EDUCATIONAL EFFECTS ELECTRONICS FACULTY: 1 st level, Engineer EDUCATION LEVEL: full-time FORM OF STUDIES: general academic PROFILE: polish

Transcription

1 EDUCATIONAL EFFECTS FACULTY: ELECTRONICS MAIN FIELD OF STUDY: TELEINFORMATICS EDUCATION LEVEL: 1 st level, Engineer FORM OF STUDIES: full-time PROFILE: general academic LANGUAGE OF STUDY: polish SPECJALIZATION: TIP Teleinformation Networks Design TIU Teleinformation Networks Maintenance

2 MAIN FIELD OF STUDY EDUCATIONAL EFFECTS Faculty:: ELECTRONICS Main field of study: TELEINFORMATICS (TIN) Level of studies: 1 st level educational effect for I level studies for main field of study TIN K1TIN_W01 MAP1140 K1TIN_W02 MAP1148 K1TIN_W03 MAP1149 K1TIN_W04 MAP1151 K1TIN_W05 MAP1152 K1TIN_W06 MAP3019 K1TIN_W07 FZP1060 K1TIN_W08 ETEW001 K1TIN_W09 ETEW003 K1TIN_W10 AREW001 K1TIN_W11 ETEW008 DESCRIPTION OF MAIN FIELD EDUCATIONAL EFFECTS After I level studies in main field of study TELEINFORMATICS graduate: KNOWLEDGE Has fundamental knowledge of complex numbers, polynomials, matrix calculus and is able to use them to solve systems of linear equations, analytic geometry-plane, in space and conic sections. Has fundamental knowledge of properties of functions (trigonometric, power, exponential, logarithmic, cyclometric and their inverse functions), and also differential equation and indefinite integral of a single variable function, and ordinary differential equations. Knows the basic concepts of differential and integral calculus of functions of several variables, infinite series, power series, Fourier series and Laplace and Fourier transforms. He/she has a basic knowledge of probabilistic models (random variables, quantiles, moments, multidimensional random variables, sequences of random variables) necessary to understand the probabilistic issues. Has a basic knowledge of linear spaces, algebra (group, ring, field) and modular arithmetic. He/she has the basic knowledge of logic, calculus and discrete mathematics Has fundamental knowledge of classical mechanics, wave motion, phenomenological thermodynamics, physics of atomic nuclei, physics of a condensed phase. Know the fundamentals of metrology and measurement theory and technique of electrical and nonelectrical quantities. Knows the rules and read the documentation of the construction technology of electronic devices Knows theoretical basics of computer control engineering and robotics, principles how control engineering components work as well as robots components. Knows the basics of systems theory, the properties of the basic structures of systems, and methods for solving simple Correlation of educational effect for the field of Technical Sciences (T)) T1A_W07 T1A_W02 T1A_W07 (dla AIR) T1A_W02

3 K1TIN_W12 INEW002 K1TIN_W13 ETEW004 K1TIN_W14 ETEW005 K1TIN_W15 ETEW009 K1TIN_W16 ETEW006 K1TIN_W17 ETEW007 K1TIN_W18 TLEK001 K1TIN_W19 TLEK002 K1TIN_W20 TLEK003 K1TIN_W21 TLEK004 K1TIN_W22 TLEK005 K1TIN_W23 TLEK006 K1TIN_W24 TLEK007 problems of identification, recognition and control Knows basics of object-oriented engineering and programming methodology Knows basics of telecommunications and is able to define basic concepts in telecommunications knows basic concepts of the theory of digital signal processing, both deterministic and random, as information storage devices, particularly a sampling task, quantization, detection and filtration Knows basic notions and methods of mathematical statistics and their applications in the area of electronics, control engineering and computer science. Knows the internal structure and programming methods of microprocessors and microcontrollers Knows basics of information technologies (including network services) connected with information acquiring, processing and presenting. Student knows operating systems principles including concurrency, process synchronization, task scheduling, memory management, device management, security and protection subsystems, and file system structure. Has the general knowledge about the circuit theory including models of electric circuits elements, basic parameters and statements, Laplace transform, transfer function and steady state and transient analysis. Can use computer simulation of circuit analysis. He is able to indicate placement of encoders and decoders in the communication channel. He has knowledge of linear codes, can explain the idea of its operating and the way of its designing. One has knowledge of the computer networks, functionality, reference model, communication protocols, addressing rules and network elements. One can explain the network functionality, functions of switches, routers, servers and hosts, characterize Local, Metropolitan and Wide Area Networks. Has a basic knowledge regarding multimedia technology, particularly in telecommunication applications.. Is able to explain the rules of the operator computational algorithms to understand the laws of electromagnetism, define physical constants describing the phenomena of the electromagnetic fields. Can explain Maxwell equations, and physical phenomena and mechanisms of the electromagnetic fields in in vacuum and material media. Can describe the structure of a plane wave, propagation in different media and the laws of reflection and refraction phenomena. Student knows basic concepts and measures describing telecommunication traffic and its characteristics in teleinformatic networks. One can describe traffic in channel- T1A_W07 T1A_W07

4 K1TIN_W25 TLEK008 K1TIN_W26 TLEK010 K1TIN_W27 TLEK011 K1TIN_W28 TLEK020 K1TIN_W29 TLEK013 K1TIN_W30 TLEK015 K1TIN_W31 TLEK017 K1TIN_W32 TLEK033 K1TIN_W33 TLEK034 K1TIN_W34 TLEK035 K1TIN_W35 FLEW001 and packet switched networks Know how to explain the physical phenomena connected with transmission by cooper cable, optical fiber and radio wave propagation. Can describe various models of the transmission media. Know how to selekt and suggest appropriate transmission media for various teleinformatic systems. Has a basic knowledge of wireless network and systems operations. Has the knowledge of used procedures, protocols, and transmission techniques, which allows distinguishing application of different networks and systems. Is able to characterize radio communication system, identify the basic elements of an architecture and their functions. He has knowledge of cryptographic systems in telecommunications. He can name and describe cryptographic systems. He distinguish between symmetric and asymmetric encryption information. He can indicate placement of encoders and decipherers in the communication channel. Has knowledge of mathematical basics regarding the construction of information compression algorithms, is able to explain basic methods of lossy compression and is able to identify appropriate solutions to tasks related to the multimedia data compression. General knowledge in the field of electromagnetic compatibility. Ability to characterize the sources of interference, indicate their paths and methods of the protection of the devices. Ability to explain how to protect living organisms from electromagnetic fields. Is able to indicate typical systems and characterize rules of transmission, legal regulations and operation principles of: WPAN, WLAN IEEE a/b/g/n, WMAN (WiMAX) and WRAN (IEEE ), define the cognitive radio concept, describe the architecture and enumerate principal parameters of cellular systems of the 3 rd (UMTS) and the 4 th (LTE, LTE-Advanced) generation. Has knowledge on the modulation, the fiber optic and radio transmission. Is able to indicate transmission limitations of these media and describe physical phenomena related to them. Has expertise in data modelling, database design, and to obtain information from databases. Know the communication protocols of Wide Area Networks Explain and describe basic information related to technologies and protocols of local area computer networks Knows knowledge of the basic methods of inference (deduction, induction and abduction); has knowledge that is essential to understanding and interpreting social and philosophical considerations of engineer s T1A_W02 T1A_W08

5 K1TIN_W36 Etyka FLEW002 K1TIN_W37 Prawo aut PREW002 K1TIN_W38 ZMZ0340 K1TIN_W39 K1TIN_W40 INEW001 K1TIN_U01 MAP1140 K1TIN_U02 MAP1148 K1TIN_U03 MAP3019 K1TIN_U04 FZP1060 K1TIN_U05 FZP2079 K1TIN_U06 ETEW002 K1TIN_U07 INEW001 K1TIN_U08 INEW001 activity Has basic knowledge necessary to understand ethical and social conditions of an engineering activity. Knows and understands basic notions and rules related to industrial property protection and copyright laws; can use patent information resources Student has a basic knowledge of the management processes; knows functions, principles and tools of management and can identify the basic problems of management and businesses; knows the basic terms of quality management, understands the nature, objectives and determinants of the quality improvement process and can recognize and explain the basic methods and tools of quality improvement. Achieves effects in the KNOWLEDGE category for one of the following specializations: Teleinformation Networks Design Teleinformation Networks Maintenance knows the concept of the algorithm and the methods of its representation, the basic syntax of algorithmic languages, the concept of recursion, the principles of structured programming, basic algorithms for sorting and searching data, as well as dynamic and complex data structures. SKILLS is able to use correctly and effectively the knowledge of linear algebra and analytical geometry in qualitative and quantitative analysis of mathematical issues in the field of TIN is able to use correctly and effectively knowledge of differential calculus and integral calculus of a single variable function as well as ordinary differential equations in qualitative and quantitative analysis of mathematical issues in the field of TIN Is able to properly and effectively use the logic, proof techniques, mathematical induction, recursion, trees and graphs. Is able to use correctly and effectively already known principles and laws of physics in qualitative and quantitative analysis of physical issues of an engineering character Is able to plan and take measurements safely, analyse their results and asses the measurement uncertainty of the value of the measurand. Can construct a measurement system and perform measurements with analog and digital devices. Knows how to represent and code the algorithm as flowchart, how to solve simple programming tasks in the form of algorithms and propose the way how they could be tested Has the ability to use modern software development environments to create structural programs using: basic data T1A_W08 T1A_W10 T1A_W09 T1A_W11 T1A_W07

6 K1TIN _U09 ETEW003 K1TIN _U10 AREW001 K1TIN_U11 ETEW008 K1TIN _U12 INEW002 K1TIN _U13 ETEW005 K1TIN _U14 ETEW009 K1TIN_U15 ETEW006 K1TIN_U16 ETEW007 K1TIN_U17 TLEK001 K1TIN_U18 TLEK002 K1TIN_U19 TLEK003 K1TIN_U20 TLEK004 K1TIN_U21 TLEK005 K1TIN_U22 TLEK006 K1TIN_U23 TLEK007 K1TIN_U24 TLEK009 types, strings, loops, procedures and functions Can use the basic forms of design writing, cast techniques and describe the object model using various cross-sections. Is able to use software used in control engineering and robotics. has the ability to represent the expert knowledge and experimental knowledge in the form of block diagrams, graphs, and sets of logical expressions, in particular is able to create an input-output system and is able to construct a mathematical model of the system Is able to create independently object oriented programs. Is able to analyse signal properties in time-frequency domain and synthesize digital filters using dedicated software. Is able to use statistical methods using specialized software packages. Can prepare, implement and run the programs fixed to internal structure of microcontrollers. Is able to use text editors, spreadsheets, prepare multimedia presentations, edit information in the network. Student can use command processor of the chosen UNIX/Linux operating system distribution. S/he can design shell scripts using awk, fing, grep. Student can assess quality of scheduling and page replacement algorithms. Can solve simple DC circuits, also with operational amplifiers and controlled sources, can solve simple RLC networks in transient state and steady state, can solve simple nonlinear circuits, can calculate spectra of typical signals, can calculate voltages and currents in transmission line. He can analyze the properties of codes: the correction capability, efficiency and indicate the length of information words and code words on input and output encoder. He can point at systems, which use particular linear codes. One is able to configure hosts and routers in the Local Area Networks, to use Internet services, diagnostic tools and protocol analyzers to observe and analyze network events. Is able to use techniques of image acquisition, compression and recognizing in practical applications Is able to use the operator computational algorithms, calculate distributions of electric and magnetic fields, compute capacity, resistance and inductance of physical systems, present the cross-border phenomena. Student is able to analyze basic traffic engineering problems in teleinformatic networks and to solve them via simulation analysis. Is able to calculate the corrective and detective ability of code as well as its efficiency. Is able to design a linear block code as well as name and recognize the differences between T1A_U10

7 K1TIN_U25 TLEK020 K1TIN_U26 TLEK013 K1TIN_U27 TLEK015 K1TIN_U28 TLEK016 K1TIN_U29 TLEK017 K1TIN_U30 TLEK033 K1TIN_U31 TLEK034 K1TIN_U32 Blok 1 język K1TIN_U33 Blok 2 język K1TIN_U34 Blok 3 język K1TIN_U35 Blok 4 język codes. Is able to create scripts and functions for performing off-line experiments with speech and sound signals as well as with static and dynamic images. Is capable of using the documentation regarding compression standards. Is able to calculate the data transmission speed in a communication channel, determined by compression algorithms. Ability to configure testing stands and conduct basic research on emission and susceptibility of electronic and electrical device. Ability to elaborate and interpret final research results. Properly matches a radiocommunication system optimal with respect to the assumed purposes. Is able to match appropriate transmission parameters, estimate the actual performance of the following systems: WPAN, WLAN, WMAN as well as plan an optimal deployment of the network nodes, create the implementation and maintenance quotations. Is able to correctly select a cryptographic system for a specific application, is able to use premade cryptographic systems, is able to design a cryptographic system according to the requirements as well as write a computer program for its implementation. Is able to match appropriate parameters of the radio transmission chain and the fiber optic chain constituent elements as well as estimate the influence of the propagation environment on the transmission. Can prepare a database schema based on the model To be able to prepare a presentation that contains problems of Wide Area Networks designing and is able to discuss about these problems is able to independently make use of various sources of information in foreign languages, especially professional literature; integrate obtained information and apply in order to deepen specialised knowledge and broaden own language competence understands texts in a foreign language by reading and listening, concerning general and science and technical topics related to the sciences and science disciplines adequate to computer science has sufficient language proficiency to speak and write correctly, formulate and justify opinions, explain own point of view, present advantages and disadvantages of different solutions, participate in discussions and present general topics as well as topics connected with science and technology is able to use a foreign language in international professional environment taking into consideration intercultural knowledge and formal and informal register, according to the CEFR requirements for B2 level. T1A_U12 T1A_U13 T1A_U06 T1A_U06 T1A_U03 T1A_U06 T1A_U02 T1A_U06

8 K1TIN_U36 Internship K1TIN_U37 K1TIN_K01 FLEW001 K1TIN_K02 Etyka K1TIN_K03 Prawo aut K1TIN_K04 ZMZ0340 K1TIN_K05 WF K1TIN_K06 Has necessary qualifications to work in an industrial environment and knowledge of safety regulations associated with the job position Achieves effects in the SKILLS category for one of the following specializations: Teleinformation Networks Design Teleinformation Networks Maintenance COMPETENCES Is aware of importance and understands humanistic aspects and effects of an engineering activity; learns about the impact of technical activity on environment and social responsibility of science and technology connected with this activity. Identifies correctly and solves dilemmas connected with profession; is aware of the social role of technical university graduates; understands a need to prepare information and opinions concerning technological achievements and other aspects of an engineering activity, and shares them with society; is able to share such information and opinions in an understandable way considering different points of view. Understands legal aspects and consequences of an engineering activity. Student understands the idea of standardization, certification and quality management systems integration, environmental protection, industrial safety and information security; understands the idea of quality management, can identify the basic problems of quality management, including quality costs and the principles of dealing with them; knows the general rules of the establishing and developing the individual entrepreneurship forms. Has awareness of essential significance of individual and team activities extending beyond the engineering practice Achieves effects in the COMPETENCES category for one of the following specializations: Teleinformation Networks Design Teleinformation Networks Maintenance T1A_U11 T1A_K01 T1A_K02 T1A_K05 T1A_K08 T1A_K05 T1A_K06 T1A_K01 T1A_K06 T1A_K07 T1A_K01 T1A_K04

9 SPECIALIZATION EDUCATIONAL EFFECTS Faculty: ELECTRONICS Main field of study: TELEINFORMATICS (TIN) Level of studies: 1 st level Specialization: TELEINFORMATION NETWORKS MAINTENANCE (TIU) educational effect for I level studies for specializatio n: TIU S1TIU_W01 TLES204 S1TIU_W02 TLEK021 S1TIU_W03 TLES205 S1TIU_W04 TLES206 S1TIU_W05 TLES207 S1TIU_W06 TLES208 S1TIU_W07 TLES209 S1TIU_W08 TLEK027 S1TIU_W09 DESCRIPTION OF MAIN FIELD EDUCATIONAL EFFECTS After I level studies in main field of study TELEINFORMATICS and specialization TELEINFORMATION NETWORKS MAINTENANCE graduate: KNOWLEDGE Knows some models in the field of operational research used to describe the issues occurring in ICT systems and methods to solve practical problems of ICT described in terms operational research. One has knowledge of the diagnostics and observation methods and teleinformatic networks functionality on all the ISO/OSI reference model layers. Student has knowledge about standards of services/systems/networks/ management and construction of teleinformatic network management systems Student is able to characterize ITU/TMN, OSI/NM and ITSM (ITIL) management models. The student has knowledge of the switched Ethernet network and with VLAN technology. The student has knowledge of the protocols and methods for attaching LAN to WAN and ISP. Is able to identify applications, enumerate requirements, characterize multi-access and routing methods in the sensor network. Student knows principles of architecture of Internet applications, and rules of developing application for mobile users. He knows the basic structural and technological solutions for building web-based systems including intranet and extranet ones. He knows their strengths and risks One has detailed knowledge of radio network planning in accordance with the requirements of intra-and intersystem electromagnetic compatibility. The student has current knowledge on developments trends in the field of maintenance of Information and Communication Networks SKILLS Correlation of educational effect for the field of Technical Sciences (T) T2A_W04 T1A_W06 T1A_W05 S1TIU_U01 Distinguish devices and services of local area computer

10 TLES201 S1TIU_U02 TLES 202 S1TIU_U03 TLES203 S1TIU_U04 TLES204 S1TIU_U05 TLEK021 S1TIU_U06 TLES205 S1TIU_U07 TLES206 S1TIU_U08 TLES207 S1TIU_U09 TLES 208 S1TIU_U10 TLES209 S1TIU_U11 TLEK027 S1TIU_U12 TLES210 S1TIU_U13 TLES211 S1TIU_U14 TLEK032 network, design and construct a local computer network, configure router, design static and dynamic routing in TCP/IP networks, design classless addressing scheme Design a wide area computer network. Is able to design a database using Management System capabilities to optimize the allocation of queries and assigning permissions to users Can choose a model in the field of operational research and use it to describe selected problems occurring in the ICT system, select the method of solving these problems, and analyse and evaluate their effectiveness. One is able to measure transmission media parameters, run and observe the data transmission, IP network layer functionality, Internet access services and multimedia applications. Student knows, how to define requirements enabling the management systems design. Student is able to present main tasks of area networks maintenance and management. The student is able to configure Ethernet switches with VLAN technology, configure routing between VLANs and connect the border router to the WAN and ISP. Is able to match an appropriate system for building a sensor network satisfying pre-defined requirements, design the network, estimate its performance and operation costs. Student can choose appropriate software and hardware platform for mobile application to develop simple interactive applications with access to remote database. Student can prepare presentation reporting results of realized project task. He can take advantage of the structural and technological solutions to build widely understood Internet systems at certain scenarios. He can analyze, formulate objectives and make a comprehensive system design One can build models of all radiocommunication network elements, calculate the power budget of the radio link and the transmission range, choose the appropriate propagation models and ranges, analyze nonlinear phenomena in the receiver Is able to perform the assigned tasks as a part of the engineering team project (complex engineering task) in the area of the teleinformatics network design; is able to make economic analysis of the project; is able to develop an appropriate documentation Is able to present a presentation containing results of the final thesis, justify in discussion the means of realization and achieved effects of the project Is able to elaborate the final thesis in the form of an engineering project in the field of teleinformation networks and prepare appropriate documentation, including: is able to acquire information from literature, T1A_U15 T2A_U01 T2A_U08 T1A_U12 T1A_U12 T1A_U10 T1A_U05 T1A_U13

11 S1TIU_K01 TLES210 databases and other sources, is able to use analytical, simulation-related and experimental methods for formulating and solving tasks, is able to evaluate the utility and possibility of using new techniques and technologies, is able to identify and formulate the tasks specification, including untypical tasks, is able to design and make an apparatus, object, system or process. COMPETENCES Has skills to work in a team while implementing the complex engineering task; is able to play the assigned role within a team; is able to perform the assigned tasks according to the time- schedule of the whole project T1A_K02 T1A_K03 T1A_K04

12 SPECIALIZATION EDUCATIONAL EFFECTS Faculty: ELECTRONICS Main field of study: TELEINFORMATICS (TIN) Level of studies: 1 st level Specialization: TELEINFORMATION NETWORKS DESIGN (TIP) educational effect for I level studies for specializatio n: TIP S1TIP_W01 TLES101 S1TIP_W02 TLES103 S1TIP_W03 TLES102 S1TIP_W04 TLES105 S1TIP_W05 TLES107 S1TIP_W06 TLES108 S1TIP_W07 TLES109 S1TIP_W08 TLES110 S1TIP_W09 S1TIP_U01 TLES101 S1TIP_U02 TLES103 S1TIP_U03 TLES102 DESCRIPTION OF MAIN FIELD EDUCATIONAL EFFECTS After I level studies in main field of study TELEINFORMATICS and specialization TELEINFORMATION NETWORKS DESIGN graduate: KNOWLEDGE Student knows the basic issues related to artificial intelligence including classical and heuristic search algorithms, inference methods and decision making with uncertainty, the basic machine learning tasks. Has detailed knowledge regarding the design of wireless networks in accordance with compatibility requirements Student knows principles of architecture of Internet applications, rules of developing dynamic Internet services and application for mobile users. He knows the basic structural and technological solutions for building web-based systems including intranet and extranet ones. He knows their strengths and risks knows the basic principles of effective management of ICT (teleinformation) projects Has an advanced knowledge regarding TCP/IP protocols Has an advanced knowledge regarding Ethernet technology Possesses basics problems related to Windows systems administration The student has current knowledge on developments trends in the field of maintenance of Information and Communication Networks SKILLS Student can choose an appropriate artificial intelligence method for a given practical problem and s/he can assess it. Is able to analyze models of all wireless network elements, calculate losses in the radio link and the tranmitter range, use appropriate propagation models and match frequency bands, analyze various phenomena in the receiver Student can choose appropriate software and hardware platform for Internet or mobile application to develop simple interactive applications with access to remote database. Correlation of educational effect for the field of Technical Sciences (T) T1A_W06 T1A_W05 T1A_U15

13 S1TIP_U04 TLES104 S1TIP_U05 TLES105 S1TIP_U06 TLES106 S1TIP_U07 TLES107 S1TIP_U08 TLES108 S1TIP_U09 TLES109 S1TIP_U10 TLES110 S1TIP_U11 TLES111 S1TIP_U12 TLES112 S1TIP_U13 TLEK032 S1TIP_K01 TLES111 Student can prepare presentation reporting results of realized project task. Is able to formulate queries evaluate strategies for implementation, and prepare applications working with the database He can take advantage of the structural and technological solutions to build widely understood Internet systems at certain scenarios. He can analyze, formulate objectives and make a comprehensive system design Design local and wide area computer networks can develop and present stages of the ICT (teleinformation) project Can configure router, can design routing and classless addressing scheme in TCP/IP networks He can distinguish and configure Ethernet network devices and knows how to build a local area network. Possesses techniques, methods and procedures necessary for the administration of Windows systems Is able to perform the assigned tasks as a part of the engineering team project (complex engineering task) in the area of the teleinformatics network design; is able to make economic analysis of the project; is able to develop an appropriate documentation To be able to prepare a presentation that contains own results and is able to discuss objectively and justify his original ideas and solutions Is able to elaborate the final thesis in the form of an engineering project in the field of teleinformation networks and prepare appropriate documentation, including: is able to acquire information from literature, databases and other sources, is able to use analytical, simulation-related and experimental methods for formulating and solving tasks, is able to evaluate the utility and possibility of using new techniques and technologies, is able to identify and formulate the tasks specification, including untypical tasks, is able to design and make an apparatus, object, system or process. COMPETENCES Has skills to work in a team while implementing the complex engineering task; is able to play the assigned role within a team; is able to perform the assigned tasks according to the time- schedule of the whole project T1A_U12 T1A_U10 T1A_U05 T1A_U13 T1A_K02 T1A_K03 T1A_K04