Integrated Engineering
Study programme title in Est.
Integreeritud tehnoloogiad
Study programme title in Engl.
Integrated Engineering
TalTech study programme code
MVEB14
MER study programme code
126337
Study programme version code
MVEB14/25
Faculty / college
E - School of Engineering
Head of study programme/study programme manager
Tauno Otto
Language of instruction
English
Study level
Bachelor study
ECTS credits
180
Self-paid study programme
no
Nominal study period
6 semesters
Study programme group
Engineering, Manufacturing and Technology
Broad area of study
Engineering, Manufacturing and Construction
Study field
Engineering and engineering trades
Curriculum group
Engineering and engineering trades not elsewhere classified
Granting the right to conduct studies in the study programme group
õppe läbiviimise õigus
Validity date of the right to conduct studies in the study programme group
tähtajatu
No. of the decision granting the right to teach in the study programme group
112
Access conditions
Secondary school leaving certificate or an equivalent recognised qualification.
According to TalTech admission requirements. Show more...
According to TalTech admission requirements. Show more...
Study programme aims and objectives
The program provides students with deep knowledge in digitalisation for productivity and smart manufacturing - Industry 4.
0 - sufficient to start activities in hi-tech industry or ICT firm with the intention of continuing education.
The program integrates knowledge from the fields of ICT, design, production, materials, logistics, robotics, and market-oriented economic subjects. Therefore, a bachelor in integrated engineering is ready to start engineering activities, as well as to continue his/her studies at a master's level.
Hence, the educational objectives of the curriculum areas are as follows:
- to provide an understanding of: social sciences, physics and engineering science fundamentals in the field of engineering to the extent required for starting to work in the field, as well as to continue studies at a master's level;
- to deliver special courses introducing mechanical engineering, materials, design, power engineering, automation, information- and communication technology;
- applying modern computing and information technology in the field;
- relying on foreign language sources and procuring information in the field. Show more...
0 - sufficient to start activities in hi-tech industry or ICT firm with the intention of continuing education.
The program integrates knowledge from the fields of ICT, design, production, materials, logistics, robotics, and market-oriented economic subjects. Therefore, a bachelor in integrated engineering is ready to start engineering activities, as well as to continue his/her studies at a master's level.
Hence, the educational objectives of the curriculum areas are as follows:
- to provide an understanding of: social sciences, physics and engineering science fundamentals in the field of engineering to the extent required for starting to work in the field, as well as to continue studies at a master's level;
- to deliver special courses introducing mechanical engineering, materials, design, power engineering, automation, information- and communication technology;
- applying modern computing and information technology in the field;
- relying on foreign language sources and procuring information in the field. Show more...
Learning outcomes of the study programme
The graduate:
- is able to express itself in speciality in written and oral manner and is able to communicate at least in one foreign language;
- can write and compile programs, including for industrial robots and CNC machine tools;
- can use industrial digitalisation and Industry 4.0 principles and methodologies for enhancing productivity;
- has knowledge how to use contemporary means of information technology and teamworking in everyday work;
- is able to take into part in engineering projects both in industry and R&D;
- can design new competitive environment friendly products, meeting the customers' expectations;
- knows how to use specific models to specify a system or process on the level of technological parameters, while creating and assessing alternative designs;
- has knowledge how to use the results obtained by the physical model for creation of an actual system or a process which would also comply to effective production requirements;
- has ability to critically assess the developed systems used in industry as well as own professional capability, and to plan the needed additional training. Show more...
- is able to express itself in speciality in written and oral manner and is able to communicate at least in one foreign language;
- can write and compile programs, including for industrial robots and CNC machine tools;
- can use industrial digitalisation and Industry 4.0 principles and methodologies for enhancing productivity;
- has knowledge how to use contemporary means of information technology and teamworking in everyday work;
- is able to take into part in engineering projects both in industry and R&D;
- can design new competitive environment friendly products, meeting the customers' expectations;
- knows how to use specific models to specify a system or process on the level of technological parameters, while creating and assessing alternative designs;
- has knowledge how to use the results obtained by the physical model for creation of an actual system or a process which would also comply to effective production requirements;
- has ability to critically assess the developed systems used in industry as well as own professional capability, and to plan the needed additional training. Show more...
Graduation requirements
Completion of the curriculum in the required amount, and the successful defence of the graduation paper in conformity with the requirements set by the TalTech Senate.
In order to obtain Cum Laude diploma the graduation paper must be defended for the grade "5" and the weighted average grade must be at least 4,60, where all grades from diploma supplement are taken into account. Show more...
In order to obtain Cum Laude diploma the graduation paper must be defended for the grade "5" and the weighted average grade must be at least 4,60, where all grades from diploma supplement are taken into account. Show more...
Degrees conferred
Bachelor of Science in Engineering
Study programme version structure :
Module type
total ECTS credits
General studies
60.0
Core studies
84.0
Special studies
24.0
Free choice courses
6.0
Graduation thesis
6.0
Total
180.0
- +MAIN SPECIALITY 1: integrated engineering
- +MODULE: Mathematics 21.0 ECTS credits (General studies)AimsThe aim of this module is:
- to give theoretical basic knowledge in linear algebra, mathematical analysis, computing methods and probability theory and mathematical statistics;
- to give knowledge how to solve practical problems utilizing mathematical methods;
- to give overview about applicability of mathematics in practice and in other fields of sciences;
- to train students to operate mathematical symbology and to develop logic, analytic, and algorithmic thinking and systematic and model-based approach to practical problems;
- to develop perception of space and graphic modelling skills;
- to give theoretical and practical knowledge of making and reading drawings;
- provide basic knowledge of mathematical statistics;
- teach to understand the concepts related to the field of mathematical presentation. Show more...Learning outcomesThe student:
- knows the calculation procedures of mathematical analysis;
- knows functions, vector and matrix algebra;
- is able to solve differential and integral calculus of functions of one and several variables;
- is able to find derivatives and differentiate, solve systems of linear equations and use vector and matrix algebra;
- use the concepts of engineering graphics in various fields of their applications;
- think logically, analytically and systematically to solve space geometrical tasks by means of drawings and images;
- use the knowledge and skills of graphic subjects to solve problems in other subjects as well as to describe and analyse the environment;
- understands the engineering related mathematical concepts and forms of presentation;
- understands the events of a probabilistic nature and the simple statistical applications; knows and is able to use diagrams;
- is able to solve extremum exercises. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 21.0 ECTS credits - +MODULE: Social and economic sciences 15.0 ECTS credits (General studies)AimsThe aim of this module is:
- to develop creative thinking, teach the principles of entrepreneurial behaviour and share knowledge of how to recognize business opportunities,
develop a business idea, to assess a business idea and to go forward with the business idea in different entrepreneurial environments;
- to familiarize the student with the economic phenomena and their relationships;
- to provide a general introduction to the environmental protection and sustainable development principles;
- to provide knowledge of safety management as a part of enterprise management;
- to develop the students’ entrepreneurial knowledge and skills and to support development of their entrepreneurial qualities and mind-set. Show more...Learning outcomesThe student:
- understands the functioning of society and core
concepts of important social processes and is able to discuss and argue for them on the basis of simple society organizational problems;
- is able to tie engineering profession in the context of the functioning of society and the important social processes;
- masters an ability to both define the principles of environmental protection and sustainable development and solve problem in these fields;
- learns about the legislation in occupational safety and health, is able to assess the hazards in the work environment, knows how to prevent the accidents on the basis of mechanical hazards, knows the principles of fire safety;
- describes the basic processes and keywords, developing tendencies, culture and different forms of entrepreneurship;
- analyzes the advantages of different business models and the impact of the business environment on business modeling. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 3.0 ECTS creditsElective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 12.0 ECTS credits - +MODULE: Exact and natural sciences 24.0 ECTS credits (General studies)AimsThe aim of this module is to:
- present a systematic knowledge and practical experience to solve the problems of equilibrium and movement of mechanical systems;
- raise the level of education in electromagnetism and optics since a higher level is needed for technical, technological and science courses;
- create a systematic, physics based view of the world by applying the scientific method;
- give a review of how to organize, analyze and exploit electric circuits and learn about the principles of operate, functions and applications of electric and electronic devices;
- acquire knowledge of the characteristic properties of substances and materials in a gaseous, liquid and solid state;
- form the students' way of thinking and working as an engineer (both systematically and dialectically);
- develop students towards systematic, scientifically based worldview;
- shape perceptions of both live and inanimate nature of the behavior and operation of ways of obtaining information. Show more...Learning outcomesThe student:
- has an overview of the methods and ways to solve the problems of equilibrium and movement of mechanical systems;
- is able to compose an appropriate model to study the motion of real mechanical systems and to solve the arising problems;
- knows and understands the laws and models including the extent of their applicability to electromagnetism and optics, and is able to analyse and solve electromagnetical and optical problems;
- knows the laws of nature which allow to describe the processes taking place in the electric circuits, can compose a model of electric devices an electric circuit and calculate, on the basis of an electric circuit currents, the voltages and powers of an electrical device;
- knows the requirements for selection of materials for equipment, buildings and constructions, is able to solve special problems, design work plans and projects in the field of material selection systematically and considering quality needs;
- understands the animate and inanimate nature, the functioning of the main laws of scientific models and the limits of their applicability;
- knows sustainable development and environmental protection in the main terms of the main environmental problems, their causes, consequences and prevention options and can take them into account in professional activity. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 18.0 ECTS creditsElective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 6.0 ECTS credits - +MODULE: Energy and its applications 24.0 ECTS credits (Core studies)AimsThe aim of this module is to:
- develop understanding on energy utilization for operating different technical systems;
- give basic theoretical and practical knowledge for the selection of energy sources for actuating and other technical systems, for analysis of their behavior and their modeling and for optimizing their structures and optimal control of energy flows;
- develop understanding in different actuating systems resource and energy needs, behavioral characteristics and their control;
- give knowledge in theoretical basis of thermodynamics, heat exchange and heat exchangers, thermal power units, refrigerating units, and different types of boilers;
- develop sustainable and energy preserving thinking at designing technical equipment. Show more...Learning outcomesThe student:
- knows basics on use of different energy sources
for powering actuators and has a good overview about the use of different kind of energy in technical systems and knowledge in solving the problems of powering actuators;
- has general knowledge in selecting, designing and exploiting hydro, pneumo, electrical and thermal actuators;
- knows basics of automation using robotics;
- knows basic terminology of thermal engineering;
- knows thermodynamic parameters of gases and vapors and general thermodynamic processes taking place in a gaseous environment;
- knows how to characterize cycles in thermal power and cooling systems and how to analyse their thermal efficiency;
- knows how to relate system energy usage parameters with system component parameters and is able to analyse them. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 18.0 ECTS creditsElective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 6.0 ECTS credits - +MODULE: Information technology 24.0 ECTS credits (Core studies)AimsThe aim of this module is to:
- develop logical, analytical and algorithmic thinking and methodical and model-based approach to solve engineering problems and tasks;
- give basic knowledge and skills for solving technology related tasks using general purpose applied software packages and skills to verify algorithms and to compile programs in high level programing languages creating a base for further successful use of information technology resources at study and professional work;
- give knowledge in strategy of composing complicated algorithms, dynamic data storage, coding algorithms in different computing languages C, C++, and on different computing platforms;
- give theoretical basic knowledge in compiling and optimizing logic schemas and to give an overview of use of digital logic components;
- give an overview of microprocessor functions and principles of I/O and data storage devices. Show more...Learning outcomesThe student:
- is able to analyse state and behavior of systems and subjects using models and is able to argue logically functionality of algorithms and methods;
- knows methods and instruments used for creating ICT applications and knows general purpose software possibilities and instruments utilized in engineering praxis;
- is able to employ today's high level programming languages and their main tools and programming environments level;
- is able to use discrete models for solving practical problems;
- is able to compile logic schemas;
- knows how to compare different microprocessor architectures, to analyse I/O in microcomputer, knows different types of storage and I/O devices. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 24.0 ECTS credits - +MODULE: Mechanics 18.0 ECTS credits (Core studies)AimsThe aim of this module is to:
- give basic and general knowledge and skills needed for the analysis of machines',
instruments' mechanisms' and other products' functionality and design, for the calculations of their kinematic, dynamic, precision, stability, service life and reliability parameters; for the choice, dimensioning and design of design components and for solving problems related to metrology and measuring techniques in product design and manufacturing. Show more...Learning outcomesThe student:
- knows mechanisms along with the general purpose design and functional componets used in machinery;
- knows methods and practices of machinery design assuming their manufacturing aspects;
- understands physical phenomena and processes present in machinery and machine elements materials under loads;
- understands general purpose machine elements manufacturing options and principles of assuring manufacturing effectiveness.
- is able to calculate parameters characterising movements in machinery, component loads and respective stresses, strains and displacements;
- is able to choose, design and optimise general purpose machinery components;
- is able to design 3D models of structures, structural and functionality schemes, component and assembly drawings with respective tolerances;
- is able to use techniques necessary for modern technical measurement and for analysis of the results of reliability and quality assurance tests of components. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 18.0 ECTS credits - +MODULE: Technology and manufacturing 18.0 ECTS credits (Core studies)AimsThe aim of this module is to:
- develop skills to design and control technology systems and manufacturing processes;
- develop understanding on supply chain utilization for different technical projects;
- give basic theoretical and practical knowledge for the selection of technical systems, for analysis of their behavior and their modeling and for optimizing their structures and optimal control of energy flows;
- give knowledge about possibilities and design of mechatronics applications ;
- give theoretical and practical knowledge in characteristics, applicability in production and programming of technology installations, CNC and robotic devices. Show more...Learning outcomesThe student:
- has knowledge in possibilities and applications of logistics in industry, regionaal, and globaal levels;
- has general knowledge in selecting, designing and exploiting hydro, pneumo, electrical and thermal actuators;
- is able to analyse and optimize hydro, pneumo, electrical and thermal actuating mechanisms taking into account specific application demands;
- knows how to compile proper models for hydro, pneumo, electrical and thermal actuating mechanisms to characterize respective work processes;
- knows basics of automation using pneumo and hydro systems and is able to compile basic electro-pneumatic schemes;
- knows basics of today's CNC and robot technology, robot sub-systems and their application principles;
- is able to design basic CNC and robot applications to solve real industrial problems;
- has an overview of basic technology appliances and their structure. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 12.0 ECTS creditsElective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 6.0 ECTS credits - +MODULE: Design and Engineering 18.0 ECTS credits (Special studies)AimsThe aim of this module is to:
- develop a logical, analytical
and algorithmical thinking; a systematic and model based approach for solving mechanical engineering problems and tasks;
- give basic knowledge and skills for applying CAD systems to engineering work. CAD systems are a "second literacy" for a modern engineer;
- gain analytical, problem solving, judgment and decision-making skills by working through a problem which requires initial analyses, the evaluation of alternative solutions and the choice of a specific approach;
- realize that following the principles of design and product development, is the shortest and fastest way to marketing of new products competitively in the world market. Show more...Learning outcomesThe student:
- using models, can analyse relations and behaviours between systems and entities; can explain the purpose of the algorithms and methods applied;
- understands role of industrial design and realises conceptual design tasks;
- knows the methods and tools for creating engineering applications;
- is able to use different parametrical 3D CAD Systems;
- masters the specialist terminology used in the field and has an overview of CAD/CAM/FEM systems' possibilities for solving different product development subtasks;
- is able to formulate the problem statement and the list of criteria. The knowledge of methods of creative problem solving and the ability of applying it;
- is able to provide market and customer analyses and to evaluate the risks in product development environment. The capability to outline the product marketing strategy and shape the product price in the context of product life cycle cost. Show more...Compulsory courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: 12.0 ECTS creditsElective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 6.0 ECTS credits - +MODULE: Integrated Engineering 6.0 ECTS credits (Special studies)AimsThe aim of this module is to:
- create new innovative solutions
in topics like Industrial Engingineering & Management; Design & Engineering; Mechatronics; Materials and Processes for Sustainable Energetics; Software Engineering; Cyber Security;
- give students an experience of working in multidisciplinary teams in a development project;
- conduct and organize inclusive development project;
- develop students' integrated skills;
- develop experimental skills including rapid prototyping methods;
- develop visualization and simulation skills;
- organize and conduct an experimenting development project;
- provide students practical experience in real engineering and technology in university R&D lab or in enterprise. Show more...Learning outcomesUpon completion of this module the student will be able to:
- work in multidisciplinary development teams, e.g in topics as Industrial Engingineering & Management; Design & Engineering, Mechatronics, Materials and Processes for Sustainable Energetics, Software Engineering, Cyber Security;
- work with conceptual solutions and develop R&D solutions;
- tie visions with social, cultural and technological trends;
- visualize ideas and use different rapid research methods;
- use different specific methodologies for understanding problems;
- conduct and evaluate experiments;
- self-critically analyse the outcome of the work;
- verbally and visually present the results of their work;
- is familiar with the content of work based on the example of an actual enterprise;
- has acquired practical experience in solving engineering problems;
- has acquired practical entrepreneurial and team-work experience;
- has acquired practical experience in professional work. Show more...Elective courses:Course titleCourse codeECTS creditsHours per weekLecturesPracticesExercisesE/P-F.Ass./ Gr.Ass.Teaching semesterTotal: at least 6.0 ECTS credits - +MODULE: Free choice courses 6.0 ECTS credits (Free choice courses)AimsTo give students possibility to develop own knowledge and skills to wide the horizon and realise individual intrest through the optional courses.Learning outcomesKnowledge and abilities connected to student special interests
according to the future specialisation preferences Show more... - +MODULE: Bachelor thesis 6.0 ECTS credits (Graduation thesis)AimsTo give experiences for compiling an engineering project and
skills to apply different theoretical knowledge for solving practical problems and to present the results as a completed set of technical documentation. The topic of the work should be chosen according further specialization. Show more...Learning outcomes- experience and skills for formulating engineering problems and for compiling a work plan;
- ability to compile a set of technical documentation for engineering problem solution;
- ablility to apply theoretical knowledge for engineering problem analysis and solution synthesis. Show more... - +STANDARD STUDY PLAN: Autumn daytime study