410 List of Elective Courses in Vehicle Engineering and Heavy Equipment Study Program Elective 1 and Elective 2 Semester 2 2nd Semester SKS ENME 8 0 0511 Teknik Kendaraan Rel 4 ENME 8 0 0512 Mesin dan Peralatan Pengangkat Handling and Construction Equipment 4 Semester 3 3rd Semester Kode Mata Ajaran Subject Sks ENME 8 0 0513 Teknologi Muktahir Kendaraan Modern Vehicle Technology 4 ENME 8 0 0514 Peralatan Pengeboran Minyak dan Gas Oil and Gas Drilling Equipment 4

6. Marine Resources and Technology

KODE MATA AJARAN SUBJECT SKS Semester 1 1 st Semester ENME 8 0 0001 Matematika Teknik Lanjut Advanced Engineering Matematics 4 ENME 8 0 0602 Termoluida Lanjut Advances Thermoluid 4 ENME 8 0 0601 Sumber Daya Maritim Maritime Resources and Technologies 4 Subtotal 12 Semester 2 2 nd Semester ENME 8 0 0003 Desain Penelit ian Design of Experiment 2 ENME800002 Komputasi Teknik dan Simulasi Engineering Computation and Simulation 4 ENME800601 Teknologi Maritim Maritime Technology 4 Pilihan Peminatan 1 Elective 1 4 Subtotal 10 Semester 3 3 rd Semester ENME 8 0 0004 Seminar Seminar 3 Pilihan Peminatan 2 Elective 2 4 Subtotal 7 Semester 4 4 th Semester ENME 8 0 0005 Tesis Thesis 7 Subtotal 7 Total 40 List of elective courses in Marine Resources and Technology Study Program Elective 1 and Elective 2 Semester 2 2nd Semester ENME 8 0 0611 Manajemen Produksi Kapal Ship Production Management 4 ENME 8 0 0612 Kapal Khusus Special Ship 4 ENME 8 0 0613 Teknik Las Welding Engineering 4 ENME 8 0 0102 Optimasi Sistem Energi Energy Optimization System 4 M A S T E R P R O G R A M 411 Semester 3 3rd Semester Kode Mata Ajaran Subject Sks ENME 8 0 0615 Bangunan Lepas Pantai Marine and Offshore Structure 4 ENME 8 0 F616 Manajemen Transportasi Laut dan Kepelabu - hanan Sea Transport and Port Management 4 ENME 8 0 F617 Hukum dan Peraturan Kemaritiman Maritime Law and Regulation 4 For students who are willing and capable to continue the education program to pursue Masters in Engineering through the Fast track program, credit transfer can be performed as many as 20 credits. The numbers of credits that can be transferred consist of: 8 credits from 2 Mandatory Core Courses and 8 credits from 2 Elective Core Courses. M A S T E R P R O G R A M 412 Course Description ENME800001 ADVANCED ENGINEERING MATHEMATICS 4 SKS Course Obj ective: Complete student’s anylitical ability. Students under st and and abl e t o use t he advances mathematical concepts in order to solve the engineering problems Syllabus: Introduction to differential equation, 1 st order differential equation, 2 nd order di f f erent i al equat ion, higher order dif f erent ial equat ion, vector analysis, vector differential, grad opera - t ion, divergence and culr, vect or int egrat ion, laplace transform, laplace transform to solve t he dif f erent ial equat ion, f ourrier t ransf orm, convulsion, numerical met hod, root of equa- t i on, numer i cal di f f er ent i at i on, numer i cal int egral. Requirement: - References: Purcell, E. J. , 1. Cal cul us and Anal yt i c Ge- omet r y , Addison-Wesley, 1996. Anton, Howard, 2. El ement ar y Li near Al ge- br a , John Wiley Sons, 1996. Kreyszig, E., 3. Advance Engi neer i ng Mat h- emat i cs , John Wiley Sons, 2004. ENME800002 ENGINEERING COMPUTATION AND SIMULA- TION 4 SKS Course Obj ective: The purpose of this course is that students know well and are able to apply the processes and met hods al gor i t hms cal cul at i ons nu- merical and anal yt ic of engineering in t he real world of computing and computer-based parameters that affect the speed and accuracy of t he calculat ion. Syllabus : I n t r o d u c t i o n o f C o m p u t e r A p p l i c a - tions: Matlab, Algorithms and Algo - rithm Analysis;Computational Complexity; Al - gorithm Types: Optimization and Representation of Numbers; Overlow and underlow; For - mula Error and Error in Numeric; FiniteD - ifference in Computing Applications: Nu - merical Integration in the Computing Applications; ODE In Applications comput - ing; PDE in computing Applications;Monte Car - lo in computing Applications Requirement: - References: Sedgewick R., Phillippe F, 1. An Int r oduct i on t o t he Anal ysi s of Al gor i t hms , Addi son Wesley. Cheney W., Kincaid D., 2. Numer i cal Mat h- emat i cs and Comput i ng , Cole Publishing ENME800003 DESIGN OF EXPERIMENT 2 SKS Course Obj ective: This course provides knowledge on methods of planning, execution and reporting of the research in the ield of engineering so that students are able to apply scientiic principles in the preparation of the thesis in particular, as well as in a scientiic publication from the research. St udent s should be able t o manage an investigation that began from the planning stages, applying the correct procedure and constructs apparatus design, and apply inst rument at ion and measurement syst ems, to execute and perform the analysis and interpretation of data by the rules of statistics properly. Syllabus: Introduction: Introduction to Research Design, Problem Solving Approaches, Research Project Planning, Design and Application Measurement Systems: Elements of Functional Measurement Systems, Performance Measurement System Characteristics, Analysis of Accuracy Uncertainty Systems, Design and Construction of Apparatus Research, Planning Experiments, execution experiments: Construction of the apparatus, the apparatus Debugging, Datasheet and logbooks; Analysis and Interpretation of data; Communication Engineering: Principles of Communication Engineering, Report, Paper, and Research Articles. Requirement : - References: Montgomery, D.C., 1. Desi gn and Anal ysi s of Exper i ment s, 5th ed., John Wiley and Sons, Inc., New York, 2001 Coleman, H.W., Steele, G.W.Jr., 2. Exper i ment at i on and Uncer t ai nt y Anal ysi s f or Engi neer s , 2nd ed., John Wiley and Sons, Inc., New York, 1999 D o e b e l i n , E . O . , 3. E n g i n e e r i n g Exper i ment at i on: Pl anni ng, Execut i on, Repor t i ng , McGraw-Hill, Inc., New York, 1995 Kirkup, Les., 4. Ex p er i m ent al Met h od : An Int r od u ct i on t o t h e Anal ysi s and Pr esent at i on of Dat a , John Wiley and Sons M A S T E R P R O G R A M 413 Australia, Ltd., Queensland, 1994 Lipson, C, Sheth, N.J., 5. St at i st i cal Desi gn and Anal ysi s of Engi neer i ng Exper i ment s , Mc-Graw Hill Kogakusha, Ltd., Tokyo, 1973 ENME800101 ADVANCED THERMODYNAMICS Course Obj ective: Provide f urt her underst anding of t he science of thermodynamics and its applications so that st udent s are able t o design and conduct a basic research mapun able to complete the analysis involves t he calculat ion of t he t hermodynamic syst em correct ly and syst emat ically in order t o ind the best solution gentang effectiveness of the use of substances and energy, especially in the ‘engineering design’ by motto: ‘Low entropy production’, ‘high thermal eficiency’ and ‘low pollution effect’. Syllabus : Basic Thermodynamics and Gas Dynamics, Equi - librium of Thermodynamics Syst em, Thermo- dynamics properties of System, Thermodyam - ics of ideal gas mixt ure, review of chemical t hermodynamics, review of chemical kinet ics, conservation equation for multicomponent reaction system, pre-mixed laminar lames, method of measuring lame velocity bunsen burner, lame quenching, lamability limit of premixed laminar lame, gaseous diffusion lame and combustion of single liquid droplet, combustion in compression ignition engine, combustion in spark ignition engine, combus - t ion research in hydrocarbon oxygen mixt ure, engine research, combust ion-generat ed emis- sion, experimental method : preseure measure - ment and recording; temperature measure - ment and recording; combustion photography and lame speed detection; spectrographic method; chemical analysis technique NDIR, FID, Gaschromatography. Requirement: - References: Holmann, J.P., Thermodynamics, Intl. Stu - 1. dent Edition, McGraw Hill, 2005. Kenneth Wark Jr. Thermodynamics, McGraw 2. Hill, 2003. Francis F. Huang, Engineering Thermody - 3. namics, MaxWell Macmillan Intl. Edition, 2000. H.D. Baehr, 4. Ter m odynam i k , Springer Verlag K. Stephan, 5. Ter modynami k , Grundlagen und technishe Anwendung-en, Band 1, Band 2, Springer Verlag. Bejan, Adrian, 6. Ad vanced Engi neer i ng Ther modynami cs , Wiley – interscience, 2nd Edition, 1997 ENME800103 ADVANCED FLUID DYNAMICS AND HEAT TRANSFER 4 SKS Course Obj ective: Enhance t he abilit y of st udent s in t he st udy of luid mechanics in more detail so as to conduct research or the application of science in indus - trial applications. Studying the mechanism of heat t ransf er in a cont rol volume due t o t he existence of the temperature difference and concent rat ion as well as t he involvement of one, two or three phases at the time simul - t aneously. Syllabus: Viscous low of Newtonian luid, membrane boundary low, Non-Newtonian Fluid Flow, Two- Multi Phase Flow, Particle Displacement Flow, Porous Media and Fluidized Beds, Turbulent Flow and Mixing, Jet, Chimney, Energy and Momentum Equatio, one-two-three dimension conduct i on heat t r ansf er, heat t r ansf er on ext ended surf ace. Requirement:- References: Frank P Incropere, David P De Witt, 1. Fundamental heat and mass transfer, 5th Ed., John Wiley Sons, 1996, New York Holman JP, Heat Transfer, 9th, Mc Graw 2. Hill, 2003. Koestoer, RA, Perpindahan Kalor untuk 3. Mahasiswa Teknik, Salemba Teknika, 2003. Welty R James, Wicks Charless, Wilson 4. Robert, Fundamentals of Momentum, Heat, and Mass Transfer, 3rd Ed. John Wiley Sons, 1996, New York Cengel, Yunus, Heat Transfer a Practical 5. Approach, 2nd Ed. Mc Graw Hill, 2003, Singapore. Kreith Frank, Bohn Mark, Principles of Heat 6. Transfer, 6th Ed. Brookscole, 2001, USA Abbott I R, Theory of Wing Section, 7. Dover Publicat ions. Bird R B, Transport Phenomena, John 8. Wiley Sons. ENME800111 HEAT AND MASS TRANSFER ENGINEERING 4 SKS Course Obj ective: The course objective is to provide understanding of t he heat exchangers used in many indust rial processes and power plants as the application of heat transfer. This course provides a basic competency to know main heat exchanger types and t o underst and and able t o select suit able M A S T E R P R O G R A M 414 heat exchanger type for current applications. Student is also expected to understand basic f act or s i n desi gni ng heat exchanger s, t o estimate size and price and know and choose the type of heat exchanger. Provide basic understanding and various parameters on the drying process so that students can perform cal cul at i ons and anal ysi s of var i ous dr yi ng techniques and their applications. This course also provides the expertise so that students are able t o do drying modeling, t o design and analyze the system for various materials solid and solvent so that the drying process can be suitably selected for particular product. Syllabus: Heat Transfer Review; Type and Application of Heat Exchangers; Practgical Design of Shell and Tube Heat Exchanger Thermal and Mechanical; Manufacturing Cost Estimation; Heat Exchangers; Operation and Monitoring of Heat Exchangers Fouling And Vibration; Maintenance of Heat Exchangers; Corrossion on Heat Eschangers; Heat Exchanger Design Soft - ware; Present at ion and Laborat ory Pract ice of Heat Exchangers. Review Transfer Phenomena Momentum, Heat and Mass; Drying Principles and Basics; Mathematical Modeling of Drying System; Classiication and Selection of Dryer, Post-Harvest Drying and Storage of Grain; Ro - tary Drying; Vacuum Drying; Fluidized Bed and Spouted Bed Drying; Drum Dryer; Spray Drying, Freeze Drying; Conveyor Drying; Solar Drying; Enrgy Optimization in Drying System; Drying Syst em Design. Requirements: Heat and Mass Transfer, Fluid Mechanics References: Frank P Incropere, David P De Witt, 1. Fundamental heat and mass transfer, 5th Ed.,John Wiley Sons, 2002, New York Holman JP, Heat Transfer, 9th, Mc Graw 2. Hill,2003. Smith Eric, Thermal Design of Heat 3. Exchanger, John Wiley Sons, 1996, New York Welty R James, Wicks Charless, Wilson 4. Robert, Fundamentals of Momentum, Heat, and Mass Transfer, 3rd Ed. John Wiley Sons, 1996, New York. Cengel, Yunus, Heat Transfer a Practical 5. Approach, 2nd Ed. Mc Graw Hill, 2003,Singapore. Kreith Frank, Bohn Mark, Principles of Heat 6. Transfer, 6th Ed. Brookscole, 2001, USA Mujumdar, A.S., Drying : Principles and 7. Practice, in Albright’s Chemical Engineer’s Handbook, Editor, Lyle Albright, Taylor Francis, NY, USA, 2002 Mujumdar, Arun, S., Drying technology in 8. agriculture and food sciences, 2001 Chakraverty, A,. Mujumdar AS and Vijaya 9. Raghavan, Handbook of Postharvest Technology, Marcel Dekker, Inc, New York, 2003 Related Journals : Drying Technology 10. Journals. Rohsenow Warren, Hartnett James, Cho 11. Young, Handbooks of Heat Transfer, 3rd Ed., Mc Graw Hill, 1998, New York. ENME800112 AERODYNAMICS ENGINEERING 4 SKS Course Obj ective: Aerodynamic Engineering is an advanced course of Fluid Mechanics which focusing on aeronau - tics applications. Through the course students is expected to be able to understand the fundamental principles and basic equations of aerodynamics and to apply them in the process of airfoil design and to understand performance charact erist ics of t he airf oil. St udent is able to understand the phenomenon of incompress - ible low through the airfoil and inite wings. Student is expected to be able to have an understanding of subsonic and supersonic com - pressible low phenomena through aerofoil and other compressible low phenomena. Syllabus: Int roduct ion on Aerodynamics; Basic and Prin- ciple Equations; Incompressible low; Airfoil Aerodynamics Characteristics; Finite Wings; Incompressible Flow through Airfoil; Incom - pressible Flow through Finite Wings; Airfoil in Compressible Flow; Wings and Wings-Body Combination in Compressible Flow; Airfoil De - sign; Double Surf ace; Vort ex Lif t ; Secondary Flow and Viscous Effect; Other Phenomena in Compressible Flow; Normal Shock Wave; Oblique Shock Wave; Expansion Wave; Super - sonic Wave. Requirement: - References: A.M. Kuethe and C.Y. Chow, Foundations 1. of Aerodynamics, John Wiley Sons, Inc., 1997. B . W. M c C o r m i c k , A e r o d y n a m i c s , 2. Aeronautics, and Flight Mechanics, John Wiley Sons,Inc., 1995. J Anderson, Fundament als of Aerodynamics, 3. McGraw Hill, 2001. ENME800113 POWER GENERATION 4 SKS Course Obj ective: The course objective is to provide an un - derstanding of the basic principles of power generation, and basic competency in the design and development of power generation M A S T E R P R O G R A M 415 syst ems. Syllabus: Indust r i al Pow er Pl ant and St eam Syst em: Boiler, Steam Turbine, Gas Turbine; Cogenera - tion Engineering, Instrumentation and Main Tools; Performance and Reliability Factors; Economical Aspects, Environmental Aspects: Set t ings and Prevent ion. Requirement: - References: Tyler G. Hicks, Power Plant Evaluation 1. and Design Reference Guide, McGraw Hill, 1986. Sill and Zoner, Steam Turbine Generator 2. Process Controll and Diagnostics, Wiley Higher Ed., 1996. Saranavamuttoo et.al, Gas Turbine Theory, 3. 5th Edition, Prentice Hall, 2001 ENME800114 COMBUSTION ENGINEERING 4 SKS Course Obj ective: Combustion Engineering provide basic compe - tency to investigate, analyze and learn about the process of combustion of fuel, and the na - ture and behavior of lame. The course provides basic understanding to apply the laws of basic aerot hermochemist ry in t he engineering cal- culation of practical combustion engineering. The student is expected to be able to analyze the combustion behavior of a lame and to develop knowledge in the ield of combustion engineering. Syllabus: Important Meaning of Combustion Study; Basic Reaction and Stoikhiometry of Combustion; Gas Fuel BBG; Liquid Fuel, Solid Fuel; Basic Thermochemistry and Fluid Dynamics of Com - bustion; Principles of Conservation of Mass and Continuity; Turbulence Premixed Flame Structure; Detonation; Combustion Technology; Fixed-Bed Combustion, Suspension, Fluidized- Bed; Study on Flame and Combustion Technol - ogy; Minimum Temperature Self-ignition Auto Self-Ignition; Flammability Limit; Fire spread, Fire Suppression Material, Combustion and the environment . Requirement: - References: Turn, S.R., An Introduction to Combustion, 1. 2nd Edition, McGraw-Hill, Inc. 2000 Borman, G.L., and Ragland, K.W., 2. Combustion Engineering, McGraw-Hill, Inc. 1998. Griffi ths, J.F., and Barnard, J.A., Flame 3. and Combustion, 3rd Edition, Blackie Academic and Professional, 1995. Glassman, I., Combustion, 3rd Edition, 4. Academic Press, 1996. Warnatz, J., Maas, U., and Dibble R.W., 5. Combustion, 2nd Edition, Springer-Verlag, 1998. ENME800115 INTERNAL COMBUSTION ENGINE 4 SKS Course Obj ective: Student is expected to have competency and expertise in the ield of his interest of inter - nal combustion engine working principle and t heory and is able t o design and do const ruct ion calculat ion. Syllabus: Actual Cycle of Internal Combustion Engine; Fuel System; Ignition and Combustion in Spark Ignition Engine and Compressed Ignition Engine; Some Basic Characteristics and Calculations; Basic Engine Design; Det erminat ion of Engine’s Main Components; Kinematics and Dynamics Analysis of the Motion; Calculation and Plan - ning of Lubrication and Cooling System. Requirement: - References: Guzela L, Onder, C., Introduction 1. to Modelling and Control of Internal Combustion Engines, Springer, 2004 Heywood, J., Internal Combustion Engines 2. Fundamental, McGraw Hill, 1989 Taylor, C.F., Internal Combustion Engines, 3. in Theory and Practice, M.I.T Press, England, 1985. Khovakh, M., Motor Vehicle Engines, MIR 4. Publisher, Moscow, 1971. ENME800116 APPLIED FLOW MEASUREMENT AND VISUAL- IZATION Course Obj ective: Applied low diagnostic study measurement and visualization techniques which have wide application both in industry and laboratory. The course give basic competency for the student t o be bal e t o underst and vari ous measure- ment and visualization methods and to design appropriate low diagnostic system in process installation in industry or experimental set up in a scientiic research activities which related to luid low. Syllabus : Statistics Diagnostic Flow, Calibration in Flow Measurement; Momentum Sensing Meter oriice plate, venturi, nozzle meters; Posi - tive Displacement Flow Meter Nutating Disc, Sliding Vane, Gear meters, etc.; Electromag - netic and Ultrasonic Flow Meters; Compressible Flow Meter Wet Gas and Wind Anemometer; Principles Local Velocity Measurement in Liq - uid and Gases; Hot Wire Anemometry; Based M A S T E R P R O G R A M 416 Laser Velocimetry LDV, PIV; Principles of Flow Visualization, Flow Visualization conven - tional; Shadowgraphs and Schliern Technique; Int erf eromet ry Technique; Light Sheet Based Technique ; Image Processing and Computer- Assisted Method Requirement: - References: Yang ,W.J, Handbook of Flow Visualization, 1. Taylor and Francis. 2001 Baker, R.C., Flow Measurement Handbook: 2. Industrial Designs, Operating Principles, Performance and Applications, Cambridge University Press, 2000 ENME800102 ENERGY OPTIMIZATION SYSTEM Course Obj ective: This course provides an understanding of math - ematical modeling, simulation and optimiza - t ion of energy syst ems t hrough t echnical and economical approach. The course is intended to equip student with the ability to understand mathematical model, simulation and optimiza - t ion of t hermal syst ems. Syllabus: Workabl e Syst em Design; Economical Eval u- ation; Determination of Mathematical Equa - tions; Thermal Equipment Modeling; System Simulation; System Optimization: Objective Function, Constraints; Lagrange Multipliers: Lagrange multiplier to complete the optimiza - tion process; Dynamics, Geometric and Linear Programming; Mathematical Model of Thermo - dynamics Properties; Big System Simulation under Steady Condition; Big Thermal System Simulation; Calculation of Variables in Opti - mum Conditions. Requirement: - References: St oecker, W. F. , 1. Desi gn of Ther mal Syst em , Mc.Graw Hill Book Co, 1989. Boehm,R.F., 2. Desi gn of Anal ysi s of Ther mal Syst em, John WileySons,1987. Yogesh Jaluria, 3. Desi gn and Opt i mi zat i on of Ther mal Syst ems , Mc.Graw Hill Book Co, 1998. ENME800203 FIRE DYNAMICS AND MODELLING Course Obj ective: Sudents understand the various stages of ires in buildings, and provide basic knowledge mengenai ber bagai met hods and t echni ques applied in the analysis of ire development, and develop students’ ability to critically analyze the methods of practical application. This course also aims to improve the ability to understand and analyze the model. Broadly speaking, after completing this course students will be able t o: Explain the effects on the growth of • the fire compartment. Explain the various applications of the • model and it s limit at ions in f ire saf et y engineering calculat ions. Able to explain the growth stage • yangapi by various variables. St udent s will have t he skills and • kemanpuan in: Applying a two-zone models in the • calculat ion of t he various cases of f ire, Calculating the value of various • physical variables related to fire growt h, Analyze and interpret the results of fire • safety engineering experiments. Assessing t he reasonableness of t he • calculat ion result s obt ained f rom a variety of computational models Estimate the value of the data for input • into the computational model Designing a fire plan so that it can • be used in the design of protection syst ems and smoke and gas handling combustion products. Evaluat e t he ef f ect of t he f ire on t he • people in the building For t he f ire in t he building, st udent s • can calculat e t he crit ical condit ions wakt usebelum achieved Maintain, in lisandan written, and • presented a selection of models and assumptions in the analysis of a given case of f ire. Syllabus: Introduction to the process of combustion, premixed lame and diffusion lame, ignition and spread of ire, classiication of ires and the inluence of the geometry of the room. Calorimetry ire: heat release rate, mass loss rate and the relationship between time and heat release rate, the growth of ire in the room, as well as t est ing met hods. The dynam- ics of the lame: ire plume and lame lame, a high lame, the lame height correlation, Froude Numbers, and the lame jet and a review of related models; the low of gas in the room during the ire, Bernoulli equations, proiles of temperature and pressure, air mass low of combustion product gases through the openings; energy balance, heat transfer, heat lux, the correlation to temperature. Products of combust ion: t he f ormat ion of smoke, t he visibility factor, illing model of smoke in a compartment, the formation of CO, CO2. Fire modeling: Two-zone models, CFD models. Analysis of lammable materials effect, the ge - M A S T E R P R O G R A M 417 ometry of the room and opening to the growth of lame, smoke and combustion products. Proposed efforts to suppress the growth and spread of lame and smoke. References: Dougal Dysdal e, An Int roduct ion t o Fire 1. Dynamics 2nd Ed., John Wiley and Sons, 2003. Soci et y of Fi r e Pr ot ect i on Engi neer s, 2. The SFPE Handbook of Fire Protection Engineering, 3rd Edition, 2003. A.H. Buchanan, Fire Engineering Design 3. Guide, New Zealand, 2001. Journal dan st andard t erkait . 4. ENME800211 VENTILATION AND AIR CONDITIONING SYSTEM 4 SKS Course Obj ective : This course provide the understanding and ba - sic competence in design the air conditioning syst em regarding a bet t er air condit ion. The student will provided with knowledge about the environment ally f riendly regrigerant . Syllabus : Basic of Air Conditioning: Air Cooled dan Water Cooled Chiller, Packaged Unit, Direct Expansion and Split Unit; Basic VAC Calculation : Design Condition, Load Estimating, Cooling Load; Sistem Ventilasi : Air Changes, Outdoor Air Requirement, Indoor Air Quality. Clean Space and Air Filter System in industry and hospotal; distribution system: Equal Friction Method and Static Regain, Duct and Piping Sizing; Air Conditioning System Components : Chiller, Cooling Tower, Fan, S and AHU; Control System in Building. Requirement: Teknik Pendingin References : Ronald Howell, Harry J.Sauer, Jr and 1. William J.Coad : Principles of HVAC, ASHRAE 1998. Carrier : Handbook of HVAC 2. ASHRAE Standard 3. Overseas Vocational Training Association 4. Employment Promotion Corporation : Fundament al s of r ef r i ger at i on and Ai r Conditioning. ENME800201 ENERGY AND SAFETY IN BUILDING Course Obj ective: The aims and out comes of t his course is t o develop an understanding of the environ - mental and energy elements applying to buildings. It deals with the energy implica - t ions of t he select ion and cont rol of t hermal, lighting, acoustics, and transportation, and saf et y in buildings. In det ails it also discuss t he heat ing and cooling syst ems in buildings, the role of condensing boilers, heat pumps, combined heat and power CHP and absorp - t ion chilling, as well as convent ional heat ing ventilation air conditioning HVAC plant, in the consumption of energy in buildings. It combines t heoret ical knowledge of t he com- ponents in building utility system that make up energy systems demand and supply in buildings with whole system appraisal. Syllabus: Identify the environmental elements ap - 1. plying to buildings Recognize our human needs relating to 2. buildings Building design: propose ways to control 3. the building’s response to the outside environment , select t he adequat e design and mat erials f or a given building con- iguration Building mat erials 4. Thermal aspects of a building 5. Lighting aspects of a building 6. Acoustic aspects of a building 7. Transportation in building 8. Lif e saf et y in building 9. Int roduct ion t o building ut ilit y syst em 10. and appraisal. ENME800202 BUILDING MECHANICAL AND ELECTRICAL SYSTEM 4 SKS Course Obj ective: The course’s objective is to deliver knowledge, ski l l s and underst andi ng of t he mechani cal and elect rical syst ems in a modern building t hat has been increasing in it s requirement s in terms of sophistication, eficiency, and low energy use. Syllabus: General Building Mechanical System, Plumb - ing System: SNI, Calculation, Waste Water Management, Building Energy System; Building Automation System; Lift and Escalator: Types, Round Trip Time, Handling Capacity, Waiting Time, Installation and Control System; Escala - tor Types, Application and Installation, Building Aut omat ion Syst em, Requirement:- References: Mechanical System for Building. 1. Handbook of HVAC. 2. ASHRAE Journal 3. NFPA 4. Mechanical Installation in Building. 5. SNI Plambing 6. SNI Hydrant, Sprinkler dan APAR. 7. M A S T E R P R O G R A M 418 ENME800212 BUILDING UTILITY SYSTEM DESIGN Course Obj ective: St udent s have t he abilit y t o design and calculat e t he ut ilit y of building int egrat ed syst ems, using knowledge, design crit eria, st andards and relat ed regulat ions. Syllabus: Integrated design include building envelope, light ing syst ems, mechanical and elect rical construction, HVAC systems, and automation syst ems, t aking int o account t he environ- ment al and economic const raint s. Requirement:- References: Anil Ahuja, Integrated ME Design: Building 1. systems engineering, Chapman Hall - International Thomson Publishing, 2000. Richard R. Janis and William K. Y. Tao, 2. Mechanical Electrical Systems in Buildings 4th Edition, 2008. SFPE Handbook of Fire Protection 3. Engineering, 2008 ASHRAE Handbook – HVAC Application, 4. 2012 American Societ y of Plumbing Engineers, 5. Plumbing Engineering Design Handbook, A Plumbing Engineer’s Guide to System Design and Specifications, 2004. Related standard and journals. 6. ENME800213 ENERGY AUDIT 4 SKS Course Obj ective: This course f ocuses on t he t heory, t echniques and practices of analyzing energy aspects of building operations and correlating a building envelope’s interaction with the mechanical systems. Students will perform a detailed energy audit of a st at e-of -t he-art commer- cial building design using energy modeling simulation software and develop energy con - servat ion st rat egies, such as t hermal st or- age, that can be applied to heating, cooling, and ventilating equipment to reduce utility bills. Students will apply supporting analyti - cal data to develop operations and mainte - nance changes designed to improve energy eficiency and reduce operating cost. Syllabus Energy Audit ing Basics, Energy Account ing and Analysis, Underst anding t he Ut ilit y Bill, Energy Economics, Survey Inst rument at ion, The Building Envelope Audit, The Electri - cal System Audit, The Heating, Ventilating and Air-Conditioning Audit, Upgrading HVAC Systems for Energy Eficiency Veriication of System Performance, Maintenance and Energy Audits, Self-Evaluation Checklists, World-class Energy Assessmeent s, and Wat er Conservation Requirement:- References: Albert Thumann, William J. Younger, 1. Terry Niehus, Handbook of Energy Audit s, Eight h Edit ion, The Fairmont Press, 2010. Moncef Krarti, Energy Audit of Building 2. Systems: An Engineering Approach, Second Edition, CRC Press, Taylor Francis Group, 2010. ENME800214 REFRIGERATION ENGINEERING 4 SKS Course Obj ective: Refrigeration engineering course provides basic competency for the student to be able to do t he simulat ion sof t ware t o design a cooling sys- tem and equipments involved with a very close relationship with the Industrial and engineering users. Hence student will have understanding in design and development of cooling system and ability to evaluate and analyze its perfor - mance, especially on clod storage. Syllabus: Principles of Refrigeration and Heat Pump, Terminology and Units; Mechanical Vapor Com - pression Refrigeration Engine; Heat Trasnfer in Refrigeration System; ph Diagram Calculation in Refrigeration Cycle; Refrigeran, Lubricant, Salt and the Environment; Compressors; Con - denser and Evaporator; Refrigeration Piping System and Equipments; Automatic Control System and Safety Equipments; Air Proper - ties; Psychrometric and its process; Absorption Refrigeration; Alternative refrigeration Cycles adsorption, gas compression, and ejector; Display Case, Prefabricated Cold Storage and Cold Storage, Cold Room Calculations. Prerequisite: Basic Thermodynamics References: ASHRAE Handbook of Fundament al 1. , ASHRAE Atlanta, 1995. Kuehn, Ramsey and Therkeld, 2. Ther mal Envi r onment al Engi neer i ng, 3 r d Edi t i on , Prentice Hall, 1998. Thr ekel d, JL. , 3. Ther m al Envi r onm ent al Engi neer i ng , Prentice Hall . ASHRAE Handbook of Fundament al , 4. ASHRAE Atlanta, 20 01 ASHRAE Han d b ook of Ref r i ger at i on 5. , ASHRAE, Atlanta, 2002. M A S T E R P R O G R A M 419 ENME800215 FIRE SAFETY AND PROTECTION ENGINEERING 4 SKS Course Obj ective: Students understand the basic and important parameters in the process of ire and ire haz - ards. Students have the competency on the regul at ions and st andards on t he t est ing of material of the ire and the design of ire pro - tection systems. Students have the expertise in specialized skills in ire modeling, designing and analyzing the protection system against ire. Students know the role of safety manage - ment on the ire hazard in ensuring the industry and high rise building operations. Syllabus: Int roduct ion of Fire Process; Fire Dynamics; dangerous Elements Release in Fire; Fire Mod - eling Theory; Fire Modeling with Computer Pro - gram; Material Testing Method for Fire Hazard; Fire Detection Systems; Standard Rules on Fire Hazard; Fire Protection System Design Fire, Fire Fighting Systems: Hydrant and Sprinkler System; Analysis of Fire Risk in Buildings. Prerequisite: None References: Dougal Dysdale, 1. An Int r oduct i on t o Fi r e Dynami cs 2 nd Ed. , John Wiley and Sons, 2003. Societ y of Fire Prot ect ion Engineers, 2. The SFPE Handbook of Fi r e Pr ot ect i on Engi - neer i ng , 3rd Edition, 2003. Rasbach, D.J., et al., 3. Eval uat i on of Fi r e Saf et y , John Wiley and Sons, 2004. A.H. Buchanan, 4. Fi r e Engi neer i ng Desi gn Gui de , New Zealand, 2001. SNI, ASTM, NFPA, rules and standards 5. ENME800302 MATERIAL AND MANUFACTURING PROCESSES Course Obj ective: The course provides understanding and basic competence of theory, application method and product manufacturing processes that covers: working principle, process characteristics, process limitations, work and force due to the process, parameters that affects to the process and the relation of material with the process that needed for certain process. Syllabi: Manufacturing Process and Production Systems; Materials in Manufacturing; Theory and Method of Casting Processes; Theory and Method of Bul k Def ormat i on Processes; Theory and Method of Metal Forming Processes; Theory and Method of Powder Metalurgy Processes; Theory and Method of Material Machining Cutting Processes; Theory and Method for En - hancing Manufactured Surface Quality; Theory and Method of Joining Processes; Theory and Method of Prototyping; Engineering Material Characteristics; The Relation between Process Characteristics and Material Characteristics; The Parameter Control of Process for Mate - rial; Assignment in Manufacturing Process and Material Selection for Market Needs. Prerequisite: Engineering Materials References: Ashby, 1. Mat er i al sel ect i on i n Mechani cal Desi gn , Butterworrth Heinneman, 2005 Ashby, 2. Mat er i al sel ect i on i n Mechani cal Engi neer i ng , Pergamon Press, 2004 Degarmo, E. Paul, 3. Mat er i al s and Pr ocesses i n Manuf act ur i ng , Prentice Hall Int. Inc, 8th edition, 2005 Kalpakjian, S, 4. Manuf act ur i ng Engi neer i ng and Technol ogy , McGraw Hill 4th edition, 2001. ENME800301 PRODUCT DESIGN AND DEVELOPMENT METHODOLOGY 4 SKS Course Obj ective: Provide an underst anding and mast ery of t he t heory and met hodology of design and product development include: planning, con - cept development, system design, detailed design, testing and screening, production ramp-up, in a series of factors to consider overall product development. Syllabus: Product Planning: Needs Identiication Met - hods; Product Selection Method Feasibility Study; Business Speciications: Concept Deve - lopment and Selection; Aspects of Engineering in Product Development and Manufacturing Process, Material, Thermal, Durability Non- Technical Aspects in Product Development and Manufacturing; basic Design for Manufacturing and Assembly; Calculation of Economics of Product Development. Requirement: - References: Karl T. Ulrich. 1. Pr oduct Desi gn and Devel - opment , 3rd edition, Mc.Graw Hill 2004. Dieter, G.E., 2. Engi neer i ng Desi gn , 3rd edition, Mc.Graw Hill 2000 M A S T E R P R O G R A M 420 ENME800401 MANUFACTURING SYSTEM AND PROCESSES 4 SKS Course Obj ective: College process and manufacturing systems are given in order f or st udent s t o know and be able to apply the conventional manufacturing process technology and non-conventional for the manufacture of a product and the parameters which inluence it are devoted to the metal forming processes, machining, rapid- prototyping process. In addition, knowing, and understanding the existing production systems in t he indust ry. Syllabus: Materials in Manufacturing: Theory and Method of Casting Process Metal Casting; Theory and Method of Bulk Formation Processes: Theory and Method of Formation Process Material Sheet Sheet Metal Forming: Theory and Methods of Powder Metallurgy Process Powder Metalurgy; Theory and Methods for Machining Processes Cutting Materials: Theory and Methods of Product Surface Quality Improvement process: Concepts and methods of manuf act uring syst ems. Requirement : - References : Wagoner R., Chenot J.-L, 1. Fundament al s of Met al For mi ng , John Wiley Sons, Inc, 2003 Degarmo P. , 2. Mat er i al s and Pr ocess i n Manuf act ur i ng , Prentice Hall, 2004 Schey J. , 3. Int r oduct i on t o Manuf act ur i ng Pr ocess , McGraw-Hill, 2004 Thomas E Vollman, 4. Manuf act ur i ng Pl anni ng and Cont r ol , McGraw Hill 1997 Stanley B. Gershwin, 5. Manuf act ur i ng Syst em Engi neer i ng , Prentice Hall, 1993 John M. Nicholas, 6. Compet i t i ve Manuf act ur i ng Management , 1997 ENME800403 MANUFACTURING INFORMANTION SYSTEM MANANGEMENT 4 SKS Course Obj ective: Provide underst anding of t he t heory, met hod and application of information technology systems, management, and development of the concept of knowledge-based information systems Knowledge Management System and capable to apply in the manufacturing indust ry. Syllabus : Int roduct ion t o Inf ormat ion Syst ems; St at e of The Art Utilization Information System; Theory and System Methodology; Database Manage - ment Systems; System Design I: Overview f unct ionalit y, enabling Technology Aut omat ed Solution Assessments Quality, Multi Data Rep - resentation, Database Technology and XML; Design Syst em II: Dat abase Design, Inf ormat ion Input, Output Information; Case Study: Docu - mentation automation and Reporting System for Manufacturing; Introduction Knowledge Base Engineering, Concepts and Methodology in the KBE System Specialists, Neural Network; KBE application. Prerequisites: None References: Raymond McLeod Jr., 1. St r at egi c Inf or ma- t i on Management : Chal l enges and St r at e- gi es i n Managi ng Inf or mat i on Syst em , 3 rd ed, Butterworth-Heinneman, 2003 Cortada, James. 2. Tot al Qual i t y Manage- ment , Mc Graw Hill Book Co Ake, Kevin et . al, 3. Inf or mat i on Technol ogy f or Manuf act ur i ng: Reduci ng Cost s and Expandi ng Capabi l i t es , CRC Press 2003 Cecelja, Franco, 4. Manuf act ur i ng Inf or ma- t i on and Dat a Syst em: Anal ysi s Desi gn and Pr act i ce , Butterworth-Heinemann 2001 ENME800311 DESIGN FOR MANUFACTURE AND ASSEMBLY 4 SKS Course Obj ective: Provide knowledge, underst anding and com- petence in the product design process which is considering, including f act or and orient ed on: material, manufacturing capability and assembling process. Therefore the product is expected to have made ease of manufacture and assembly. Sillaby: Review of the materials selection and pro - cesses, product design for manual assembly, design for automated assembly, PCB design for manufacture and assembly, machining process design, injection molding, sheet metal forming processes, die-casting. Prerequisite: None References: Boot hroyd, Pr oduct Desi gn f or Manuf act ur e and Assembl y , Marcel Dekker Inc, 2002 ENME800312 MECHANICAL FAILURE 4 SKS Course Obj ective: This course provides an understanding and M A S T E R P R O G R A M 421 competence about principles and modes of mechanical f ailure may occur and should be avoided so t hat should be considered in t he desi gn of mechani cal , i ncl udi ng buckl i ng, Corrosion, fatigue, creep, melting, fracture, t hermal, and wear. Sillaby: Theory and Buckling Mode Torsional-lateral, Plastic, Dynamic, Theory and Corrosion mode Metal, Non-Metal, Glass; Corrosion Preven - tion; Theory and Fatigue Failure Mode; Theory and creep mode; Theory and Melting Mode; Theory and Type of Fracture mode, Theory and t he t her mal f ai l ur e mode; Theor y and Wear mode; Failure Analysis and Prevent ion t o: Buckling, Corrosion, Fatigue, creep, Melting, Fract ure, Thermal, and Wear. Pr er equisit es: Engineering Material, Basic Mechanical Design, Mechanical Design References: Jack A Collins, 1. Mat er i al s Fai l ur e i n Me- chani cal Desi gn , Wi l ey - Int er sci ence, 1993 S. Suresh, 2. Fat i gue of Mat er i al s , Cambridge University Press, 1998 M Jansenn, J. Zuidema, 3. Fr act ur e Mechan- i cs , VSSD, 2006 Arthur J. McEvily, 4. Met al Fai l ur es : Mecha- ni sms, Anal ysi s and Pr event i on , 2001 ENMEB00313 NOISE AND VIBRATION Course Obj ective : This course provides competency to students to complete the issue of application of vibration on t he mechanical st ruct ure of t he const ruct ion, and plate or vessel vessel, perform the calculation of vibrat ion reducer syst em design, syst em and en- gine holder enhancing of production equipment. Finally st udent s have t o make a basic vibrat ion measurements, forecasts predicted the damage engine, t he vibrat ion analysis of t he dat a signal and the vibration spectrum and carry out machine performance diagnosis based on data analysis of vibrat ion dat a and ot her dat a relat ed Syllabus : Mechanical vibration with Many Degrees Freedom; Vibration on the Structure Construction; Vibra - tion on plate and body shell Vibration Plate and Shel l ; Vibrat ion Isol at ion; Designing Vibrat ion Absorber; Engineering Vibration Measurement; Vibration spectrum analysis; Performance Diag - nostic Machine. Prerequisites: Numerical Computation, Mechani - cal Vibration, Maintenance and Machine Cond. Minitoring References: Jerry H.G., 1. “ Mechani cal and St r uct ur al Vi br at i ons ”, John Wiley, 2004 Demeter G.F., “ 2. Mechani cal and St r uct ur al Vi br at i ons ”, John Wiley, 1995 Kenneth G.M., “ 3. Vi br at i on Test i ng-Theor y and pr act i ce ”, John Wiley, 1995 Wer ner Soedel , “ 4. Vi br at i ons of Shel l s and Pl at es ”, 3rd edition – revised and expanded, Marcel Dekker, INC., 2004 Randall R.B., “ 5. Fr equency Anal ysi s ”, Brüel Kjær, 1987 Jens T. B. , “ 6. Mechani cal Vi br at i on and Shock Measur ement ”, Brüel Kjær, 1980 ENME800314 MICROFABRICATION AND PRECISION MANU- FACTURING 4 SKS Course Obj ective: This course provides expertise of micro manu - facturing process widely used in the making of MEMS micro Electro mechanical system at this time that has wide application of the biomedic syst em, sensors and micro-elect ronic devices elect ronic devices. This course giving underst anding of manuf act uring t echniques and basic structure mechanics in a product and also the micro-characterization of the process fabrication conducted in the labora - tory. This course provides a basic competency of the principles in the design techniques which control the movement of the size or dimensions in a very small if compared with the size of the object that is designed and produced the correct design and the development machine and a precision mechanism. Lectures focus on the practical concepts that can be directly ap - plied to the design process. Laboratory sessions will be provided in the form of a group where there tried to apply the principles learned in an act ivit y. . Syllabus: Introduction to Engineering Micro Fabrica - tion; Lithography: The design aspect, ma SKS making, et ching t echnique And Wet Et ching Dry Etching; Deposisi Engineering: Chemistry and Chemicals; Electroplating, Micromolding, Beam Processing; Microscaling consideration; Transport Processes and Metrology in the micro-scope; Lab Practice and Applications. Philosophy Precision Manufacturing; kinematic concept; Pro and contra Flexures Design; Ma - terials for Precision Components; Self Calibra - tion Concept; Manufacturing Process which is Important in Precision Manufacturing, Precision Instruments; Basic Concept of Tolerance on Dimensions and geomet ric. Requirement: - References: M a d o u , M . J . F u n d a m e n t a l s o f 1. m i c r o f a b r i c a t i o n : t h e sc i e n c e o f M A S T E R P R O G R A M 422 miniaturization, CRC Press, 2002. McGeough, J Ed., Micromachining of 2. Engineering Materials, Marcel Dekker, 2002, ISBN 0-8247-0644-7 Mainsah, E., Greenwood J.A. and 3. Chetwynd D.G. Metrology and properties of engineering surf aces, Kluwer Academic Publ., 2001 Gardner J.W. and Hingle H.T. Ed. From 4. Instrumentation to Nanotechnology, Gordon and Breach Science Publishers, 1991, ISBN 2-88124-794-. Korvink J.G. and Greiner A. Semiconductors 5. for Micro- and Nanotechnology – An Introduction for Engineers, WILEY-VCH Verlag GmbH, 2002, ISBN 3-527-30257-3. Mark J. Jackson, Microfabrication and 6. nanomanuf act uring. Tayl or and Francis, 2006. Dor nf el d, D. , Lee Dae- Eun, 7. Pr eci si on Manuf act ur i ng , Springer, 2008, ISBN 978- 0-387-32467-8 Smith, S. T., Chetwynd, D. G., 8. Foundat i ons of Ul t r apr eci si on Mechani sm Desi gn , Tay- lor Francis, 1992, ISBN 288-449-0019. Evans, C. E., 9. Pr eci si on Engi neer i ng: An Evol ut i onar y Vi ew , Cranield Press, Bed - ford, UK, 1989. TJ15 .E9 1989, RBR ENME800315 DYNAMICS OF MECHANICAL SYSTEM 4 SKS Course Obj ective: Provide an understanding and competence in the principles and methods of dynamic analysis of mechanical systems as an important input in the design process to produce a mechanical syst em t hat has a bet t er dynamic resist ance and also know the effects they impose on other syst ems t hat int eract . Syllabus: Kinematic Systems: Theory and Principles of Dynamic Systems: Dynamic Modeling Method: Block Diagrams and State-Variable Model: Analysis on Time-Domain Syst em: Analysis of t he Frequency-Domain Syst em; Vibrat ion; St a- bilit y: Dynamic Balance: Dynamic Analysis of Mechanical Components; Modeling and Analysis cont rol syst em. Requirement: - References: Palm, 1. Model l i ng, Anal ysi s, and Cont r ol of Dynami c Syst ems , Wiley, 2006 Harold Joseph dan Ronald Huston, 2. Dy- nami c of Mechani cal Syst em , CRC, 2002 Palm, 3. Syst em Dynami cs , McGraw-Hill, 2007 Chapman, Stephen J., 4. Essent i al s of Mat - l ab Pr ogr ammi ng , Thomson Nelson, 2006 ENME800316 COMPOSITE PRODUCT DEVELOPMENT Course Obj ective: Provide expertise and competence to students in the ield of designing and manufacturing of parts mechanical construction using composite materials. This course provides an understanding of composite materials, includ - ing t he charact erist ics, t est ing, manuf act uring process, and special applications in the engi - neering ield. Syllabus: Composite Type, Material, Properties, Me - chanics; Knowledge and Characteristics of Fiber Composite, Strength, Hardness, and the composite thermal expansion; Theory of Com - bination Fiber and Matrix; Matrix Composite Characterization; Laminar Theory On Axis and Off Axis; Composite Product Design, Composite Fabrication Technique ; Testing Method; Future Applications. Requirement: - References: A. Brent St rong, 1. Fundament al s Of Com- posi t es Manuf act ur i ng: Mat er i al s, Met hods and Appl i cat i ons - Technology Engineer - ing – 2007 By Daniel Gay, Suong V . Hoa, Stephen W. 2. TsaiTranslated by Stephen W Tsai Contribu - tor Suong V. Hoa, Stephen W. Tsai, Com- posi t e mat er i al s: Desi gn and appl i cat i on : CRC Press 2003 Soemardi, T. P. 3. Di kt at Mekani ka komposi t , Fabr i kasi dan Test i ng . FTUI.2003. Composites ASM handbook No 21 4. ENME800317 FINITE ELEMENT AND MULTIPHYSICS 4 SKS Course Obj ective: Provide a basic underst anding and skil l s re- garding the principles of modeling, solution techniques such as ‘inite element method’ and its application in cases of design and engi - neering analysis. The models st udied included physical aspects of the problem in Thermal, elasticity plates and shells, acoustic, and elect romagnet ic. Syllabus: The int roduct ion of FEA Finit e Element Analy- sis; Fundamental FEA I basic concepts and f ormul at i ons FEA FEA FEA Fundament al s II failure modes, Dynamic Analysis, FEA Capa - bilit ies and limit at ions; Basic Finit e Element Modeling: Modeling CAD for FEA; Building a Finite Element Model: Model simulation and interpretation of results; Thermal-Structural; Pressure-St ruct ural; Elect romagnet ic-Thermal- M A S T E R P R O G R A M 423 St r uct ur al ; Anal ysi s of Ther mal Act uat or ; Coating process: Key elements of Successful Implementation of Technology multiphysics; Introduction to CFD and Its Application. Re quir e me nt : Matematika Teknik, Fisika Mekanika dan Panas, Fisika Listrik, Magnit, Gelombang dan Optik References: William B J Zimmerman, Multiphysics 1. Modeling with Finite Element Methods, World Scientific Publishing, 2006 Barry H.V Topping, A Bittnar, Engineering 2. computational technology, Civil-Comp press Edinburgh, UK, 2002 Indra Siswantara, Catatan Kuliah Teknologi 3. Multiphysiscs, 2008 ENME800411 CAD CAM 4 SKS Course Obj ective: This lect ure will discussed about t echnology of CAD, CAM, Integration of CAD CAM application in the industry and the emphasis on: the principles modeling and surface curve geometry Geomet - ric modeling, design of 2D and 3D models with computer assisted. The principle of data exchange between CADCAM systems also tool path design using computer for prismatic and sculptured model. Lectures CAD CAM are provided with t he aim t hat st udent s have t he underst anding and applying technology of CAD CAM: starting the process from design to production process with the computers assistance. Syllabus: Overview of CAD CAM System; Hardware Software System of CAD CAM; Interactive Tools and Computer Graphics Concepts, Geometric Modeling: Type Representation of mathemati - cal model Curve, Surface Solid ; Data Exchange in CAD CAM system; Manufacturing Processes: Manufacturing Process Review Type and Parameter Calculation machining, Lab. practice of CAD; CNC Technology; Tool Path Generation Method in the CAM system; Control ‘quality of machinery’ in the CAM system; Computer Aided Process Planning- CAPP; Postprocessing; Lab. practice of CAM Requirement: - References: Kiswanto G., Handout CADCAM, Diktat 1. kuliah, 2004. Choi B. K., Jerard R. B., Sculptured 2. Surface Machining, Zeid, I., CADCAM Theory and Practice, 3. McGraw-Hill, 1991. C h a n g , T. - C . , C o m p u t e r A i d e d 4. Manufacturing, Prentice-Hall, 1998. Korem, Y., Computer Control of 5. Manufacturing Systems, McGraw-Hill ENME800412 MANUFACTURING PERFORMANCE ASSESMENT 4 SKS Course Obj ective: Syllabus: Requirement: - References: ENME800413 MACHINE VISION SYSTEM 4 SKS Course Obj ective: Machine Vision Industry Subjects provides the understanding and competency of the prin - ciples, methods and applications monitoring the production process by using visual-based camera technology, image processing, for the purpose of introducing the feature: product identiication, selection and product screening, and quality control. With the completion of this course, students have the ability to apply and develop the visual method of monitoring the production process in the industry for the purpose. Syllabus: Basic Machine Vision Method: Binary Image, Binary Morphology and Gray-Scale, Texture analysis; Identiication Method feature; image Processing Method Smart Intelligent, Image Processing System Prolog; Control Equipment Instruments Interface Instruments, Signal, Protocol, PLC ; Method Introduction Color image; Machine Vision Applications. Requirement: - References: J.R. Parker, Algorithms for Image Processing 1. and Computer Vision, Wiley, 2003 Butchelor B. G., Whelan P. F.,Intelligent 2. Vision System for Industry, Springer, 2002 E.R. Davies, Machine Vision : Theory, 3. Algorithm, Practicalities, Morgan Kauffman, 2004 Micheul S, Lawrence O’Gorman, Michael J 4. S Pract ical Algorit hms f or Image Analysis : Description, Examples and Code, , Cambride Univ. Press, 2000 Rafael Gonzales, et.al, Digital Image 5. Processing using Matlab, Prentice Hall, 2003 ENME800414 QUALITY AND PRODUCTION MANAGEMENT SYSTEM 4 SKS Course Obj ective: Provide knowl edge, underst anding and abil - ity to perform management, analysis and improvement of production systems in the manufacturing industry with the principles of eficiency and effectiveness, and able to un - M A S T E R P R O G R A M 424 derstand and implement and develop policies and procedures are needed to improve and control the various processes to improve the performance of the industry. Syllabus : Introduction to Manufacturing Systems, Manu - facturing Principles, Resources, Production Process and Production Organization, Produc - tion Lay-Out, Design, Scheduling and Produc - tion Process Control; Productive Maintenance, Logist ics and Invent ory; Engineering Qualit y, Quality Control, Quality Function Deployment QFD , Total Quality Management; Quality Management System 8 Quality Management Principles, International Standard Quality Management System: ISO 9001, ISO 9004, ISO TS 16949, the International Management System Standard: ISO 14001, OHSAS 18001; System And Process Improvement: Cause - Ef - fect Analysis, FMEA Failure Mode and Effect Analysis, Lean Six Sigma. Requirement: - References: Hitomi, Katsundo. Manufacturing System 1. Engineering. Taylor Francis. 2001 TQM : A Cross Functional Prespective, Rao, 2. CARR, Dambolena, Kopp, Martin, Rafii, Schlesinger, John Willey, 1996 TQM, Text, Cases and Readings, Joel E. 3. Ross, St. Lucie Press 100 E. Linton Blvd Suite 403 B Delray Beach, FL 33483 ENME800511 RAILWAY VEHICLE ENGINEERING 4 SKS Course Obj ective: Provide t he st udent s wit h t he knowledge and ability in analyzing and designing railway vehicle. Syllabus : Engi neer i ng and economi c anal ysi s of r ai l vehicle; st ruct ures and f rame of rail vehicle; structural analysis of lat car; coupler analysis; electrical and pressurized air; analysis and model i ng of bogi e; axl e; wheel ; brake and pivot; suspension system and riding quality; dynamic l oad anal ysis; f at igue and f ract ure in rail vehicle; rail vehicle model and t rack geometry; modeling of rolling stock compo - nents; rail vehicle response on tangent track; rail vehicle lat eral st abilit y on t angent t rack; rail vehicle response on curved track; wheel wear; dynamics of rail vehicle t rain. Requirement : - References: Simon Iwnicki, handbook of railway vehicle 1. dynamics, CRC Press, Taylor Francis Group, 2006. ENME800512 HANDLING AND CONSTRUCTION EQUIPMENT 4 SKS Course Obj ective: Provide expertise and competence to students in the ield of design and development of lifting equipment and construction equipment Syllabus: Introduction and Scope of Construction Equip - ment; Tractor, Bulldozer, Dump Truck and shovel; Construction Equipment Mechanical Concept; Heavy equipment system: Pneumatic and Hydraulic; Basic Machine-lifting machinery and materials transporter; Cranes, hoist and conveyor; forklift: Moving Walks, Escalators, and Elevat ors Requirement: - References: ASME. Handbook of Materials Handling. 1. Mc.Guiness. Mechanical and Electrical 2. Equiment f or Building. ENME800501 VEHICLE ENGINEERING HEAVY DUTY EQUIPMENT Course Obj ective This course provides the latest technology from the four-wheeled passenger vehicle, especially with covering all aspects of engineering in a ve - hicle. Lect ures given vehicle engineering wit h the aim that students have basic competence t o do t he engineering on t he f our-wheel ed passenger vehicle in particular. Syllabus : Vehicle Kinematics Dynamics; mover and t ransmission syst em; Breaking Syst ems, Wheel and Suspension; Security System: Active and passive at the time experiencing issues. Requirement : - References: Bosch Automotive Handbook, Sixth 1. Editions, 2006 Gillespie, Thomas D., Fundamentals of 2. Vehicle Dynamics, 2004 Heisler, Heinz. Advanced Vehicle 3. Technology, 2004 Hermann, Hans. SAE Handbook of 4. Automotive Engineering, 2004 Miliken, William F., Douglas L. Milliken, 5. Maurice Olley, Chassis Design : Principles and Analysis, 2004 Pacejka, Hans B. Tire Vehicle Dynamics, 6. SAE, 2006 M A S T E R P R O G R A M 425 ENME800502 VEHICLE FRAME AND BODY ENGINEERING Course Obj ective Provide the understanding of several concepts relat ed t o design and analysis of vehicle f rame such as: A br i ef under st andi ng i n t he hi st or y of − vehicle design development Understanding the different possible − scenarios f or vehicle design and int eract ivit y of the process in the design and manufacture of vehicles, as well as various types of vehicle st ruct ure and it s use. Understand how the load can be analyzed − simply and with the use of computers as well as a simple structural analysis that highlights the processes involved in vehicle st ruct ures. Understanding the basic concepts related − t o t he aerodynamic vehicle body and t he basic calculat ions required in t he f orm of an aerodynamic vehicle design Syllabus : Int roduct ion t o Innovat ion and breakt hrough discoveries in the ield of automotive and industrial development of the automotive world today. Understanding the concept of loading on t he vehicle st ruct ure, various types of chassis, structural analysis with a simple method of surface structure Simple St ruct ural Surf ace met hod and met hod of computing the skeletal structure. aerody - namic f orce, reducing t he lif t f orce drag force reduction, stability and concept of calculat ion of t he vehicle body dynamics computation. Requirement : - References: Heinz Heisler, “Advance Vehicle 1. Technol ogy” , Soci et y of Aut om ot i ve Engineers, Inc. ISBN 0 7680 10713. Brian Cantor, Patrick Grant and Colin 2. Joh n st on , “ Au t om ot i v e En gi n e e r i n g Lightweight, Functional, and Novel Materials”, Taylor Francis Group, 6000 Broken Sound Parkway NW, Suite 300, ISBN 978-0-7503-1001-7. Giancarlo Genta, Lorenzo Morello, “The 3. Automotive Chassis Vol. 1: Components Design”, Springer Science+Business Media B.V., ISBN: 978-1-4020-8674-8 e-ISBN: 978- 1-4020-8676-2. Giancarlo Genta, Lorenzo Morello, “The 4. Automotive Chassis Vol. 1: System Design”, Springer Science+Business Media B.V., ISBN: 978-1-4020-8673-1 e-ISBN: 978-1- 4020-8675-5. David A. Crolla, “Automotive Engineering 5. Powertrain, Chassis System and Vehicle Body”, Butterworth-Heinemann is an imprint of Elsevier, Linacre House, Jordan Hill, Oxford OX2 8DP, UK ISBN: 978-1- 85617-577-7. Nick Tucker and Kevin Lindsey, “An 6. Introduction to Automotive Composite”, Rapra Technology Limited, ISBN: 1-85957- 279-0. Jason C. Brown, A. John Robertson, 7. and Stan T. Serpento, “Motor Vehicle Structures: Concepts and Fundamentals”, Butterworth-Heinemann Linacre House, Jordan Hill, Oxford OX2 8DP, ISBN 0750651342 Liang Yun · Alan Bliault · Johnny Doo, WIG 8. Craft and Ekranoplan, “Ground Effect Craft Technology”, ISBN 978-1-4419- 0041-8 e-ISBN 978-1-4419-0042-5, DOI 10.1007978-1-4419-0042-5, Springer New York Dordrecht Heidelberg London. M a t t h e w H u a n g , “ Ve h i c l e C r a s h 9. Mechanics”, CRC Press LLC, International Standard Book Number 0-8493-0104-1. Ahmed A. Shabana, Khaled E. Zaazaa 10. and Hiroyuki Sugiyama, “Railroad Vehicle Dynamics a Computational Approach”, CRC Press is an imprint of the Taylor Francis Group, ISBN 978-1-4200-4581-9. ENME800601 MARITIME RESOURCES AND TECHNOLOGIES Course Obj ective: Provide the understanding about the potential of mar i t i me r esour ces: f i sher i es and non- isheries in Indonesia. Syllabus : Fisheries potential in Indonesia, ishing zone classiication, ishing, aquaculture, ish pro - cessi ng i ndust r y, mar i ne-based i ndust r i es, utilization of coral reefs, utilization of algae. Requirement : - References : Talahatu, Marine Resources Dictate 1. Lecture. 2008 Departemen kelautan dan Perikanan. 2. Potensi Perikanan di Indonesia. 2008 ENME800513 MODERN VEHICLE TECHNOLOGY Course Obj ective: Students understand the concept of manufac - t uring t echnology and cont rol syst ems on t he vehicle so as t o: Analyze the condition of current • t echnol ogi cal ad vances t o m ak e f und am ent al changes i n vehi cl e design a sust ainable f ut ure. Design process to create an automatic • control system that helps in controlling M A S T E R P R O G R A M 426 t he vehicle. Desi gni ng vehi cl es wi t h el ect r oni c • control systems that can improve vehicle performance. Describes t he int egrat ion of vehicle • cont r ol syst em s and m echani cal - electrical interaction possibilities for t he design of f ut ure vehicles. Syllabus : Knock cont r ol , Li near sol enoi d i dl e speed con- t r ol , Sequent i al f uel i nj ect i on, Di st r i but or l ess i gni t i on, Sel f -di agnosi s f or f ai l -saf e oper at i on, Cr ankshaf t angul ar posi t i on measur ement f or ignition timing, Direct mass air low sensor, Var i abl e val ve phasi ng, t eknol ogi kendaraan Hybr i d El ect r i c Vehi cl es and El ect r i c Vehi cl e . Requirement References: Julian Happian-Smith, “ An Introduction 1. to Modern Vehicle Design”, Butterworth- Heinemann Linacre House, Jordan Hill, Oxford OX2 8DP, ISBN 07506 5044 3. Heinz Heisler, “Advance Vehicle 2. Technol ogy” , Soci et y of Aut om ot i ve Engineers, Inc. ISBN 07680 1071 3. Fuhs, Allen E., “Hybrid vehicles and the 3. future of personal transportation”, CRC Press, Taylor Francis Group, ISBN-13: 978-1-4200-7534-2, ISBN-10: 1-4200- 7534-9. Lino Guzzella and Christopher H. Onder, 4. “Introduction to Modeling and Control of Internal Combustion Engine Systems”, Springer-Verlag Berlin Heidelberg, ISBN 978-3-642-10774-0 e-ISBN 978-3-642- 10775-7, DOI 10.1007978-3-642-10775-7, Library of Congress Control Number: 2009940323. Iqbal Husain, “ELECTRIC and HYBRID 5. VEHICLES Design Fundamentals”, CRC PRESS Boca Raton London New York Washington, D.C., ISBN 0-203-00939-8 Master e-book ISBN, International Standard Book Number 0-8493-1466-6 Print Edition, Library of Congress Card Number 2002041120. Ali Emadi, “Handbook of Automotive 6. Power Electronics and Motor Drives”, Taylor Francis Group, CRC Press is an imprint of Taylor Francis Group, ISBN 0-8247-2361-9. Nicolas Navet and Françoise Simonot- 7. Li on, “ Aut omot i ve Embedded Syst ems Handbook”, CRC Press Taylor Francis Group, 6000 Broken Sound Parkway NW, Suite 300, ISBN-13: 978-0-8493-8026-6, ISBN-10: 0-8493-8026-X Paul Nieuwenhuis and Peter Wells, “The 8. aut omot ive indust ry and t he environment A t echnical, business and social f ut ure” , Woodhead Publishing ISBN 1 85573 713 2, CRC Press ISBN 0-8493-2072-0, CRC Press order number: WP2072. Simon Tung, Bernard Kinker, and Mathias 9. Woydt , ” Aut omot ive Lubricant Test ing and Advanced Additive Development”, ASTM 100 Barr Harbor Drive PO Box C700, West Conshohocken, PA 19428-2959, ISBN: 978- 0-8031-4505-4. James Lar mi ni e, John Lowr y, “ El ect r i c 10. Vehicle Technology Explained”, Oxf or d Br ookes Uni ver si t y, Oxf or d, UK, Acent i Desi gns Lt d. , UK. ISBN 0-470-85163-5. ENME800514 OIL AND GAS DRILLING EQUIPMENT Course Obj ective: Provide additional insights regarding the imple - ment at ion of basic knowledge of engineering competence that is at the core of oil and gas drilling techniques. Competencies expected of graduates capable of developing the engine wit h value added t echnical knowledge of oil and gas drilling equipment that is ready to be trained and shaped to be easily and immedi - ately adapt to work without the awkwardness of the world’s E P oil and gas ields in general and in particular oil and gas drilling. Thus it has t he advant ages of graduat es and a wider choice in the real world of work later. Objectives and learning out comes t o be achieved: Enabled st udent s t o know t he basic 1 t ool s and t hei r f unct i ons and how each i s needed i n an oi l and gas drilling operations. Students capable of explaining the 2 t echni que of oi l and gas dr i l l i ng operations and its other related aspects such as equipment used, safety issues, safety equipment, emergency and environment al issues. Students have a pretty good 3 underst anding of t he knowl edge of drilling equipment and its operation so as to participate in an oil and gas drilling operations with confidence and readiness t o increase knowledge and skills lat er on af t er graduat ion. Syllabus : Intro to oil gas well, oil gas Exploration, exploitation and production, drilling rig, the terminology, the problem of drilling, drilling luid, drilling oil and gas in the system, hoist - ing system equipments, equipments rotating system, circulating system equipments, power system equipments, blowout prevention system equipments, well design, equipments and op - erations for safety and eficiency, process and equipments for cementing, drilling prepara - M A S T E R P R O G R A M 427 tion, drilling operations, drilling and process problems drill string vibration and whirling, collar failure, etc. artiicial lift methods and equipments, visit to the ield of oil and gas drilling. Requirement References: Don A. Gorman, Jerry W. Meyer, “Drilling 1. Equipment and Operations”, Action Systems Inc., Dallas, Texas – USA. Adam T. Bourgoyne, Martin E. Chenevert, 2. et. al., “Applied Drilling Engineering”, Society of Petroleum Engineers, Richarson, Texas – USA. Nguyen J.P., “Drilling-Oil and Gas Field 3. Development Techniques”, Institut Français du Pétrole Publication, 1996 Ker mi t E. Br ow n, “ The Technol ogy of 4. Artificial Lift Methods”, Volume 2a, Petroleum publishing Co., 1980 Amanat U.C., “Oil Well Testing handbook”, 5. Elsevier, 2004 Amanat U.C., “Gas Well Testing handbook”, 6. Elsevier, 2004 ENME800602 ADVANCED THERMOFLUIDS Course Obj ective: Students are expected to understand the concepts of mass, momentum, heat, work, energy and entropy at termoluida mechanics. Memahmi basic principles of hydrostatics, low measurement, identifying termoluid system or control volume and the low of time, momen - t um, heat and work associat ed wit h a given problem. Understand the concept of lift and drag force. Applying the irst and second law of thermodynamics withing thermoluids sytem. Syllabus : Introduction to thermoluids, hydrostatic, control volume approach, Bernoulli equation, streamlined curves, the basic concepts of thermodynamics, the relationship properties and ideal gases, application of the irst and second law of thermodynamics, tempera - ture, entropy, entropy of use, fuel , control volume analysis, steady low, gas turbines and jet engines. Requirement : - References: Cengel, Y.A. Boles, M.A. 1. Thermodynamics: An Engineering Approach Homsy, G.M.Ed. Mechanics Of Fluids 2. Moran, M.J. Shapiro, H.N. 3. Fundamentals Of Engineering Thermodynamics Nakayama, Y.; Boucher, R.F. 4. Introduction To Fluid Mechanics Rogers, G.F.C. Mayhew, Y.R. 5. Engineering Thermodynamics Samimy, M., Et Al. A Gallery Of Fluid 6. Motion Sonntag, R.E., Borgnakke, C., 7. Van Wylen, G.J. Fundamentals Of Thermodynamics Van Dyke, M. An Album Of Fluid Motion 8. ENME800303 DESIGNING AND MANUFACTURING TECH- NOLOGY INTEGRATION Course Obj ective: Provide an understanding of competence and capability in designing and manufacturing pro - cess by utilizing peracangan includes latest design and manufacturing system CAD CAM and reverse engineering and prototype deve - lopment to improve eficiency and accelerate the production process, reduce errors, improve quality and reduce production costs. Syllabus : System Overview of CAD CAM; Hardware Software Systems CAD CAM: Geometric Modelling: Type a mathematical representa - t ion of t he model curve, surf ace and solid 3D modeling methods and manipulation of 3D models; exchange of data within and between sistem-CADCAM; CAD Laboratory Activity; Technology CNC; Tool Path Genera - tion Method-CAM systems; Control ‘quality of machining’ machined surf ace qualit y in the system-CAM: Computer-Aided Process Planning CAPP; postprocessing; Practice CAM: 3D geometry measurements, principles and measurement based Coordinate Measur - ing Machine CMM, the method of iltration data, the identiication of boundary features, modeling and manipulation of point-based 3D models, 3D models for the modularization of the prototype, prototype and rapidprototyp - ing method, discretization model, principles and application of SLS and SLM. Requirement : - References: Kunwoo Lee, 1. Pr i nci pl es of CAD CAM CAE , Prentice Hall, 2003 Gandjar K, 2. Hand out CAD CAM , DTMUI, 2007 Connie L. Dotson, 3. Fundament al s of Di mensi onal Met r ol ogy , Delmar Learn- ing, 2006 Ali K. Kamrani, Emad A Nasr, 4. Rapi d Pr ot ot ypi ng : Theor y And Pr act i ce, Birkhauser, 2006 Patri K. Venivinod, Weyin Ma, 5. Rapi d Pr ot ot ypi ng: Laser based and Ot her Technol ogi es , 2003 M A S T E R P R O G R A M 428 ENME800402 AUTOMATION AND ROBOTICS 4 SKS Course Obj ective: Automation and Robotics course discusses technology and application in the automa - t ion indust ry and t he design and cont rol t he robot emphasizes: understanding the types of automation systems, particularly in the manuf act uring indust ry and t he mechanism, the design and development of automation system that emphasizes the 3 things: reliability, qualit y and cost and t he underst anding robot control system. Automation and Robotics Lec - t ures given wit h t he aim t hat st udent s have an understanding in the implementation of tech - nology Automation and Robotics, especially in t he manuf act uring indust ry. Syllabus : Automation System; Classiication Type Manu - f act ur i ng Aut omat i on machi ner y; Act uat or ; Sensor System; PLC Control System in the Manufacturing Automation machinery; Robot - ics: Deinitions and Principles of Robot; Spa - tial Descriptions: Deinitions and Principles, Methods and Applications Spatial descriptions; Forward Kinematics: Deinition, Principles and The Forward Kinematics; Jacobians: Speed, explicit shape, definition and principle of inverse Kinemat ics; Dynamic: The f orm of ex- plicit, Acceleration and inertia; Control system ronbotic: PID control, the Joint Space Control, Operational Control and Space Force Control; Robot Design Assignment. Requirement :- References: Craig J., 1. Int r oduct i on t o Robot i cs, Addison Wesley Publishing Inc., 1989. Heath L., 2. Fundam ent al s of Robot i cs, Theory and Applications, Prentice Hall, 1979. Koren Y., 3. Robot i cs f or Engi neer , McGraw Hill, Intl Edition, 1985. Lentz K. W. Jr., 4. Desi gn of Aut omat i c Ma- chi ner y , Van Nostrand Reinhold, 1985. Schilling R. J., Mikell P., 5. Fundament al s of Robot i cs, Anal ysi s and Cont r ol , Prent ice Hall, 2000. Kiswanto G., 6. Ot omasi dan Robot i ka , Dikt at Kuliah Departemen Teknik Mesin, 2004. ENME800503 VEHICLE CONTROL SYSTEM Course Obj ective: St udent s under st and t he basi c f eat ur es of t he vehicle cont rol syst em t hat has t he abil- it y t o; Describes a simple method for the • analysis of vehicle suspension systems and components; Describes the vehicle suspension • syst em design requirement s and how t o achieve it ; Analyze the various factors and issues • that affect the design of suspension of driving Under st and t he mechani cs of t he • vehicle wheel Describes recent developments in • cont r ol of t he br aki ng syst em and braking syst em design and mat erial needs an ef f icient , Analyze the influence of the steering • syst em charact erist ics t o t he vehicle mot ion Syllabus : Introduction of the role of vehicle suspension systems, factors that affect the design, dei - nitions and terminology in vehicle suspension systems, suspension mobility mechanisms, different types of suspension, kinematics analysis, t he analysis cent er of rot at ion roll cent er analysis, geomet ric st yle as well as lateral, suspension components. The basis of the braking system. Regulation, function and t erms of use brake syst em, brake syst em components and conigurations as well as the kinematics of the braking system. Consider - ation of adhesion force proportional to the brake system and braking eficiency. Defor - mation, lateral force and slip angle on the t ire when t he vehicle is running. Penikungan charact erist ics cornering charact erist ics ac- cording to Fiala theoretical approach to the mat hemat ical model and t he ef f ect is due t o air pressure in tires. Requirement :- References: Heinz Heisler, “Advance Vehicle 1. Technology” , Societ y of Aut omot ive Engineers Inc. ISBN 0 7680 1071 3 Giancarlo Genta, Lorenzo Morello, “The 2. Automotive Chassis Vol. 1: Components Design”, Springer Science+Business Media B.V., ISBN: 978-1-4020-8674-8 e-ISBN: 978- 1-4020-8676-2. Giancarlo Genta, Lorenzo Morello, “The 3. Automotive Chassis Vol. 1: System Design”, Springer Science+Business Media B.V., ISBN: 978-1-4020-8673-1 e-ISBN: 978-1- 4020-8675-5. David A. Crolla, “Automotive Engineering 4. Powertrain, Chassis System and Vehicle Body”, Butterworth-Heinemann is an imprint of Elsevier, Linacre House, Jordan Hill, Oxford OX2 8DP, UK ISBN: 978-1- 85617-577-7. M A S T E R P R O G R A M 429 Masato Abe, “Vehicle Handling Dynamics, 5. Theory and Applications”, Butterworth- Heinemann is an imprint of Elsevier Linacre House, Jordan Hill, Oxford OX2 8DP, UK, ISBN–13: 978-1-8561-7749-8. Fred Puhn, “ Brake Handbook”, Published 6. by HPBooks A Division of HPBooks, Inc., ISBN 0-89586-232-8 Library of Congress Catalog Number 84-62610. John C. Dixon, “The Shock Absorber 7. Handbook Second Edition”, John Wiley Sons Ltd, The Atrium, Southern Gate, Chichester, ISBN 978-0-470-51020-9. Reza N. Jazar, “Vehicle Dynamics: 8. Theory and Applications,” Springer Science+Business Media, LLC, ISBN: 978-0- 387-74243-4 e-ISBN: 978-0-387-74244-1. Liang Yun · Alan Bliault · Johnny Doo, WIG 9. Craft and Ekranoplan, “Ground Effect Craft Technology”, ISBN 978-1-4419- 0041-8 e-ISBN 978-1-4419-0042-5, DOI 10.1007978-1-4419-0042-5, Springer New York Dordrecht Heidelberg London. T.K. GARRETT , K. NEWTON, W. STEEDS, 10. “The Motor Vehicle”, Butterworth- Heinemann Linacre House, Jordan Hill, Oxford OX2 8DP, ISBN 07506 4449 4. ENME800603 MARITIME TECHNOLOGY Course Obj ective: Under st andi ng about mar i t i me t echnol ogy and t he use of sea transport of marine-based energy sources. This course is also int ended t o make st udent s underst and t he marit ime op - portunities that can be developed by utilizing t he t echnology. Syllabus : Ships clasification based on their function, aspects to be considered in designing the ship, the historical development of offshore construction, marine environment, types of buil ding of f shore: f ixed and f l oat ing design design, mooring and anchor syst ems, Perhit unga st yl e and st r engt h cal cul at i ons of of f shor e construction , FPSO, Marine energy resources: wave, wake, OTEC, salinity, hydrogen Requirement :- References: International Energy Authority Renewable 1. Energy Technology Deployment IEA-RETD, Offshore Renewable Energy: Accelerating the Deployment of Offshore Wind, Tidal, and Wave Technologies ., IEA-RETD 2012. Chakrabarti, Handbook of Offshore 2. Engineering, Elsevier. 2007 ENME800611 SHIP PRODUCTION MANAGEMENT 4 SKS COURSE OBJECTIVE : Provide knowledge and underst anding of t he various shipyard management and technique. Syllabus : Shipyard Layout ; Ship Process Production ; St eel St ock Yard Planning ; Crane Calculation : Jamorang Calculation At Each St age Produc- t ion: Make Work Schedule: Work Break Down St ruct ure; Int egrat ed Hull Outitting and Paint - i ng; Advanced Outiting ; Group Technol ogy Methods f or Ship Product ion; Ship launching; Ship t rials. Prasayarat : References : D.J. Eyres, Ship Construction, Butterworth- 1. Heinemann, 2007 R.Shenoi, Ship Production Technology, Univ. 2. Of Southampton. National Research Council, Shipbuilding 3. Technology and Education, National Academy Press, 1996 ENME800614 ENERGY SYSTEM OPTIMIZATION 4 SKS Course Obj ective: This course provides an understanding of math - ematical modeling, simulation and optimiza - t ion of energy syst ems t hrough t echnical and economical approach. The course is intended to equip student with the ability to understand mathematical model, simulation and optimiza - t ion of t hermal syst ems. Syllabus: Workabl e Syst em Design; Economical Eval u- ation; Determination of Mathematical Equa - tions; Thermal Equipment Modeling; System Simulation; System Optimization: Objective Function, Constraints; Lagrange Multipliers: Lagrange multiplier to complete the optimiza - tion process; Dynamics, Geometric and Linear Programming; Mathematical Model of Thermo - dynamics Properties; Big System Simulation under Steady Condition; Big Thermal System Simulation; Calculation of Variables in Opti - mum Conditions. Requirement: Engineering Mathematics, Basic Thermodynamics, Fluid Mechanics References: St oecker, W. F. “ Design of Thermal Sys- 1. tem”, Mc.Graw Hill Book Co, 1989. Boehm,R.F.”Design of Analysis of Thermal 2. System”John WileySons,1987. Yogesh Jaluria, “Design and Optimization 3. of Thermal Systems “ Mc.Graw Hill Book Co, 1998. ENME800615 MARINE AND OFFSHORE STRUCTURE 4 SKS Course Obj ective : Provide t he knowledge, underst anding of t he t heory and principles of building of f shore include the type , f unct ion, and of f shore const ruct ion t echnology and t echniques in performing design st ruct ure. Syllabus : Types of Offshore ; Construction and Offshore St r uct ur es; Calculation of St yl e and Power Offshore : Safety Requirements ; Construction Semi-submersible; Single Buoy Mooring ; FPSO ; Offshore Maintenance and Repair . M A S T E R P R O G R A M 430 Requirement : References : Cliff Gerwick, Construction of Marine and 1. Off-shore Structures, CRC Press 1999 Subrata Chakrabarti, Handbook of Offshore 2. Engineering, Elsevier Science, 2005 Yong Bai, Marine Structural Design, 3. Elsevier Science, 2003 ENME800617 MARITIME LAW AND REGULATION 4 SKS Course Obj ective : Provide knowledge and underst anding of t he l aws and regul at ions on marit ime act ivit ies bot h nat ionally and int ernat ionally. Syllabus : Int roduct ion of marit ime law; Regulation of Ma - rine Pollut ion Prevention and Control ; SOLAS ; Prevent ion of Collisions Regulations ; ISM Code; St at ut ory Rules ; Passenger Ship Regulations ; Tanker Regulations ; Offshore Regulations : Ac- cident Rescue Regulations; Other IMO rules . Accident prevention regulat ions ; R isk assess- ment and analysis. Requirement : - References : International Convention for the Prevention 1. of Pollution From Ships MARPOL, International Maritime Organisation Publicat ions International Regulations for Preventing 2. Collisions at Sea COLREG, International Maritime Organisation Publications International Convention for the 3. Saf et y of Li f e at Sea SOLAS, International Maritime Organisation Publications International Safety Management Code ISM 4. Code Guide Book, International Maritime Organisation Publications Churchil R.R. dan Lowe A.V, The Law of the 5. Sea, MUP 1999 ENME800612 SPECIAL SHIP PROJECT 4 SKS Course Obj ective : Provide t he knowledge, underst anding of ship design for special purposes Syllabus : Typology and special ship purposes ; Material t o special Ship, Design Considerations ; Calcula - t ion of loading; Calculation of Ship Quantities; Computation St ruct ures: Propulsion Syst ems; Motion Syst em; Saf et y and Navigation System ; Stability Calculation . Requirement : - References : Lars Larsson dan Rolf Eliasson, Principles of 1. Yacht Design, International MarineRagged Mountain Press, 2007 Dave Gerr, The Elements of Boats Strength, 2. International MarineRagged Mountain Press, 1999 Norman L. Skene, dan Marnard Bray, 3. Elements of Yacht Design, Sheridan house, 2001 Steve Killing dan Doug Hunter, Yacht Design 4. Explained : A Sailors Guide to the Principles and Practices of Design, W.W Norton and Company, 1998 S. Sleight, Modern Boat Building, Conway 5. Maritime Press. ENME800613 WELDING ENGINEERING 4 SKS Course Obj ective : Provide t he knowledge, underst anding of t he t heories , principles, design and assessment of t he welding qualit y and applications . Syllabus : Int roduct ion: welding inspector qualiications ; Dest ruct ive t est ; Non- dest ruct ive t est ; welding inspector responsibilities ; welding procedures and welder qualiications ; welding design ap - plications ; residual st ress and def ormat ion; welding symbols Requirement : References : Technical Manual TM 5-805-7. Welding Design, Procedures and Inspection Headquarters, De - partment of the Army.1985 Lioyds Register. Welding Procedures, Inspec - tions and Qualiications. ENME800616 SEA TRANSPORT AND PORT MANAGEMENT 4 SKS Course Obj ective : Provide knowledge and underst anding of vari- ous management approaches, marit ime t rans- port and port act ivit ies which also include risk f act ors, saf et y, and economy. Syllabus : Sea Transport Demand Trend: Marine Transpor - t at ion Market Research ; Int er Mode Transport Syst em; Syst em loading and unloading, Types of Sea Transport , War ehousi ng and St or age Cargo Syst ems, Syst ems Agency, Survey Charge , Corporate Sailing economic calculat ion, Cus - t oms. Requirement : - References : P. Lorange, Shipping Management, 1. Institution for shipping Research. Patrick Alderton, Reeds Sea Transport : 2. Operation and Management, Adlard Coles, 2008 Patrick Alderton, Port Management and 3. Operations,Informa Business Publishing, 2005 Svein Kristiansen, Maritime Transportation 4. : Safety management and Risk analysis, Butterworth-Heinemann, 2004 M. Stopford, Maritime Economics, 5. Routledge, 1997 House, D.J, Cargo Work for Maritime 6. Operation, Butterworth Heinemann, 2005 M A S T E R P R O G R A M 431 Program Speciication 1 Awarding Institution Universit as Indonesia

2 Teaching Institution

Universit as Indonesia

3 Programme Title

Master Program in Electrical Engineering

4 Class

Regular

5 Final Award

Magister Teknik M.T.

6 Accreditation Recognition

BAN-PT: A – accredited

7 Languages of Instruction

Bahasa Indonesia

8 Study Scheme Full Time Part Time

Full Time 9 Entry Requirements S1 in Electrical Engineering, Math and Physics; and pass the entrance exam.

10 Study Duration

Designed for 2 years Type of Semester Number of semester Number of weeks semester Regular 4 17 Short optional - - 11 Graduate Proiles: Master of Engineering who is able to design and independently conduct research in the ield of electrical engineering based on technological advancement in accordance with professional ethics

12 Expected Learning Outcomes:

General outcomes: Able to independently conduct research based on innovative methods in electrical engineering • ields in accordance with scientiic and preofessional ethics. Able to disseminate research results to society both written and oral in scientiic forum. • Able to design develop system in electrical engineering ield through inter and multidisciplinary • approach Able to manage teamwork or research team to solve electrical engineering problems • Able to contribute in human resources improvement aiming at electrical engineering research • development Able t o broaden and maint ain collaborat ion net work wit h colleagues and elect rical engineering • research communit ies bot h nat ionally and int ernat ionally Speciic outcomes in photonic and electronic major: Able to characterize and integrate circuits and electronic devices and photonics • Able to design a variety of electronic circuits and devices, photonics and micro-electro • Able to analyze in depth various circuit design, electronic devices, photonics and micro-electro • mechanical syst ems Able to contribute to current developments in the ield of electronics and photonics • Speciic outcomes to telecommunication major: Able to analyze in depth and improve the performance of telecommunication access system and • net works Able t o model and design t he communicat ion syst em • Able t o model and design t he radar syst em • Speciic outcomes in control major: Able t o accurat ely model t he cont rol syst em according t o t he act ual syst em • Able to analyze the stability of comprehensive control system • Able to develop and implement alternative control algorithms in real-time as a solution • Able to contribute to the development of new control techniques and it’s applications • Speciic outcomes in electrical power and energy major: Able to master the phenomenon of electric power • Identify the needs of Electric Power System Components and Power Electronics • Able to apply conventional and renewable energy conversion • Able to plan, analyze, design and engineering combine energy and electricity • Able to implement technology advancement in energy and electricity engineering •

6. 3. MASTER PROGRAM IN ELECTRICAL ENGINEERING