
XIV week exercises	Highlighting below the constitution. Overflow over a wide threshold.
XV week lectures	colloquium II
XV week exercises	colloquium II

Student workload	Weekly 6.0 credits x 40/30 = 8 hours Total workload for the subject 6.0x30 = 180 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature	D. Prodanović: Mehanika fluida za studente Građevinskog fakulteta. Građevinski fakultet u Beogradu.2007. G.Hajdin: Mehanika fluida-Uvodjenje u hidrauliku.Građevinski fakultet, Beograd. 2001. Č.Maksimović. Zbirka zadataka iz mehanike fluida. Građevinski fakultet, Beograd, 1995. Dopunska literatura : B. Batinić : Hidraulika, Građevinski fakultet, Beograd, 1993. M. Radojković:Stacionarno strujanje u otvorenim tokovima prizmatičnog preseka,Građevinski fakultet, BG,1978 B. Batinić, M. Radojković: Zbirka rešenih ispitnih zadataka iz hidraulike", Građevinski fakultet, Beograd, 1981
Examination methods	Knowledge is checked continuously during the semester and at the final exam. The maximum possible number of points is 100, the colloquium 50 points and the final exam 50 points.
Special remarks	One part of the exercises must be done in the hydraulic laboratory. Laboratory practice requires mandatory attendance.
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and from the vice dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / HYDROLOGY

Course:

HYDROLOGY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11940	Obavezan	1	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims	Gaining basic knowledge of hydrology with an emphasis on building applications
Learning outcomes
Lecturer / Teaching assistant	Dr Goran Sekulić – prof.
Methodology	Lectures, exercise, graphic works, colloquiums

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction, hydrologic cycle
I week exercises	Introduction, hydrologic cycle
II week lectures	Water balance; hydrological data; Weather Service.
II week exercises	Water balance; hydrological data; Weather Service.
III week lectures	Hydrometeorology: atmospheric processes; climate and weather; measurement and analysis of meteorological variables: temperature, humidity, pressure, wind, evaporation.
III week exercises	Hydrometeorology: atmospheric processes; climate and weather; measurement and analysis of meteorological variables: temperature, humidity, pressure, wind, evaporation.
IV week lectures	Precipitation, origin, measurement and analysis.
IV week exercises	Precipitation, origin, measurement and analysis.
V week lectures	Hydrological systems and processes: hydrological systems and subsystems; basin as a system; physical parameters.
V week exercises	Hydrological systems and processes: hydrological systems and subsystems; basin as a system; physical parameters.
VI week lectures	Process parameters
VI week exercises	Process parameters
VII week lectures	FREE WEEK
VII week exercises	FREE WEEK
VIII week lectures	COLLOQUIUM I
VIII week exercises	COLLOQUIUM I
IX week lectures	Hydrometry, surveillance networks; measurement / observation of basic hydrological parameters.
IX week exercises	Hydrometry, surveillance networks; measurement / observation of basic hydrological parameters.
X week lectures	The basic data processing, hydrograph, hydrograph, flow curves; fault frequency and duration
X week exercises	The basic data processing, hydrograph, hydrograph, flow curves; fault frequency and duration
XI week lectures	Runoff Modelling: component hydrograph; Types of hydrological models.
XI week exercises	Runoff Modelling: component hydrograph; Types of hydrological models.
XII week lectures	Large and small water.
XII week exercises	Large and small water.
XIII week lectures	Regional analysis.
XIII week exercises	Regional analysis.
XIV week lectures	Probably the maximum precipitation and runoff.
XIV week exercises	Probably the maximum precipitation and runoff.
XV week lectures	COLLOQUIUM II
XV week exercises	COLLOQUIUM II

Student workload	Week 4.5 credits x 40/30 = 6 hours Total work hours for the course 4.5x30 = 135 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods	Knowledge checking is carried out continuously throughout the semester and the final exam. The minimum level of knowledge during the semester for pass rate is 51 points. The maximum possible number of points is 100 / semester.
Special remarks	One part of the exercise must be carried out in the hydraulic laboratory. Laboratory training requires mandatory attendance at all sessions.
Comment	Additional information can be obtained at the present teachers, assistants, head of the study program with Dean for Academic Affairs.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / CONSTRUCTION MANAGEMENT

Course:

CONSTRUCTION MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11941	Obavezan	1	5	3+1+1

Programs	INFRASTRUCTURES
Prerequisites	None
Aims	Acquisition of knowledge in management theory, organizational behavior, human resource management, leadership, business ethics, negotiation, and decision-making in construction
Learning outcomes	After passing this exam, the student will be able to: 1. Master basic concepts in construction management. 2. Understand management functions and levels generally, particularly in the construction industry. 3. Possess knowledge in strategic management, motivation theories, and leadership. 4. Apply acquired knowledge directly in management tasks in the company and on construction sites.
Lecturer / Teaching assistant	Prof. dr Miloš Knežević Mr Mladen Gogić
Methodology	Lectures and consultations, visits to construction companies

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction; Definition, genesis, functions, and classification of management, historical development, management schools
I week exercises	Preparation for exercises. Basic instructions.
II week lectures	Management functions - Planning; Levels of planning, planning methods: PRECEDENCE method, PERT method, relationship method of planning, resources, finances within construction companies
II week exercises	Seminar paper, consultations, and review.
III week lectures	Management functions - Organizing; Basic principles, definitions, conditions, and possible organizational models; Sustainable development
III week exercises	Seminar paper, consultations, and review.
IV week lectures	Division of labor and specialization in construction
IV week exercises	Seminar paper, consultations, and review.
V week lectures	Definition of organization, organization functioning, organizational means.
V week exercises	Seminar paper, consultations, and review.
VI week lectures	Organizational behavior and human resource management
VI week exercises	Seminar paper, consultations, and review.
VII week lectures	FIRST TEST
VII week exercises	FIRST TEST
VIII week lectures	Management functions - Leading; Definition of leadership and leadership; Basic qualities of successful leadership; Leadership and management styles
VIII week exercises	Seminar paper, consultations, and review.
IX week lectures	Motivational processes and motivation for work
IX week exercises	Seminar paper, consultations, and review.
X week lectures	Management functions - Control and coordination; Control of the production process in construction; Coordination.
X week exercises	Seminar paper, consultations, and review.
XI week lectures	Strategic management; Definition, goal, division, classification, and role in the functioning of construction companies. Competitive behavior in design and construction processes
XI week exercises	Seminar paper, consultations, and review.
XII week lectures	Negotiation strategies and techniques and conducting business meetings.
XII week exercises	Seminar paper, consultations, and review.
XIII week lectures	Communication and information processes; Making business decisions.
XIII week exercises	Seminar paper, consultations, and review.
XIV week lectures	SECOND TEST
XIV week exercises	SECOND TEST
XV week lectures	Evaluation of seminar paper
XV week exercises	Evaluation of seminar paper

Student workload	Weekly: 5 credits x 40/30 = 6 hours and 40 minutes Structure: 3 hours of lectures 1 hour of exercises 1 hour of individual exercises 1 hour and 40 minutes of independent study. During the semester: Teaching and final exam: (6 hours 40 minutes) x 16 = 106 hours 40 minutes Preparation before the semester begins (administration, registration, verification): 2 x (6 hours and 40 minutes) = 13 hours and 20 minutes Total workload for the subject 5x30 = 150 hours Additional work for exam preparation in the makeup exam period, including taking the makeup exam, from 0 to 30 hours (remaining time from the first two items to the total workload for the subject 150 hours) Workload structure: 106 hours and 40 minutes (Teaching) + 13 hours and 20 minutes (Preparation) + 30 hours (Additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	To regularly attend lectures and exercises, take tests
Consultations	Throughout the semester continuously
Literature	V. Novakovic: Management in Contemporary Construction, Izgradnja, Belgrade, 2003. P. Duranovic: Management of Investment Projects, Faculty of Civil Engineering, Podgorica, 2003. B. Masic: Strategic Management, University "Braca Karic", Belgrade, 2001. P. Duranovic: Construction Management, script, Faculty of Civil Engineering, Podgorica, 2000. G. Cirovic: Business Process Reengineering, Faculty of Civil Engineering, Belgrade, 1999.
Examination methods	Minimum and maximum points that a student can achieve within the elements that are graded, where the student must achieve the prescribed minimum number of points for each element: • Attendance at lectures and exercises: 1 to 5 points • First test: 10 to 20 points • Second test: 10 to 20 points • Final exam: 5 to 50 points A passing grade is obtained if at least 50 points are accumulated. Both the minimum and maximum points are given. Tests and final exams are written. A passing grade is obtained if 50 points are accumulated.
Special remarks
Comment	Further information about the course can be got from the teacher, assistant, manager of the study program , vice-dean for teaching courses.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / ROADS DESIGN

Course:

ROADS DESIGN/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11942	Obavezan	2	6	3+1+1

Programs	INFRASTRUCTURES
Prerequisites	Geodesy Roads
Aims	Acquiring basic knowledge of road design.
Learning outcomes	After passing this exam, the student will be able to: 1. Master entry criteria for road design 2. Understands road design methodology 3. Apply knowledge to the specific task of the Preliminary Design of the road
Lecturer / Teaching assistant	dr Biljana Ivanović - Associate Professor mr Teodora Popović - Teaching Associate
Methodology	Lectures, exercises, graphic work, colloquium and consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Planning of rural roads.
I week exercises	Planning of rural roads.
II week lectures	Road and traffic (road traffic development, classification of roads).
II week exercises	Road and traffic (road traffic development, classification of roads).
III week lectures	Exploitation parameters, relevant speeds, relevant vehicles.
III week exercises	Exploitation parameters, relevant speeds, relevant vehicles.
IV week lectures	Cross section of the road (elements of cross sections, standardised cross sections).
IV week exercises	Cross section of the road (elements of cross sections, standardised cross sections).
V week lectures	System driver - vehicle - environment.
V week exercises	System driver - vehicle - environment.
VI week lectures	Elements of designed geometry of roads.
VI week exercises	Elements of designed geometry of roads.
VII week lectures	Colloquium I
VII week exercises	Colloquium I
VIII week lectures	Intersections (at-grade junctions) and interchanges (grade-separated-junctions).
VIII week exercises	Intersections (at-grade junctions) and interchanges (grade-separated-junctions).
IX week lectures	Accompanying contents for the road users needs, functional contents.
IX week exercises	Accompanying contents for the road users needs, functional contents.
X week lectures	Route tracing and shaping (route management principles, tracing technique).
X week exercises	Route tracing and shaping (route management principles, tracing technique).
XI week lectures	Road and the environment, synthesis of constraints.
XI week exercises	Road and the environment, synthesis of constraints.
XII week lectures	Internal and external harmony of road elements.
XII week exercises	Internal and external harmony of road elements.
XIII week lectures	Road route analysis: traffic, driving and geometric analysis.
XIII week exercises	Road route analysis: traffic, driving and geometric analysis.
XIV week lectures	Methodology and technology of road design: process and structure of design, evaluation of variant solutions. Project management from the aspect of Investors and Designers.
XIV week exercises	Methodology and technology of road design: process and structure of design, evaluation of variant solutions. Project management from the aspect of Investors and Designers.
XV week lectures	Colloquium II
XV week exercises	Colloquium II

Student workload	Weekly 6.0 credits x 40/30 = 8 hours Total workload on the subject 6.0x30 =180hours
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Attendance in lectures and exercises, doing graphic work, passing colloquiums.
Consultations	According to the schedule defined at the beginning of the semester.
Literature	Katanić, Maletin, Anđus:Projektovanje puteva i Metodologija projektovanja puteva od Anđusa i Maletina.
Examination methods	- attendance in lectures and exercises from 1 do 3 poens (student gets 1 poen fr 70% of attendance) - graphic work from 7 to 27 poens - two colloquiums 2x20 poens - final exam up to 30 poens - students pass this subject if the cumulative number of points is 50 poens.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and from the Vice Dean for Teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / CONSTRUCTION TECHNOLOGY FOR CIVIL ENG. STRUCTURES

Course:

CONSTRUCTION TECHNOLOGY FOR CIVIL ENG. STRUCTURES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11943	Obavezan	2	6	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	There is no conditionality.
Aims	Students should learn basic categories and concepts from technologies of civil engineering.
Learning outcomes
Lecturer / Teaching assistant	dr Željka Beljkaš - professor mr Mladen Gogić - assistant
Methodology	Lectures, seminar paper, preliminary exam.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Generally on technologies of civil engineering construction, preparatory and earth works (geodetic works, site clean-up, soil categorization, site organization).
I week exercises	Generally on technologies of civil engineering construction, preparatory and earth works (geodetic works, site clean-up, soil categorization, site organization).
II week lectures	Execution of earth works, constructional plant for excavation, and loading.
II week exercises	Execution of earth works, constructional plant for excavation, and loading.
III week lectures	Constructional plant for compaction.
III week exercises	Constructional plant for compaction.
IV week lectures	Making of cuts and embankments.
IV week exercises	Making of cuts and embankments.
V week lectures	Deformation, repair and insurance of road base.
V week exercises	Deformation, repair and insurance of road base.
VI week lectures	Slopes protection and stabilization of landslide.
VI week exercises	Slopes protection and stabilization of landslide.
VII week lectures	FREE WEEK
VII week exercises	FREE WEEK
VIII week lectures	Noise protection. PRELIMINARY EXAM
VIII week exercises	Noise protection. PRELIMINARY EXAM
IX week lectures	Traffic equipment and traffic safety.
IX week exercises	Traffic equipment and traffic safety.
X week lectures	Asphalt works. PREPARATORY EXAM
X week exercises	Asphalt works. PREPARATORY EXAM
XI week lectures	Procedures of cool recycling in rehabilitation of asphalt road structures.
XI week exercises	Procedures of cool recycling in rehabilitation of asphalt road structures.
XII week lectures	Procedures of warm recycling in recycling of asphalt road structures.
XII week exercises	Procedures of warm recycling in recycling of asphalt road structures.
XIII week lectures	Procedures of warm recycling in recycling of asphalt road structures.
XIII week exercises	Procedures of warm recycling in recycling of asphalt road structures.
XIV week lectures	Application of geo-synthetic materials in civil engineering construction.
XIV week exercises	Application of geo-synthetic materials in civil engineering construction.
XV week lectures	Technology of construction and reconstruction of railways
XV week exercises	Technology of construction and reconstruction of railways

Student workload	Weekly 6.0 credits x 40/30 = 8 hours. Total workload for the course 6.0x30 = 180 hours
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods	- Attendance of teaching courses to 5 point - Seminar paper 1 x 20 = 20 points - Preliminary exam 1 x 25 = 25 points - Final exam = 50 points - Sufficient mark is got if you collect 51 point.
Special remarks
Comment	Further information can be got at the course teacher, assistant, manager of the study program and at the vice-dean for teaching courses.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / DESIGN AND CONSTRUCTION OF THE RAILWAYS

Course:

DESIGN AND CONSTRUCTION OF THE RAILWAYS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11944	Obavezan	2	6	3+2+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 2 excercises 2 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / RAILWAY SUPERSTRUCTURES

Course:

RAILWAY SUPERSTRUCTURES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11945	Obavezan	2	6	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / TRAFFIC ROADS MODELING

Course:

TRAFFIC ROADS MODELING/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11946	Obavezan	2	6	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims	Getting acquainted with the methodology of application of CAD systems in the design of roads.
Learning outcomes	After passing this exam, the student will be able to: 1. Manage the procedure for downloading, controlling and processing geodetic data. 2. Manage the procedures of modeling and calculation of line objects using CAD. 3. Manage the procedures of modeling and calculation of surface objects using CAD. 4. Transforms the results of modeling and calculation into standard forms of project documentation.
Lecturer / Teaching assistant	dr Biljana Ivanović - Associate Professor mr Teodora Popović - Teaching Associate
Methodology	Lectures, exercises, graphic work, colloquium and consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Need, design principles, a global review of several well-known softwares for design. Software environment.
I week exercises	Introduction. Need, design principles, a global review of several well-known softwares for design. Software environment.
II week lectures	Computer drawing in 2D.
II week exercises	Computer drawing in 2D.
III week lectures	Getting acquainted with the environment of Auto CAD.
III week exercises	Getting acquainted with the environment of Auto CAD.
IV week lectures	Drawing basic graphic elements.
IV week exercises	Drawing basic graphic elements.
V week lectures	Modification of elements in the drawing. Text and complex objects. Hatching and dimensioning.
V week exercises	Modification of elements in the drawing. Text and complex objects. Hatching and dimensioning.
VI week lectures	Processing and correction of drawing.
VI week exercises	Processing and correction of drawing.
VII week lectures	Preparing drawings for printing.
VII week exercises	Preparing drawings for printing.
VIII week lectures	Colloquium I.
VIII week exercises	Colloquium I.
IX week lectures	Technological process of project development using program GCM (GAVRAN CIVIL MODELAR).
IX week exercises	Technological process of project development using program GCM (GAVRAN CIVIL MODELAR).
X week lectures	Terrain modeling techniques and algorithms.
X week exercises	Terrain modeling techniques and algorithms.
XI week lectures	Designing axle geometry of the road.
XI week exercises	Designing axle geometry of the road.
XII week lectures	Designing of elevation.
XII week exercises	Designing of elevation.
XIII week lectures	Analysis and preparation of cross section.
XIII week exercises	Analysis and preparation of cross section.
XIV week lectures	Auxiliary tools.
XIV week exercises	Auxiliary tools.
XV week lectures	Colloquium II.
XV week exercises	Colloquium II.

Student workload	Weekly 6.0 credits x 40/30 = 8 hours Total workload on the subject 6.0x30 =180hours
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Attendance in lectures and exercises, doing graphic work, passing colloquiums.
Consultations	According to the schedule defined at the beginning of the semester.
Literature	Elektronska dokumentacija programa GCM (sa video dokumentacijom). Elektronska dokumentacija programa AutoCAD.
Examination methods	attendance in lectures and exercises from 1 do 3 poens (student gets 1 poen fr 70% of attendance) - graphic work from 7 to 27 poens - two colloquiums 2x20 poens - final exam up to 30 poens - students pass this subject if the cumulative number of points is 50 poens.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and from the Vice Dean for Teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / ENGINEERING HYDROLOGY

Course:

ENGINEERING HYDROLOGY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11947	Obavezan	2	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	None
Aims	Familiarization with hydrological calculations and models and their connection to applied hydraulic engineering disciplines.
Learning outcomes	After passing the exam in this subject, students will be able to: independently develop hydrological studies and prepare hydrological bases, as well as plan and design hydraulic structures and water management systems.
Lecturer / Teaching assistant	Prof dr Goran Sekulić
Methodology	Lectures, exercises, graphic works, field trips, colloquiums.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction
I week exercises	Introduction
II week lectures	Hydrological calculations in hydraulic engineering and water management.
II week exercises	Hydrological calculations in hydraulic engineering and water management.
III week lectures	Hydrological models: classifications, applications.
III week exercises	Hydrological models: classifications, applications.
IV week lectures	Design storms (intensity-duration-frequency relationships, computational hyetographs).
IV week exercises	Design storms (intensity-duration-frequency relationships, computational hyetographs).
V week lectures	Calculation of effective rainfall (methods for determining losses).
V week exercises	Calculation of effective rainfall (methods for determining losses).
VI week lectures	Unit hydrograph. Synthetic unit hydrographs.
VI week exercises	Unit hydrograph. Synthetic unit hydrographs.
VII week lectures	The rational method and other parametric methods.
VII week exercises	The rational method and other parametric methods.
VIII week lectures	COLLOQUIUM I
VIII week exercises	COLLOQUIUM I
IX week lectures	Examples of more complex hydrological models.
IX week exercises	Examples of more complex hydrological models.
X week lectures	Mass balance methods for calculations in various water management branches.
X week exercises	Mass balance methods for calculations in various water management branches.
XI week lectures	Specificities of urban hydrology.
XI week exercises	Specificities of urban hydrology.
XII week lectures	Analysis of large floods. Analysis of low flows
XII week exercises	Analysis of large floods. Analysis of low flows
XIII week lectures	Hydrological studies and water management foundation (watershed management plan).
XIII week exercises	Hydrological studies and water management foundation (watershed management plan).
XIV week lectures	Practical examples, field trips.
XIV week exercises	Practical examples, field trips.
XV week lectures	COLLOQUIUM II
XV week exercises	COLLOQUIUM II

Student workload	Weekly workload: 5 credits x 40/30 = 6.67 hours Structure: 2 hours of lectures 2 hours of exercises 2.67 hours of independent work, including consultations During the semester: Teaching and final exam: (6.67 hours) x 16 = 106.67 hours Preparation before the start of the semester (administration, enrollment, verification): 2 x (6.67 hours) = 13.33 hours Total workload for the subject: 5 x 30 = 150 hours Additional work for exam preparation in the retake exam session, including taking the retake exam: 0 to 30 hours (remaining time from the first two items to the total subject workload of 150 hours) Load structure: 106.67 hours (Teaching) + 13.33 hours (Preparation) + 30 hours (Additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature	Basic literature: 1. .Jovanović, S. (1990) Hidrologija, pogl. 2, Tehničar 6, Beograd. 2. Jovanović, S. (1975) Parametarska hidrologija, JDH, Beograd. 3. Vukmirović, V. i Pavlović D. (2005) Primenjena hidrologija – zbirka zadataka, Građevinski fakultet, Beograd. Additional literature: 4. Chow, V.T, Maidment, D.R. and Mays, L.W. (1988) Applied Hydrology, McGraw Hill. 5. Lynsley, R.K., Kohler, M.A. and Paulhus, J.H.L. (1982) Hydrology for Engineers, McGraw Hill.
Examination methods	Knowledge assessment is conducted continuously throughout the semester and during the final exam. During the semester, a student can earn a maximum of 100 points. Evaluation is based on the following: Attendance: 2 to 5 points (70% attendance earns 2 points, 100% attendance earns 5 points, less than 70% attendance earns 0 points) Graphic works: 5 x (2.0 to 5.0) = 10 to 25 points (a minimum of 2.0 points is awarded for positively assessed graphic work) Colloquium: 2 x 19 to 35 points Final exam: up to 50 points A minimum passing score and maximum score are provided. Quizzes and the final exam are conducted in written form. A passing grade is obtained if a student accumulates 50 points and if they achieve at least 19 points on both the first and second colloquium.
Special remarks
Comment	Additional information about the subject can be obtained from the course instructor, assistants, the head of the study program, and the vice dean for education.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / HYDROTECHNIC CONSTRUCTION

Course:

HYDROTECHNIC CONSTRUCTION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11948	Obavezan	2	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	No conditionality
Aims	Enabling students to participate in the design and construction of hydro-technical structures.
Learning outcomes	Students will be able for independent participation in design, construction and maintenance of hydro-technical structures.
Lecturer / Teaching assistant	Dr Jelena Pejović
Methodology	Lectures, exercises, semester works, fieldwork

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Introduction to hydro-technical structures. Basic types of hydro-technical structures.
I week exercises	Introduction. Introduction to hydro-technical structures. Basic types of hydro-technical structures.
II week lectures	Loads. Loads analysis and seismic impacts.
II week exercises	Loads. Loads analysis and seismic impacts.
III week lectures	Hydro-technical materials. Geo-technical characteristics of the environment for hydro-technical structure foundation.
III week exercises	Hydro-technical materials. Geo-technical characteristics of the environment for hydro-technical structure foundation.
IV week lectures	Dams. Classification and basic characteristics of various types of dams. Dam data and dam type selection.
IV week exercises	Dams. Classification and basic characteristics of various types of dams. Dam data and dam type selection.
V week lectures	Gravity and lightweight concrete dams. Disposition with water evacuation facilities.
V week exercises	Gravity and lightweight concrete dams. Disposition with water evacuation facilities.
VI week lectures	Stability of concrete gravity dams. General stability calculation.
VI week exercises	Stability of concrete gravity dams. General stability calculation.
VII week lectures	Arch dams. Disposition. Terms and conditions of design. Review of calculation methods.
VII week exercises	Arch dams. Disposition. Terms and conditions of design. Review of calculation methods.
VIII week lectures	Earth and Rock-fill Dams.
VIII week exercises	Earth and Rock-fill Dams.
IX week lectures	Water evacuation buildings. Bypass tunnels and canals. Overflows, drains, rapids and waterfalls.
IX week exercises	Water evacuation buildings. Bypass tunnels and canals. Overflows, drains, rapids and waterfalls.
X week lectures	Testing of knowledge.
X week exercises	Testing of knowledge.
XI week lectures	Hydraulic structures for water abstraction. Entrance structures. Surface and depth construction.
XI week exercises	Hydraulic structures for water abstraction. Entrance structures. Surface and depth construction.
XII week lectures	Water transport buildings. Channels. Hydraulic tunnels. Pipelines.
XII week exercises	Water transport buildings. Channels. Hydraulic tunnels. Pipelines.
XIII week lectures	Facilities on the Water transport buildings. Crossing objects.
XIII week exercises	Facilities on the Water transport buildings. Crossing objects.
XIV week lectures	Visit to the HE Perućica and Piva.
XIV week exercises	Visit to the HE Perućica and Piva.
XV week lectures	Testing of knowledge.
XV week exercises	Testing of knowledge.

Student workload	Weekly 5 credits x 40/30 = 6.67 hours Structure: 2 hours of lectures 2 hours of exercise 2.67 hours of independent work, including consultations.
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance at lectures and exercises, making semester works.
Consultations
Literature	1. Lj, Savić: Uvod u hidrotehničke građevine, Građevinski fakultet, Beograd, 2003. 2. P. Stojić: Hidrotehnicke gradjevine I, Sveučilište u Splitu, Građevinski fakultet, 1997. 3. P. Stojić: Hidrotehnicke gradjevine II, Sveučilište u Splitu, Građevinski fakultet, 1998. 4. P. Stojić: Hidrotehnicke gradjevine II, Sveučilište u Splitu, Građevinski fakultet, 1999.
Examination methods	Knowledge and understanding shown during the exercises 0 do 15; Semesteral work 0 do 15; Theoretical part of the final exam 0 do 30; Analytical part of the final exam 0 do 40.
Special remarks
Comment	Additional information about the subject can be obtained from the teacher, teaching assistant, head of the study program and vice dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / MUNICIPAL WATER ENGINEERING

Course:

MUNICIPAL WATER ENGINEERING/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11949	Obavezan	2	5	3+1+1

Programs	INFRASTRUCTURES
Prerequisites	There is no conditionality
Aims	The course aims to familiarize students with the principles of designing and constructing water supply and sewage systems in settlements
Learning outcomes	After passing the exam in this subject, students will be able to independently participate in the design, implementation, and maintenance of water supply and sewage systems in settlements and buildings.
Lecturer / Teaching assistant	Dr Goran Sekulić
Methodology	The course includes lectures, exercises, graphical work, field trips, and colloquiums.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	The historical development of water supply to populated areas and industries
I week exercises	The historical development of water supply to populated areas and industries
II week lectures	The components of water supply systems and their role in different conditions, as well as the classification of water supply systems
II week exercises	The components of water supply systems and their role in different conditions, as well as the classification of water supply systems
III week lectures	The basics of planning, including the planning period, water demand, consumption variations, and required water quality. Natural water supply sources, as well as the protection of water sources.
III week exercises	The basics of planning, including the planning period, water demand, consumption variations, and required water quality. Natural water supply sources, as well as the protection of water sources.
IV week lectures	Structures for accessing groundwater, springs, and surface atmospheric water.
IV week exercises	Structures for accessing groundwater, springs, and surface atmospheric water.
V week lectures	Pumping stations and reservoirs.
V week exercises	Pumping stations and reservoirs.
VI week lectures	Inflow pipelines and distribution networks, hydraulic calculations, mathematical models, pipes, fittings, and valves.
VI week exercises	Inflow pipelines and distribution networks, hydraulic calculations, mathematical models, pipes, fittings, and valves.
VII week lectures	Water supply installations in buildings and supervisory control systems in water supply systems.
VII week exercises	Water supply installations in buildings and supervisory control systems in water supply systems.
VIII week lectures	Colloquium 1
VIII week exercises	Colloquium 1
IX week lectures	Sewage systems for populated areas and industries. Introduction - purpose and historical development. Types of wastewater.
IX week exercises	Sewage systems for populated areas and industries. Introduction - purpose and historical development. Types of wastewater.
X week lectures	Sewage systems: parts, disposal solutions, wastewater quantities, qualitative properties of wastewater. Conditions for discharging wastewater into public sewers and receivers.
X week exercises	Sewage systems: parts, disposal solutions, wastewater quantities, qualitative properties of wastewater. Conditions for discharging wastewater into public sewers and receivers.
XI week lectures	Drainage of atmospheric wastewater from streets.
XI week exercises	Drainage of atmospheric wastewater from streets.
XII week lectures	Sewer network: location and depth of the sewer, sewer slopes, flow velocities, sewer profile shapes, hydraulic calculation, mathematical modeling of the sewer network.
XII week exercises	Sewer network: location and depth of the sewer, sewer slopes, flow velocities, sewer profile shapes, hydraulic calculation, and mathematical modeling of the sewer network.
XIII week lectures	Types of sewer pipes and their installation, special structures and devices in the sewer system, maintenance, and cleaning.
XIII week exercises	Types of sewer pipes and their installation, special structures and devices in the sewer system, maintenance, and cleaning.
XIV week lectures	Sewage installations in buildings.
XIV week exercises	Sewage installations in buildings.
XV week lectures	Colloquium 2
XV week exercises	Colloquium 2

Student workload	The weekly workload of 5 credits x 40/30 = 6.67 hours. Structure: 2 hours of lectures and 2 hours of exercises. 2.67 hours of individual work, including consultations. During the semester Teaching and final exam: (6.67 hours) x 16 = 106.67 hours. Necessary preparations before the start of the semester (administration, enrollment, verification) 2 x (6.67 hours) = 13.33 hours Total workload for the course 5x30 = 150 hours. Additional work for exam preparation in the retake exam period, including retaking the exam, from 0 to 30 hours (remaining time from the first two items to the total workload of 150 hours for the course). Workload structure: 106.67 hours (Teaching) + 13.33 hours (Preparation) + 30 hours (Additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance at lectures and exercises, completion of graphical assignments, passing colloquiums.
Consultations
Literature	Primary literature: G. Sekulic, I. Cipranic, Municipal Hydrotechnics, Faculty of Civil Engineering, Podgorica, 2015. M. Milojevic, Water Supply and Sewerage of Settlements, Belgrade, 2002. Additional literature: 3. D. Ljubisavljevic, A. Djukic, B. Babic, B. Jovanovic, Municipal Hydrotechnics, Examples from Theory and Practice, Faculty of Civil Engineering, Belgrade, 2001
Examination methods	Knowledge assessment is carried out continuously throughout the semester and on the final exam. A student can earn a maximum of 100 points during the semester. The following are evaluated: Attendance: 2 to 5 points (70% attendance 2 points, 100% attendance 5 points, <70% attendance 0 points) Graphic works: 5x (2.0 to 5.0) = 10 to 25 points (a minimum of 2.0 points is awarded for a positively evaluated graphic work) Midterm exams: 2 x 19 to 35 points Final exam: up to 50 points The minimum and maximum number of points are given. Midterm and final exams are written. The passing grade is obtained if the student collects 50 points, as well as if they earn at least 19 points on both the first and second midterm exams.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program, and vice-dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / WATER PROTECTION AND QUALITY

Course:

WATER PROTECTION AND QUALITY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11950	Obavezan	2	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	None.
Aims	Review of issues of quality, protection and contamination of natural waters.
Learning outcomes	After having passed the exam, students will be able to: 1. Explain components of water quality; 2. Calculate concentration of ions in water and express them in proper units; 3. Explain eutrophication process; 4. Explain transport process of contaminants in water; 5. Develop vulnerability maps, hazard and risk maps of groundwater contamination; 6. Determine limits of sanitary protection zones around watersources; 7. Calculate guaranteed ecological flow of waterflow; 8. Classify environmental impacts of hydrotechnical reservoirs.
Lecturer / Teaching assistant	Prof. Dr Milena Tadić - lecturer, Prof. Dr Milan Radulović - lecturer
Methodology	Lectures, exercises, consultations, homeworks, etc.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Basic characteristics of water. Solubility. Expression of solution concentration. Physical properties of water.
I week exercises	Introduction. Basic characteristics of water. Solubility. Expression of solution concentration. Physical properties of water.
II week lectures	Chemical composition of water. Soluble gases in water. Hydrochemical parameters (pH, Eh, stiffness, alcalinity, acidity, TDS, electrical conductivity). Macro and micro components of chemical composition. Organic matters in water (indicators BPK5, HPK, con
II week exercises	Chemical composition of water. Soluble gases in water. Hydrochemical parameters (pH, Eh, stiffness, alcalinity, acidity, TDS, electrical conductivity). Macro and micro components of chemical composition. Organic matters in water (indicators BPK5, HPK, con
III week lectures	Testing water quality. Laboratory equipment. Water sampling. Analyses of water samples. Accuracy check of chemical analyses. Water classification based on content of macro components.
III week exercises	Testing water quality. Laboratory equipment. Water sampling. Analyses of water samples. Accuracy check of chemical analyses. Water classification based on content of macro components.
IV week lectures	Graphic presentation of chemical composition. Calculation of mixture of waters with different origin. Hydrochemical indicators (saturation index with calcite (SIc) and dolomite (SId), hydrochemical coefficients, ratio Mg/Ca and salinity). Water aggressivi
IV week exercises	Graphic presentation of chemical composition. Calculation of mixture of waters with different origin. Hydrochemical indicators (saturation index with calcite (SIc) and dolomite (SId), hydrochemical coefficients, ratio Mg/Ca and salinity). Water aggressivi
V week lectures	Quality of aquatic ecosystems. Environmental terms. Level of ecological organization. Aquatic ecosystems. Horizontal and vertical zoning. Organisms in aquatic ecosystems. Food chain of aquatic ecosystems. Cycle of nitrogen and phosphor in nature.
V week exercises	Quality of aquatic ecosystems. Environmental terms. Level of ecological organization. Aquatic ecosystems. Horizontal and vertical zoning. Organisms in aquatic ecosystems. Food chain of aquatic ecosystems. Cycle of nitrogen and phosphor in nature.
VI week lectures	Eutrophication. Curve of change in dilute ohygen due todischarge of waste water into recipient. Calculation of pollutants concentration in recipient. Saprobity index. Quality components of aquatic ecosystems.
VI week exercises	Eutrophication. Curve of change in dilute ohygen due todischarge of waste water into recipient. Calculation of pollutants concentration in recipient. Saprobity index. Quality components of aquatic ecosystems.
VII week lectures	I TEST; I COLLOQIUM
VII week exercises	I TEST; I COLLOQIUM
VIII week lectures	Contamination of natural waters. Sources of contamination (contaminants). Concentrated and loose contamination sources.
VIII week exercises	Contamination of natural waters. Sources of contamination (contaminants). Concentrated and loose contamination sources.
IX week lectures	Pollution matters (pollutants). Oil and oil derivatives. Detergents. Phenols. Pesticides. Mineral fertilizers. Heavy and toxic metals. Basic processes of transport and transformation of pollutants in water.
IX week exercises	Pollution matters (pollutants). Oil and oil derivatives. Detergents. Phenols. Pesticides. Mineral fertilizers. Heavy and toxic metals. Basic processes of transport and transformation of pollutants in water.
X week lectures	Contamination risk assessment for ground water. Vulnerability maps for ground water. Contamination hazard and risk maps for ground water.
X week exercises	Contamination risk assessment for ground water. Vulnerability maps for ground water. Contamination hazard and risk maps for ground water.
XI week lectures	Protection of drinking water sources. Determination and maintenance of zones and bands of sanitary protection of water sources. Marking the groundwater. Introducing national regulation on determination and maintenance of zones and bands of sanitary protec
XI week exercises	Protection of drinking water sources. Determination and maintenance of zones and bands of sanitary protection of water sources. Marking the groundwater. Introducing national regulation on determination and maintenance of zones and bands of sanitary protec
XII week lectures	Environmental impact assessment from hydrotechnical projects. Contents of elaboration on environmental assessment. Environmental impact assessment from hydrotechnical reservoirs- negative and positive impacts.
XII week exercises	Environmental impact assessment from hydrotechnical projects. Contents of elaboration on environmental assessment. Environmental impact assessment from hydrotechnical reservoirs- negative and positive impacts.
XIII week lectures	Legislation. Overview of national documents regulating water quality. Overview of EU and WHO (World Health Organization) documents on groundwater quality protection.
XIII week exercises	Legislation. Overview of national documents regulating water quality. Overview of EU and WHO (World Health Organization) documents on groundwater quality protection.
XIV week lectures	Repetition of lessons.
XIV week exercises	Repetition of lessons.
XV week lectures	II TEST; II COLLOQUIUM
XV week exercises	II TEST; II COLLOQUIUM

Student workload	Weekly 4.5 credits x 40/30 = 6 hours Total workload for the Subject 4.5x30 = 135 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance, preparation of graphical papers, taking the tests
Consultations	Monday 11.00-13.00
Literature	Literature: Dimitrijević N. (1991) Hidrohemija. Rudarsko-geološki fakultet. OOUR grupa za hidrogeologiju, Univerzitet u Beogradu, Beograd, p. 313 Vujasinović S., Matić I. (2009) Osnovi hidrogeoekologije. Rudarsko-geološki fakultet, Univerzitet
Examination methods	- Attendance to lectures and exercises: max 10 pt - Colloquiums: max 40 pt; - Final exam: max 50 pt; - Pass requires minimum 50 pt.
Special remarks
Comment	Further information about the Subject can be required from the lecturer, assistant, head of the study program and vice dean of academic affairs.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / RIVER FLOW CONTROL

Course:

RIVER FLOW CONTROL/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11951	Obavezan	2	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / MODELING IN HYDROTECHNICS

Course:

MODELING IN HYDROTECHNICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11952	Obavezan	2	5	1+0+3

Programs	INFRASTRUCTURES
Prerequisites
Aims	Gaining basic knowledge in designing and performing the hydrotechnical aspect.
Learning outcomes
Lecturer / Teaching assistant	Dr Goran Sekulić
Methodology	Lectures, exerc., Consultations, homework, etc..

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
I week exercises	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
II week lectures	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
II week exercises	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
III week lectures	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
III week exercises	Basics facts about software BCE-ON to simulate the hydrological processes in nature.
IV week lectures	The basics of the software to determine the probability of a random hydrological size (distribution function) MATSTAT-DISTRIBUTION.
IV week exercises	The basics of the software to determine the probability of a random hydrological size (distribution function) MATSTAT-DISTRIBUTION.
V week lectures	The basics of the software to determine the probability of a random hydrological size (distribution function) MATSTAT-DISTRIBUTION.
V week exercises	The basics of the software to determine the probability of a random hydrological size (distribution function) MATSTAT-DISTRIBUTION.
VI week lectures	COLLOQUIUM I
VI week exercises	COLLOQUIUM I
VII week lectures	Free week
VII week exercises	Free week
VIII week lectures	The basic of software to simulate the water supply networks (EPANET, WESNET)
VIII week exercises	The basic of software to simulate the water supply networks (EPANET, WESNET)
IX week lectures	The basic of software to simulate the water supply networks (EPANET, WESNET)
IX week exercises	The basic of software to simulate the water supply networks (EPANET, WESNET)
X week lectures	The basic of software to simulate sewer networks (EPASWMM, SEWER)
X week exercises	The basic of software to simulate sewer networks (EPASWMM, SEWER)
XI week lectures	The basic of software to simulate sewer networks (EPASWMM, SEWER)
XI week exercises	The basic of software to simulate sewer networks (EPASWMM, SEWER)
XII week lectures	The basic of software to optimize hydropower tunnels and designing HPP
XII week exercises	The basic of software to optimize hydropower tunnels and designing HPP
XIII week lectures	The basic of software to simulate flow in open watercourses and canals (HEC-RAS, REKA)
XIII week exercises	The basic of software to simulate flow in open watercourses and canals (HEC-RAS, REKA)
XIV week lectures	The basic of software to simulate flow in open watercourses and canals (HEC-RAS, REKA)
XIV week exercises	The basic of software to simulate flow in open watercourses and canals (HEC-RAS, REKA)
XV week lectures	COLLOQUIUM II
XV week exercises	COLLOQUIUM II

Student workload	Week 4.5 credits x 40/30 = 6 hours. Total hours for the course 4.5x30 = 135 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 1 sat(a) theoretical classes 3 sat(a) practical classes 0 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods	Knowledge checking is carried out continuously throughout the semester and the final exam. The minimum level of knowledge during the semester for pass rate is 51 points. The maximum possible number of points is 100 / semester.
Special remarks
Comment	Additional information can be obtained at the present teachers, assistants, head of the study program with Dean for Academic Affairs.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / TRAFFIC PLANNING AND SYSTEMS

Course:

TRAFFIC PLANNING AND SYSTEMS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11953	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims	Acquiring basic knowledge of planning and traffic systems.
Learning outcomes	After passing this exam, the student will be able to: 1. Analyze and forecast traffic flows. 2. Plan different aspects and hierarchical levels of transport infrastructure systems.
Lecturer / Teaching assistant	dr Biljana Ivanović - Associate Professor mr Teodora Popović - Teaching Associate
Methodology	Lectures, exercises, graphic work, colloquium and consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Basic parameters of traffic flow.
I week exercises	Basic parameters of traffic flow.
II week lectures	Procedures and devices for measuring traffic flow.
II week exercises	Procedures and devices for measuring traffic flow.
III week lectures	Characteristics of the traffic flow.
III week exercises	Characteristics of the traffic flow.
IV week lectures	Time unevenness of traffic flow.
IV week exercises	Time unevenness of traffic flow.
V week lectures	Relationships between the basic parameters of the traffic flow.
V week exercises	Relationships between the basic parameters of the traffic flow.
VI week lectures	Capacity and level of service on highway.
VI week exercises	Capacity and level of service on highway.
VII week lectures	Capacity and level of service on two-lane roads.
VII week exercises	Capacity and level of service on two-lane roads.
VIII week lectures	Colloquium I.
VIII week exercises	Colloquium I.
IX week lectures	Capacity of priority intersections.
IX week exercises	Capacity of priority intersections.
X week lectures	Capacity on roundabouts.
X week exercises	Capacity on roundabouts.
XI week lectures	Capacity on signalized intersections.
XI week exercises	Capacity on signalized intersections.
XII week lectures	The basics of the traffic planning process in cities.
XII week exercises	The basics of the traffic planning process in cities.
XIII week lectures	Sustainable development of transport in cities.
XIII week exercises	Sustainable development of transport in cities.
XIV week lectures	Traffic planning models.
XIV week exercises	Traffic planning models.
XV week lectures	Colloquium II.
XV week exercises	Colloquium II.

Student workload	Weekly 5 credits x 40/30 = 6 hours and 40 minutes Total workload on the subject 5x30 =150hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance in lectures and exercises, doing graphic work, passing colloquiums.
Consultations	According to the schedule defined at the beginning of the semester.
Literature	M. Maletin: Planiranje i projektovanje saobraćajnica u gradovima.
Examination methods	attendance in lectures and exercises from 1 do 3 poens (student gets 1 poen fr 70% of attendance) - graphic work from 7 to 27 poens - two colloquiums 2x20 poens - final exam up to 30 poens - students pass this subject if the cumulative number of points is 50 poens.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and from the Vice Dean for Teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / MANAGEMENT AND MAINTENANCE OF ROADS

Course:

MANAGEMENT AND MAINTENANCE OF ROADS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11954	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	Pavement construction
Aims	Acquiring knowledge in the field of management methodology for the maintenance of roads and facilities on them. Mastering the knowledge and skills for collecting and processing the data necessary for the assessment of the state of pavement, determination of decision-making models and management systems with the application of informatics.
Learning outcomes	After passing this exam, the student will be able to: 1. Monitor and evaluate the condition and deformations of the roadway construction 2. To form or upgrade the existing database on roads, bridges and traffic 3. To decide on works and carry out work/supervision on the maintenance of the road network, apply modern maintenance methods and equipment.
Lecturer / Teaching assistant	PhD. Katarina Mirković
Methodology	Teaching is conducted through lectures, exercises and consultations, and the students acquired knowledge is checked through seminar work, colloquiums and a final exam. Auditory lectures are conducted with the help of presentation technology. The topics covered are accompanied by appropriate lessons/calculations or examples from practice. Students receive instructions and independently prepare a seminar paper.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introductory lecture on management. Road and maintenance life cycle. History. Concept and area of management system. Levels of decision making.
I week exercises	Examples from practice/calculation examples from the processed methodological unit.
II week lectures	Analysis of road maintenance processes and activities. Methodologies for process and data modeling.
II week exercises	Examples from practice/calculation examples from the processed methodological unit.
III week lectures	Information systems in road network management.
III week exercises	Examples from practice/calculation examples from the processed methodological unit.
IV week lectures	Reference system. Road network databases.
IV week exercises	Examples from practice/calculation examples from the processed methodological unit.
V week lectures	Databases on roads, bridges and traffic.
V week exercises	Examples from practice/calculation examples from the processed methodological unit.
VI week lectures	Methodological basics of facilities management system. Elements for description, maintenance and inspection of facilities.
VI week exercises	Examples from practice/calculation examples from the processed methodological unit.
VII week lectures	I colloquium
VII week exercises	I colloquium
VIII week lectures	Pavement damage processes, influencing factors, damage catalog.
VIII week exercises	Examples from practice/calculation examples from the processed methodological unit.
IX week lectures	Monitoring and assessment of condition, definitions of pavement structure failure, condition indicators and limit values.
IX week exercises	Examples from practice/calculation examples from the processed methodological unit.
X week lectures	Devices and methods for acquisition of road network data.
X week exercises	Examples from practice/calculation examples from the processed methodological unit.
XI week lectures	Road network maintenance works and equipment, organization.
XI week exercises	Examples from practice/calculation examples from the processed methodological unit.
XII week lectures	Modern maintenance treatments for pavement structures.
XII week exercises	Examples from practice/calculation examples from the processed methodological unit.
XIII week lectures	Alternative strategies.
XIII week exercises	Examples from practice/calculation examples from the processed methodological unit.
XIV week lectures	Models of decision making.
XIV week exercises	Examples from practice/calculation examples from the processed methodological unit.
XV week lectures	II colloquium
XV week exercises	II colloquium

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attending lectures and exercises, making graphic/semester papers, preparing for knowledge tests.
Consultations	The consultation date is determined in agreement with the student representative and is held once a week for 2 hours.
Literature	1. Z. Radojković: Sistemi upravljanja kolovozima, Građevinska knjiga, Beograd, 1990. 2. A.Cvetanović: Održavanje puteva, Direkcija za puteve, Beograd, 1993. 3. Đ. Uzelac: Baze podataka o putevima, mostovima i saobraćaju u okviru integrisanog informacionog sistema o putnoj mreži, 4. Đ. Uzelac: Upravljanje održavanjem objekata sa primjerima primjene kod puteva i mostova 5. Haas, Hudson, Zaniewski: Modern Pavement Management, Krieger, 1994. 6. HDM-4 (Highway Development and Management) Documentation. 7.Lichtberger, B.: Track Compendium, Eurailpresss, 2005. 8.Esveld, C.: Modern Railway Track, MRT-Production, 2001.
Examination methods	Semester work max 10 points, activity during the semester max 8 points, colloquiums max 30 points, final exam max 52 points.
Special remarks
Comment	Additional information can be obtained from the subject teacher, associate, head of the study program and vice dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / URBAN COMMUNICATIONS

Course:

URBAN COMMUNICATIONS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11955	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	Geodesy Roads
Aims	Acquiring basic knowledge of Urban Rods.
Learning outcomes	After passing this exam, the student will be able to: 1. Understand the classification of urban roads, their differences, application conditions. 2. Understand the design methodology of urban roads. 3. Apply knowledge to the specific task of the preliminary design of the intersection.
Lecturer / Teaching assistant	dr Biljana Ivanović - Associate Professor mr Teodora Popović - Teaching Associate
Methodology	Lectures, exercises, graphic work, colloquium and consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	City and traffic.
I week exercises	City and traffic.
II week lectures	Urban traffic systems (classification and basic characteristics, functional classification of the urban road network, spatial models, classification of public transport systems).
II week exercises	Urban traffic systems (classification and basic characteristics, functional classification of the urban road network, spatial models, classification of public transport systems).
III week lectures	Program and design conditions for the design of urban roads (traffic load, capacity, level of service of road sections, public tranport and pedestrian paths). Relevant speeds and relevant vehicles.
III week exercises	Program and design conditions for the design of urban roads (traffic load, capacity, level of service of road sections, public tranport and pedestrian paths). Relevant speeds and relevant vehicles.
IV week lectures	The design elements of the roads of the primary road network.
IV week exercises	The design elements of the roads of the primary road network.
V week lectures	Interchanges (grade-separated junctions).
V week exercises	Interchanges (grade-separated junctions).
VI week lectures	Intersections (at-grade junctions).
VI week exercises	Intersections (at-grade junctions).
VII week lectures	Colloquium II.
VII week exercises	Colloquium II.
VIII week lectures	Roundabouts.
VIII week exercises	Roundabouts.
IX week lectures	Roads of the secondary traffic network (planning basics of traffic calming, design elements of access roads, intersections and turnstiles).
IX week exercises	Roads of the secondary traffic network (planning basics of traffic calming, design elements of access roads, intersections and turnstiles).
X week lectures	Parking (planning basics of stationary traffic and principles of capacity planning, classification of parking lots).
X week exercises	Parking (planning basics of stationary traffic and principles of capacity planning, classification of parking lots).
XI week lectures	Design standards and elements of parking lots, at-grade parking lots, parking garages.
XI week exercises	Design standards and elements of parking lots, at-grade parking lots, parking garages.
XII week lectures	Accompanying equipment (curbs, drainage, utility instalations, lighting).
XII week exercises	Accompanying equipment (curbs, drainage, utility instalations, lighting).
XIII week lectures	Signalization (hotizontal and vertical signalization, light signaling, basics of dimensioning).
XIII week exercises	Signalization (hotizontal and vertical signalization, light signaling, basics of dimensioning).
XIV week lectures	Methodology of designing roads in cities.
XIV week exercises	Methodology of designing roads in cities.
XV week lectures	Colloquium II.
XV week exercises	Colloquium II.

Student workload	Weekly 6.0 credits x 40/30 = 8 hours Total workload on the subject 6.0x30 =180hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance in lectures and exercises, doing graphic work, passing colloquiums.
Consultations	According to the schedule defined at the beginning of the semester.
Literature	M. Maletin: Gradske saobraćajnice
Examination methods	- attendance in lectures and exercises from 1 do 3 poens (student gets 1 poen fr 70% of attendance) - graphic work from 7 to 27 poens - two colloquiums 2x20 poens - final exam up to 30 poens - students pass this subject if the cumulative number of points is 50 poens.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and from the Vice Dean for Teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / FUNDAMENTALS OF URBAN PLANNING

Course:

FUNDAMENTALS OF URBAN PLANNING/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11956	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / PAVEMENT STRUCTURES

Course:

PAVEMENT STRUCTURES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11957	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / MAINTENANCE OF RAILWAY TRACKS

Course:

MAINTENANCE OF RAILWAY TRACKS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11958	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / WATER PURIFICATION

Course:

WATER PURIFICATION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11959	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	There is no conditionality.
Aims	Introduction to the principles of drinking water treatment, as well as the treatment of wastewater that arises from the use of water in households, industries, and atmospheric water.
Learning outcomes	After passing the exam in this subject, students will be able to participate independently in the design, implementation, and maintenance of drinking water treatment systems and wastewater treatment as a member of a multidisciplinary team working on such projects.
Lecturer / Teaching assistant	Dr Goran Sekulić
Methodology	The course includes lectures, exercises, graphical work, field trips, and colloquiums.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction, an overview of water treatment and available technologies.
I week exercises	Introduction, an overview of water treatment and available technologies.
II week lectures	Water quality for drinking - sanitary, aesthetic, and technical aspects.
II week exercises	Water quality for drinking - sanitary, aesthetic, and technical aspects.
III week lectures	Selection of the drinking water treatment process. Sampling for analysis.
III week exercises	Selection of the drinking water treatment process. Sampling for analysis.
IV week lectures	Overview of individual processes for drinking water treatment.
IV week exercises	Overview of individual processes for drinking water treatment.
V week lectures	Drinking water treatment plant: plant facilities, functional and hydraulic design of facilities.
V week exercises	Drinking water treatment plant: plant facilities, functional and hydraulic design of facilities.
VI week lectures	Supporting facilities and equipment of the treatment plant, and plant disposition.
VI week exercises	Supporting facilities and equipment of the treatment plant, and plant disposition.
VII week lectures	Hydraulic calculations and hydraulic profile of the treatment plant.
VII week exercises	Hydraulic calculations and hydraulic profile of the treatment plant.
VIII week lectures	Colloquium 1
VIII week exercises	Colloquium 1
IX week lectures	Methods for assessing the quality of wastewater of different origins.
IX week exercises	Methods for assessing the quality of wastewater of different origins.
X week lectures	Methods of wastewater treatment. Functional and hydraulic design of facilities and the treatment plant as a whole.
X week exercises	Methods of wastewater treatment. Functional and hydraulic design of facilities and the treatment plant as a whole.
XI week lectures	Methods of wastewater treatment (physical-chemical, chemical, biological). Wastewater treatment processes (primary, secondary, and tertiary treatment).
XI week exercises	Methods of wastewater treatment (physical-chemical, chemical, biological). Wastewater treatment processes (primary, secondary, and tertiary treatment).
XII week lectures	Primjenjivani uređaji u sklopu postrojenja.
XII week exercises	Primjenjivani uređaji u sklopu postrojenja.
XIII week lectures	Treatment of sludge from wastewater treatment plants.
XIII week exercises	Treatment of sludge from wastewater treatment plants.
XIV week lectures	Mathematical modeling of hydraulic processes in wastewater treatment plants and wastewater receiving bodies.
XIV week exercises	Mathematical modeling of hydraulic processes in wastewater treatment plants and wastewater receiving bodies.
XV week lectures	Colloquium 2
XV week exercises	Colloquium 2

Student workload	The weekly workload of 5 credits x 40/30 = 6.67 hours. Structure: 1 hour of lectures and 3 hours of exercises. 2.67 hours of individual work, including consultations. During the semester: Teaching and final exam (6.67 hours) x 16 = 106.67 hours. Necessary preparations before the start of the semester (administration, enrollment, verification) 2 x (6.67 hours) = 13.33 hours. The total workload for the course 5x30 = 150 hours. Additional work for exam preparation in the retake exam period, including retaking the exam, from 0 to 30 hours (remaining time from the first two items to the total workload of 150 hours for the course). Workload structure: 106.67 hours (Teaching) + 13.33 hours (Preparation) + 30 hours (Additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance at lectures and exercises, completion of graphical assignments, passing colloquiums.
Consultations
Literature	Primary literature: 1. G. Sekulic, I. Cipranic, Municipal Hydrotechnics, Faculty of Civil Engineering, Podgorica, 2015. 2. M. Milojevic, Water Supply and Sewerage of Settlements, Belgrade, 2002. 3. D. LJubisavljević D, A. Đukić, B. Babić B. Wastewater treatment, Faculty of Civil Engineering, Belgrade, 2004. Additional literature: 4. D. Ljubisavljevic, A. Djukic, B. Babic, B. Jovanovic, Municipal Hydrotechnics, Examples from Theory and Practice, Faculty of Civil Engineering, Belgrade, 2001
Examination methods	Knowledge assessment is carried out continuously throughout the semester and on the final exam. A student can earn a maximum of 100 points during the semester. The following are evaluated: Attendance: 2 to 5 points (70% attendance 2 points, 100% attendance 5 points, <70% attendance 0 points) Graphic works: 5x (2.0 to 5.0) = 10 to 25 points (a minimum of 2.0 points is awarded for a positively evaluated graphic work) Midterm exams: 2 x 19 to 35 points Final exam: up to 50 points The minimum and maximum number of points are given. Midterm and final exams are written. The passing grade is obtained if the student collects 50 points, as well as if they earn at least 19 points on both the first and second midterm exams.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program, and vice-dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / MEASUREMENTS IN HYDROTECHNICS

Course:

MEASUREMENTS IN HYDROTECHNICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11960	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / THE USE OF HYDRO POWER RESOURCES

Course:

THE USE OF HYDRO POWER RESOURCES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11961	Obavezan	3	6	3+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / IRRIGATION AND DRAINAGE ENGINEERING

Course:

IRRIGATION AND DRAINAGE ENGINEERING/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11962	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims	Familiarisation with the principles of designing and building improvement facilities.
Learning outcomes	After passing the exam from this subject, students will be able to: independently participate in the design, implementation and maintenance of melioration systems.
Lecturer / Teaching assistant
Methodology	Lectures, exercises, graphic works, colloquiums.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Purpose and area of hydro-technical melioration, water management problems of irrigation and drainage.
I week exercises	Introduction. Purpose and area of hydro-technical melioration, water management problems of irrigation and drainage.
II week lectures	Necessary conditions for the operation of irrigation and drainage systems, environmental problems.
II week exercises	Necessary conditions for the operation of irrigation and drainage systems, environmental problems.
III week lectures	Conditionality of irrigation and drainage, water balance, evaporation, modified methods for calculating evapotranspiration.
III week exercises	Conditionality of irrigation and drainage, water balance, evaporation, modified methods for calculating evapotranspiration.
IV week lectures	Calculation of parameters for determining reference evapotranspiration
IV week exercises	Calculation of parameters for determining reference evapotranspiration
V week lectures	Soil. Physical and thermal properties of the soil, water properties of the soil.
V week exercises	Soil. Physical and thermal properties of the soil, water properties of the soil.
VI week lectures	Chemical properties of soil, biological activities in soil, soil classification.
VI week exercises	Chemical properties of soil, biological activities in soil, soil classification.
VII week lectures	Water flow in unsaturated environments, basic characteristics of water movement, differential equations of unsteady water flow in unsaturated environments.
VII week exercises	Water flow in unsaturated environments, basic characteristics of water movement, differential equations of unsteady water flow in unsaturated environments.
VIII week lectures	COLLOQUIUM I
VIII week exercises	COLLOQUIUM I
IX week lectures	Irrigation mode. Determining the relevant flows for sizing the irrigation system.
IX week exercises	Irrigation mode. Determining the relevant flows for sizing the irrigation system.
X week lectures	Surface gravity watering methods, rain watering, underground watering, drip watering, choice of method and device for watering, supply and distribution network, and facilities on canals.
X week exercises	Surface gravity watering methods, rain watering, underground watering, drip watering, choice of method and device for watering, supply and distribution network, and facilities on canals.
XI week lectures	Fittings, devices and facilities on pipelines for watering, calculation of water hammer in networks and their protection, water intakes, pumping stations.
XI week exercises	Fittings, devices and facilities on pipelines for watering, calculation of water hammer in networks and their protection, water intakes, pumping stations.
XII week lectures	Drainage regime, drainage norms, and methods of water drainage.
XII week exercises	Drainage regime, drainage norms, and methods of water drainage.
XIII week lectures	Calculate horizontal pipe drainage, vertical drainage, protective filters, and drainage system drainage network.
XIII week exercises	Calculate horizontal pipe drainage, vertical drainage, protective filters, and drainage system drainage network.
XIV week lectures	Irrigation and drainage system design, foundations and investigation work, project types and content.
XIV week exercises	Irrigation and drainage system design, foundations and investigation work, project types and content.
XV week lectures	COLLOQUIUM II
XV week exercises	COLLOQUIUM II

Student workload	Weekly: 5 credits x 40/30 = 6.67 Structure: 2 hours of lectures + 2 hours of exercises - 2.67 hours of independent work, including consultations. During the semester: Classes and final exam: (6.67 hours) x 16 = 106.67 hours Necessary preparations before the beginning of the semester (administration, registration, certification) 2 x (6.67 hours) = 13.33 hours. Total workload for the course 5x30 = 150 hours. Supplementary work for exam preparation in the make-up exam period, including taking the make-up exam from 0 to 30 hours (remaining time from the first two items to the total load for the course 150 hours) Load structure: 106.67 hours (Teaching)+13.33 hours (Preparation)+30 hours (Supplementary work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attending lectures and exercises, making graphic works, and passing the colloquium.
Consultations
Literature	1. D. Avakumović: Elementi navodnjavanja I ovodnjavanja, Građevinski fakultet, Beograd, 2005 2. D. Avakumović: Navodnjavanja, Građevinski fakultet, Beograd, 2005. 3. D. Avakumović: Odvodnjavanje, Građevinski fakultet, Beograd, 2005.
Examination methods	Knowledge is checked continuously during the semester and on the final exam. A student can earn a maximum of 100 points during the semester. The following are assessed: - Graphic work: up to 10 points; - Colloquium: up to 30 points - Final exam: up to 60 points. The colloquium and the final exam are done in writing. A passing grade is obtained if 50 points are collected.
Special remarks
Comment	Additional information about the subject can be obtained from the subject teacher, associate, head of the study program and vice dean for teaching.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / HARBORS AND PORTS

Course:

HARBORS AND PORTS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11963	Obavezan	3	4	2+1+1

Programs	INFRASTRUCTURES
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Civil Engineering / INFRASTRUCTURES / GROUNDWATER HYDRAULICS

Course:

GROUNDWATER HYDRAULICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11968	Obavezan	3	5	2+1+1

Programs	INFRASTRUCTURES
Prerequisites	None.
Aims	Knowledge acquisition from groundwater hydraulics.
Learning outcomes	After having passed the exam, students will be able to: 1. Explan functioning of hydrogeological systems; 2. Explain parameters of porosous areas; 3. Understand equations of groundwater streaming; 4. Apply methods for solution of differential equations of groundwater streaming; 5. Create conceptual hydrogeological model; 6. Use MODFLOW-based softwares; 7. Develop a mathematical model of groundwater streaming
Lecturer / Teaching assistant	Prof. Dr. Milan Radulović – lecturer
Methodology	Lectures, exercises, tests, colloquiums.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Groundwater as part of water cycle. Structures of rocks porosity. Hydrogeological function of rocks masses. Recharge and discharge of aquifers. Examples from the territory of Montenegro
I week exercises	Introduction. Groundwater as part of water cycle. Structures of rocks porosity. Hydrogeological function of rocks masses. Recharge and discharge of aquifers. Examples from the territory of Montenegro
II week lectures	Aquifer parameters (hydraulic conductivity, porosity, groundwater velocity, hydraulic gradient, etc.). Darcy law. Heterogeneity and anisotropy of aquifer.
II week exercises	Aquifer parameters (hydraulic conductivity, porosity, groundwater velocity, hydraulic gradient, etc.). Darcy law. Heterogeneity and anisotropy of aquifer.
III week lectures	Groundwater flow through the saturated zone. Flow lines and flow mesh. Basic equatations of groundwater flow. Mass balance equatation. Generalization of Darcy law.
III week exercises	Groundwater flow through the saturated zone. Flow lines and flow mesh. Basic equatations of groundwater flow. Mass balance equatation. Generalization of Darcy law.
IV week lectures	Steady-state groundwater flow in the confined and unconfined aquifers.
IV week exercises	Steady-state groundwater flow in the confined and unconfined aquifers.
V week lectures	Transient groundwater flow in the confined and unconfined aquifers.
V week exercises	Transient groundwater flow in the confined and unconfined aquifers.
VI week lectures	Methods for solving the differential equitation of groundwater flow.
VI week exercises	Methods for solving the differential equitation of groundwater flow.
VII week lectures	I TEST, I COLLOQUIUM
VII week exercises	I TEST, I COLLOQUIUM
VIII week lectures	Numerical models. Transfer of the conceptual model to the numerical model. MODFLOW. Geometry of groundwater model. Parameters of groundwater model.
VIII week exercises	Numerical models. Transfer of the conceptual model to the numerical model. MODFLOW. Geometry of groundwater model. Parameters of groundwater model.
IX week lectures	Boundary conditions. Calibration of groundwater model. Sensitivity analysis. Verification of model.
IX week exercises	Boundary conditions. Calibration of groundwater model. Sensitivity analysis. Verification of model.
X week lectures	Groundwater flow to the well. Pumping test data processing.
X week exercises	Groundwater flow to the well. Pumping test data processing.
XI week lectures	Groundwater flow in the karst aquifer. Limits of Darcy law in the karst aquifers.
XI week exercises	Groundwater flow in the karst aquifer. Limits of Darcy law in the karst aquifers.
XII week lectures	Field investigation works. Groundwater flow through and under dams and embankments.
XII week exercises	Field investigation works. Groundwater flow through and under the dams and embankments.
XIII week lectures	Groundwater inflow to the tunnels and excavations.
XIII week exercises	Groundwater inflow to the tunnels and excavations.
XIV week lectures	II TEST, II COLLOQUIUM
XIV week exercises	II TEST, II COLLOQUIUM
XV week lectures	Repetition of lessons.
XV week exercises	Repetition of lessons.

Student workload	Weekly 3.0 credits x 40/30 = 4 hours Total workload for the Subject 3.0x30 = 90 hours
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Attendance, preparation of graphical papers, taking the tests.
Consultations	Monday, 12.00 - 13.00
Literature	Pušić M. (1994) Hidraulika podzemnih voda. Slavija press, Novi Sad Pušić M. (2003) Dinamika podzemnih voda. Rudarsko-geološki fakultet, Beograd Mandle R. J. (2002) Groundwater modeling guidance. Michigan department of environmental quality.
Examination methods	- Attendance to lectures and exercises: max 4 pt; - Graphic works: max 4 pt; - Seminary Essays: max 10 pt; - Tests: max 12 pt; - Colloquiums: max 40 pt; - Final exam: max 30 pt; - Pass requires minimum 50 pt.
Special remarks
Comment	Further information about the Subject can be required from the lecturer/assistant, head of the study program and vice dean of academic affairs

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points