Course description: MATRICES, DETERMINANTS AND SYSTEMS Matrices and Determinants. Definition of matrix. Linear operations with matrices. Product of matrices. Transposed matrix. Properties. Types of matrices. Inverse matrix. Uniqueness and properties. Elementary operations. Elementary matrices. Equivalent matrices. Hermite canonical form. Gauss-Jordan method for calculating the inverse of a matrix. Range of a matrix. Calculation of the range through elementary operations. Definition and properties of the determinant of a square matrix. Application of determinants. LINEAR AND NON-LINEAR EQUATIONS SYSTEMS Terminology and notations. Equivalent systems. Gauss removing method. Rouché–Capelli theorem. Homogeneous Systems: Nullspace of a matrix. Systems solving: methods and iterative. VECTOR SPACE AND EUCLIDEAN SPACE -Rn Vector Space. Definition and properties. Linear dependence and independence. Properties. Basis and dimension of Rn vector space. Vector’s coordinates. Change of basis in Rn. Vector subspaces. Characterisation. Equations of a subspace. Basis and dimension of a subspace. -Rn Euclidean Vector Space.Scalar product. Module of a vector and angle between vectors. Orthogonal and orthonormal basis. Method for orthonormalisation of Gram–Schmidt. DIAGONALIZATION OF MATRICES Eigenvalues and eigenvectors of a square matrix. Properties. Diagonalizable matrix. Diagonalization. Diagonalization of symmetric matrices by orthogonal similarity. Powers of a diagonalizable matrix. Jordan canonical form for matrices of order two and three. CONICS AND QUADRICS -Conics Definition of conic. Matricial equation. Reduced equation of a conic. Classification and main elements of conics. Study of ordinary conics. -Quadrics Definition of quadric. Matricial equation. Reduced equation of a quadric. Classification of quadrics. Study of ordinary quadrics. CURVES AND SURFACES – Flat curves. Concept of flat curve. Expressions of a curve: parametric, explicit and implicit. Tangent and normal in a point of a curve. Singular points and Ordinary points. Flat curves in polar coordinates. – Warped Curves Definition of a curve in the space. Equations of a curve. Ordinary point and Singular point. Arc length of a curve. Three-dimension space and Frenet Formula. Tangent, normal and binormal straight line. Curvature and twisting. Normal, rectifying and osculating planes. – Surfaces Concept of surface. Tangent plane and normal straight line to a surface. Surfaces of revolution and translation. Conical and cylindrical surfaces.

Course description: FUNCTIONS OF A VARIABLE Differential calculus of single variable functions. Real numbers and Complex numbers. Definition of function. Concept of continuity and limit. Calculation of limits. Concept of derivative. Interpreting the derivative. Calculation of derivatives. Mean value theorem. L’Hôpital’s rule Implicit derivative. Integral calculus of single variable functions. Primitive function. Calculation of primitive functions. Problem of the area of a flat region. Riemann’s integral. Rieman’s integral properties. Mean value theorem. Fundamental Theorem of Calculus and Barrow’s rule. Applications of integrals. Improper integral.SEQUENCES AND SERIES Real sequences. Limits of a sequence. Concepts of convergence and divergence. Real series: of positive terms, alternating and of whichever terms. Concepts of convergence and divergence. Geometric series and simple harmonic series. Convergence criteria. Power series. Taylor’s theorem. Taylor and McLaurin Series. NUMERICAL METHODS Numerical equation solving. Polynomial interpolation. Function approximation. Numerical differentiation and integration. DIFFERENTIAL CALCULUS OF SEVERAL VARIABLES FUNCTIONS Introduction to several variables functions. Surfaces in the space. Continuity and limits. Partial derivatives. Differentiability. Chain rule. Directional derivatives. Implicit derivative. Optimisation of several variables functions. Lagrange multipliers. INTEGRAL CALCULUS OF SEVERAL VARIABLES FUNCTIONS Iterated integrals. Double and Triple integrals. Applications. Variables changes: Polar, cylindrical and spherical coordinates.

Course description: BASIC GEOMETRIC CONSTRUCTIONS. Elementary geometry flat transformations. Geometric traces. Scales. Translation, rotation, symmetry and homothesis affinity and homology diedric system FUNDAMENTALS AND APPLICATIONS OF DISTANCES Auxiliary views. Rotations. Changes of plances projections of a flat figure angles. Introduction to the study and representation of regular polyhedral surfaces. Prism and pyramide cylinder and cone sphere. DIMENSIONED DRAWING SYSTEM Fundamentals and applications of distances. Auxiliary views. Rotations. Angles. Flat figures representations. Dimensioned representation of bodies and surfaces building roofs Topographical surfaces. INTRODUCTION TO AUTOCAD AIDED DESIGN BASIC CONCEPTS Autocad environment. Drawing and edition basic commands.

Course description: INTRODUCTION TO PHYSICS KINEMATICS; GENERAL CONCEPTS; STUDY OF MOVEMENTS PARTICLE DYNAMICS; NEWTON PRINCIPLES; WORK AND ENERGY SYSTEM OF PARTICLES DYNAMICS RIGID BODY DYNAMICS THERMODYNAMICS; HEAT AND TEMPERATURE; THERMODYNAMIC TRANSFORMATIONS

Course description: THEORY Introduction to computer science (4 hours) Definitions. Computer basic functions. Software: operative systems, programming languages and applications. Databases.

PROGRAMMING FUNDAMENTALS (26 hours)
Introduction to the software life cycle.
Algorithm: concept, elements and representation. Structured programming.
Modular/top-down design.

WORK PLACEMENTS
Developing programmes under a programming language. Java (26 hours) Types of primitive data.
Variables, constants and operators. Selection and iteration statements. Text files.
Tables (vectors and matrices). Modular/top-down design

Use of computing applications in engineering (4 hours) Databases management system.

Course description: INTRODUCTION TO MATERIALS SCIENCE AND ENGINEERING Introduction to Materials Science and Engineering. STRUCTURE, LAYOUT AND MOVEMENT OF ATOMS. Crystalline structures Crystalline defaults Diffusion in solids PROPERTIES OF MATERIALS Mechanical properties, break and tests. Other physical properties Chemical properties CONTROL OF PROPERTIES AND MICROSTRUCTURE Plastic deformation in metals Phase diagrams Phase transformations Handling and controlling thermal, electrical, magnetic and optical properties. ENGINEERING MATERIALS: PROPERTIES, APPLICATIONS AND PROCESSING. Metallic alloys Ceramic materials Polymeric materials Composite materials Functional materials. SELECTION OF MATERIALS IN INDUSTRIAL DESIGN Criteria for selecting materials PRACTICAL UNIT Thermal treatments: Normalised, hardened, tempered on F114 steel Charpy tests: impact toughness on F114 steel. Resin deep-drawing of samples for metallographic preparation. Tension tests on F114 steel: determination of the elastic module, elastic limit, tension resistance, shear stress, ductility, elastic energy and plastic energy. Vickers, Rockwell and Brinell hardness tests. Metallographic preparation and microscope observation of deep-drawn samples with different thermal treatment.INTRODUCTION TO MATERIALS SCIENCE AND ENGINEERING Introduction to Materials Science and Engineering. STRUCTURE, LAYOUT AND MOVEMENT OF ATOMS. Crystalline structures Crystalline defaults Diffusion in solids PROPERTIES OF MATERIALS Mechanical properties, break and tests. Other physical properties Chemical properties CONTROL OF PROPERTIES AND MICROSTRUCTURE Plastic deformation in metals Phase diagrams Phase transformations Handling and controlling thermal, electrical, magnetic and optical properties. ENGINEERING MATERIALS: PROPERTIES, APPLICATIONS AND PROCESSING. Metallic alloys Ceramic materials Polymeric materials Composite materials Functional materials. SELECTION OF MATERIALS IN INDUSTRIAL DESIGN Criteria for selecting materials PRACTICAL UNIT Thermal treatments: Normalised, hardened, tempered on F114 steel Charpy tests: impact toughness on F114 steel. Resin deep-drawing of samples for metallographic preparation. Tension tests on F114 steel: determination of the elastic module, elastic limit, tension resistance, shear stress, ductility, elastic energy and plastic energy. Vickers, Rockwell and Brinell hardness tests. Metallographic preparation and microscope observation of deep-drawn samples with different thermal treatment.

Course description: DESCRIPTIVE STATISTICS REGRESSION AND CORRELATION THEORY OF PROBABILITY.CALCULATION OF PROBABILITIES ONE-DIMENSIONAL AND TWO-DIMENSIONAL RANDOM VARIABLES. DISCRETE AND CONTINUOUS DISTRIBUTIONS STATISTICAL INFERENCE POINT AND INTERVAL ESTIMATION HYPOTHESIS TESTING. PARAMETERS HYPOTHESIS TESTING INTRODUCTION TO OPTIMISATION

Course description: OSCILLATIONS WAVES: CHARACTERISATION; PROPAGATION FIELDS OF CENTRAL FORCES; ELECTROSTATIC FIELD; GRAVITATIONAL FIELD ELECTRIC CURRENT MAGNETOSTATIC FIELD ELECTROMAGNETIC INDUCTION

Course description: THE COMPANY AND THE ECONOMIC SYSTEM Concept of economy The transformation curve Fundamental economic problems The economic systems The economic agents Introduction to the markets functioning THE COMPANY AS AN ECONOMIC REALITY Concept of company. Functions of companies The constituting elements of a company. Classification of companies The companies according to their legal form. Concept of businessman The businessman within the current company reality. The entrepreneurs THE COMPANY AS A SYSTEM Managing roles Concept and properties of the systems Typology of the systems Conceptual elements of the company as a system The subsystems within the company The business environment THE FINANCIAL FUNCTION Investment and funding Fundamental preliminary concepts The planned investment Funding sources or instruments in the company The own resources The third party’s resources Profit and profitability MARKETING IN THE COMPANY The commercial subsystem. Definition of marketing The market: concept, segmentation and strategies. The marketing-mix The product. The price The place. The promotion THE PRODUCTION SUBSYSTEM The production activity: concept and types Concept and elements of the production subsystem. Types of production processes Goals and decisions when administering production THE EFFICIENCY IN THE COMPANY Efficiency measures. The productivity Graphical analysis of the productivity functions. Elements affecting productivity Concept and classification of costs DIMENSION OF INSTALLATIONS Concept and criteria for dimension measures Dimension and scale economies Dimension and structure of costs Dimension, occupation rate and hysteresis of costs Methodology for determining the production capacity DECISIONS ON INSTALLATIONS LOCATIONS Decisions on company location and its installations Strategies for multisite location Procedures and elements for the decision-making process Quantitative methods for location PHYSICAL DISTRIBUTION OF INSTALLATIONS Concept, objectives and elements for on-site distribution Types of on-site distribution Methods for installations distribution DESIGNING AND MEASURING WORK Design of work Study of work methods Study of times PROJECT PLANNING, PROGRAMMING AND CONTROL Concept and stages in project management Concept and types of control Scope of control Project planning and control techniques

Course description: STRUCTURE OF MATTER QUANTITATIVE ASPECTS OF CHEMISTRY MATTER AGGREGATION STATES LIQUID STATE AND DISSOLUTIONS CHEMICAL THERMODYNAMICS CHEMICAL KINETICS CHEMICAL BALANCE ACID-BASE REACTIONS OXIDATION REDUCTION REACTION CHEMICAL FUNDAMENTALS OF CORROSION ORGANIC CHEMISTRY

Course description: VECTOR ANALYSIS Vector fields. Line integrals. Conservative vector field and independence of path. Green’s theorem. Surface integrals. Divergence. Divergence theorem. Rotational. Stokes’ theorem. ORDINARY DIFFERENTIAL EQUATIONS (ODE) Origin, definition and classification of the ODE. Main concepts. Solutions. Type of solutions. FIRST ORDER ODE: Existence and uniqueness of solution theorem. Geometric interpretation of the equation. y’=F(x,y)(placements). Differential equations (DE) with separable to reducible variables. Reducible to homogeneous DE. Exact DE. Reducible to exact: Integrating factor. First order linear DE. Definitions. Resolution. Bernouilli equation. Orthogonal and isogonal trajectories. INTRODUCTION TO THE PARTIAL DIFFERENTIAL EQUATIONS LINEAR DE OF SECOND ORDER OR HIGHER Definitions. Existence and uniqueness theorem. Vector treatment of solutions. Linear Homogeneous Constant-Coefficient ODE: cases for resolution. Full linear ODE: undetermined coefficients method and method of variations of parameters. Variable changes. Euler equation. Converting a linear equations system into a higher order equation POWER SERIES SOLUTION OF DIFFERENTIAL EQUATIONS Application of the power series to the solution of equations. LAPLACE TRANSFORM Introduction. Definition. Calculation of transforms of elementary functions. Properties. Convolution product. Inverse transform. Properties. Application for the solution of differential equations and integrals and linear equations systems.

Course description: INTRODUCTION AND PRELIMINARY CONCEPTS Object and purpose. Model of solid. Mechanical prism. Balance conditions and stresses.

STRESSES
Stress vector. Stress matrix. Main stresses and directions Intrinsic component. Mohr circles.

DEFORMATIONS
Deformation vector. Deformation matrix. Main deformations and directions Intrinsic components Mohr circles.

GENERAL SETTINGS OF THE ELASTIC PROBLEM
Tension test. Hooke law. Transverse deformations. Poisson’s coefficient. Principle of superposition.
Generalised Hooke’s law. Lame’s equation.

THEORIES OF ANELASTIC ACTION
Introduction. Mohr criteria of limit states. Other criteria

THEORY OF FORCES. STATIC CHARACTERISTICS OF THE SECTION
Forces. Moments. Centre of gravity. Static moment. Moment of inertia.

AXIALS
Introduction. Axial diagrams Stresses. Deformations.

SHEAR AND BENDING
Introduction. Shear and bending diagrams.

BENDING STRESSES
Pure bending, Navier-Stokes law. Simple bending. Relation shear and bending.

BENDING DEFORMATIONS
Introduction. The elastics.
Mohr’s Theorems.

BUCKLING
Introduction. Critical load. Effective length.
Buckling according to Eurocodes.

Course description: AIR AND ACOUSTIC POLLUTION The atmosphere and its main pollutants. General principles on gas emissions treatment. Operations and processes for gas emissions treatment. Acoustic pollution.

WASTE POLLUTION
Introduction to waste regulations. Urban wastes.
Hazardous wastes. Radioactive wastes.
Soil pollution and repair.

ENVIRONMENTAL MANAGEMENT
Environmental impact assessment. Environmental management systems.
Life cycle analysis. Green labelling.

WATER POLLUTION
The natural water environment and the waste waters Physical operations for waste waters treatment. Chemical processes for waste waters treatment. Biological processes for waste waters treatment. Treatment and management of sludge.
Examples of waste waters treatment plants.

Course description: STATICS OF THE RIGID SOLID KINEMATICS AND DYNAMIC OF THE RIGID SOLID Kinematics of machines and mechanisms Dynamics of machines and mechanisms GENERAL CONCEPTS ON MACHINES AND MECHANICMS LEVIES AND GEARS

Course description: PROPERTIES AND STATES OF PURE SUBSTANCES APPLICATIONS OF THE THERMODYNAMICS PRINCIPLES MECHANISMS FOR HEAT TRANSFER Conduction, convection and radiation Combined applications of the heat transfer mechanisms heat exchangers

Course description: INTRODUCTION TO AUTOMATICS REGULATION Introduction to Automatics regulation. Description of Control Systems. Revision of mathematical basis and modelling of dynamic systems Time response Analysis. Structures of industrial regulators. INTRODUCTION TO AUTOMATION Definitions and structures. Introduction to logic systems Combinational and Sequential Systems and Applications. INTRODUCTION TO MODELLING OF AUTOMATION SYSTEMS AND PROGRAMMABLE AUTOMATES Introduction to modelling of Automation Systems. Petri networks. The programmable automates. Structure, programming Industrial applications.

Course description: THE P-N JUNCTION AS A DIODE Qualitative theory of the P-N junction Characteristics and functioning of the diode. Approaches. Circuits with diodes. Rectification. The Zener diode. The Zener regulator. THE BIPOLAR JUNCTION TRANSISTOR (BJT) Morphology. Functioning regions. Characteristic curves. The BJT as an amplifier. The BJT as a switch. Pulse Wide Modulation (PWM). JOINT FIELD EFFECT TRANSISTOR (JFET) Morphology. Functioning regions. Characteristic curves. The MOSFET as an amplifier. The MOSFET as a switch. THE OPERATIONAL AMPLIFIER (OA) Amplification and features. The feedback. OA ideal model. Basic settings. DIGITAL ELECTRONICS AND DIGITAL INTEGRATED CIRCUITS Analogue vs digital. Binary system. Digital encoding of information. A/D and D/A converters. The clock. Series/parallel communications. Logic gates. Design and optimisation of logic circuits. Logic families.

Course description: METHODS FOR CIRCUITS ANALYSIS Introduction

RESISTIVE CIRCUITS COILS AND CONDENSERS
Methods for circuits analysis

SINGLE PHASE AND THREE-PHASES CIRCUITS ANALYSIS SINUSOIDAL SIGNALS
Analysis in the sinusoidal steady state Power in the sinusoidal steady state Three-phases balanced systems.

ELECTROMETRICS
Fundamentals of electrical measurements Analogue and digital instruments Conditioning of signal Measurement methods.

BASIC PRINCIPLES OF ELECTRICAL MACHINES
Basic elements of electrical machines Balance of energy in electrical machines Classification of electrical machines.

Course description: LABORATORY PLACEMENTS Workshop security Metrology Sand moulding Conventional machining and CNC Welding PROBLEMS Metrology Forming technologies and processes with material preservation Forming technologies and processes with material removing Joining technologies THEORY Manufacturing systems Manufacturing engineering and processes CAx Systems and Manufacturing management systems. CIM Production systems. Plant engineering Emerging manufacturing systems METROLOGY Fundamentals of metrology Dimensional metrology Metrology of lengths and angles Metrology of surface finish Metrology of forms Adjustment and tolerances FORMING TECHNOLOGIES AND PROCESSES Forming technologies and processes with material preservation Introduction to forming with material preservation Consolidation processes Deformation processes. Advanced processes FORMING TECHNOLOGIES AND PROCESSES WITH MATERIAL REMOVING Introduction to forming processes with material removing Conventional machining processes Cutting tools Machining fundamentals JOINING TECHNOLOGIES Introduction to forming with provision of material Welding joining processes Symbolic representation of welding Advanced processes with provision of material

Course description: CALCULATION OF PIPELINES, CHANNELS AND FLUID SYSTEMS ONE DIMENSIONAL LAMINAR FLOW IN LIQUIDS IDEAL FLUIDS BASIC PRINCIPLES IN FLUID MECHANICS Statics of fluids Kinematics Integrals applied to finite volumes. CONSERVATION OF MASS EQUATION Continuity equation Equation of conservation of quantity of momentum. Integral form. Differential form Equation of conservation of energy. Integral form. Differential form. PROPERTIES OF FLUIDS AND DIMENSIONAL ANALYSIS Introduction. Forces acting on a fluid Thermodynamics. Transport phenomena Dimensional analysis.

Course description: INTRODUCTION TO INDUSTRIAL TECHNICAL DESIGN. INDUSTRIAL FORMS AND THEIR STANDARDISED REPRESENTATIONS The industrial technical design instrumentation and its practices standardised representations. Conventionalisms in industrial design. Cuts, sections, breaks and other conventionalisms auxiliary views Sketching. DIMENSIONING General on dimensioning. Dimensioning according to manufacturing process. SIGNS FOR SURFACE FINISHES Surfaces finishing symbols of surface status. TOLERANCES Dimensional tolerances. Geometric tolerances. CONSTRUCTION ELEMENTS: NON DETACHABLE JOINTS Riveting and welding. CONSTRUCTION ELEMENTS: dETACHABLE JOINTS Flange and threads. Screws, nuts and washers. Supplementary security systems. Keys and keyseats. Hinge pins. ORGANS OF MACHINES Trees. Couplings. Spring bases. Pulleys Toothed wheels. ENSEMBLE AND EXPLODED DIAGRAM General considerations. USEFUL CONSIDERATIONS FOR INDUSTRIAL DESIGN ALIGNMENT. SYMBOLS AND STANDARDISATION basic concepts for isometric alignment of pipes in processes plants. symbols and standardisation basic concepts for alignment of electrical schemes. symbols and standardisation basic concepts for alignment of printed circuits. symbols and standardisation AIDED DESIGN Design aids and edition dimensioning Blocks and attributes

Course description: GENERAL ON ELECTRICAL MACHINES STATIC ELECTRICAL MACHINES ROTATIONAL ELECTRICAL MACHINES FIRST PART ELEMENTS OF MANOEUVRE, COMMAND, CONTROL AND PROTECTION OF ELECTRICAL ENGINES ELECTRICAL DRIVERS OF CC AND AC

Course description: AMPLIFICATION. INTEGRATED AMPLIFIERS. Introduction. Types and characteristics. Power and decibels. The model of voltage booster. Response in frequency in amplifiers. Supply sources and performance. THE OPERATIONAL AMPLIFIER. ANALYSIS AND FEEDBACK Introduction. The ideal operational amplifier. Deviations from the idealized operational amplifier. Structure of operational amplifier. Feedback: concepts, interpretation, advantages and disadvantages. Types of feedback. Practical feedback networks with operational amplifiers. Basic amplifier circuits. LINEAR APPLICATIONS WITH OPERATIONAL AMPLIFIERS. SPECIAL AMPLIFIERS Introduction. The differential amplifier. The instrumentation amplifier. The converter voltage-current and current-voltage. Offset compensation. Accuracy rectifiers: medium wave and double wave. Peak detector. NON LINEAR APPLICATIONS OF OPERATIONAL AMPLIFIERS The operational amplifier as a comparator. Commercial comparators. Comparators with hysteresis. Clippers-limiters. Exponential amplifier. Logarithmic amplifier. FILTERS Introduction. First order passive and active filters. Second order passive and active filters. Delyiannis- Friend passband filters. Universal filters. Transitional response OSCILLATORS Introduction. Waveform. Basic feedback principles. Barkhausen’s criteria. Generic oscillator. Wien bridge oscillator. Phase displacement oscillator. Twin-T network oscillator. Hartley Oscillator. Colpitts Oscillator. RC digital oscillator. Glass oscillator. APPLICATIONS Regulated voltage sources. Capacity commutation. The 555 integrated timer. Voltage generators. Analogue multipliers. Other integrated functions.

Course description: LOGIC GATES ANALYSIS Design with integrated Logic gates ANALYSIS AND DESIGN OF CIRCUITS Analysis and design of combinational circuits. Analysis and design of arithmetic circuits. Analysis and design of circuits with bistables SEQUENTIAL CIRCUITS: Analysis and design of counter circuits. and Analysis design with registers. AUXILIARY DIGITAL CIRCUITS ANALYSIS AND DESIGN OF MICRO-PROGRAMMABLE CIRCUITS The free hardware.

Course description: COMPONENTS AND STRUCTURES OF AN AUTOMATIC REGULATION SYSTEM MODELLING OF CONTROL SYSTEMS MASTER OF TIME AND SYSTEMS SIMULATIONS QUALITATIVE ANALYSIS OF THE TIME RESPONSE DESIGN OF CONTROLLERS; INTRODUCTION TO DIGITAL CONTROL

Course description: INTRODUCTION TO PLANNING AND CONTROL OF PRODUCTION INVENTORY MANAGEMENT AGGREGATE PLANNING MASTER PROGRAMMING COMPONENTS PROGRAMMING VERY SHORT TERM PLANNING AND CONTROL

Course description: INTRODUCTION TO LABOUR RISK PREVENTION ORGANISATION OF THE PREVENTION IN-COMPANY RESPONSIBILITIES AND PENALTIES CONCERNING PREVENTION. PERSONAL PROTECTION EQUIPMENT. MINIMUM PROVISIONS ON SAFETY AND HEALTH SIGNALLING. SAFETY AND PREVENTION IN ELECTRICAL AND OXY ACETYLENE WELDING HANDLING, MOVING AND TRANSPORTING LOADS. MACHINES SECURITY AGAINST MECHANICAL RISKS SECURITY PROVISIONS AT WORK PLACES PREVENTION AND PROTECTION AGAINST FIRES. ELECTRICAL RISKS ASSESSMENT OF POLLUTANTS. CHEMICAL POLLUTANTS. RADIATIONS SECURITY AND HEALTH STUDIES IN CONSTRUCTION WORKS

Course description: INTRODUCTION TO INDUSTRIAL AUTOMATION Fundamentals of industrial control Conventional automatisms Acting sensors Conditioning of signals LOGIC CONTROLLERS AND HALF-MEDIA CIRCUITS Logic controllers Programmable logic devices Design of logic controllers with programmable logic devices PROGRAMMABLE AUTOMATES Introduction to the programmable automate Programming of the automate Grafcet methodology, specific Gemma Interfaces guide INDUSTRIAL PROCESSES CONTROL SCADA Systems Industrial communication networks Distributed control systems Standardisation and protection levels of industrial equipment

Course description: INTRODUCTION TO POWER ELECTRONICS General on different types of electrical energy conversion. General blocks scheme of a power system. Circuits in the power systems. Basic functions. Waveforms and characteristic values. Scope of application. SPECIFIC COMPONENTS OF POWER ELECTRONICS Thyristor and GTO. Block and conduction status. Ways of pulse. Times of pulse. Characteristics of gates. Blocking procedures. Other components STATIC SWITCHES General characteristics. CC static switches Block by parallel condenser. Block with inductance series with load. AC static switches. Natural block switches. Forced block switches. REGULATORS Introduction. Basic concepts. CC dissipative and non-dissipative regulators. Classification. Types of regulators. Choppers. Analysis chopper type A. Inverse, direct, elevator and buck. Analysis of chopper type B. Analysis of chopper type C. Analysis of chopper type D. Commutation in choppers. Commutation in resonant series circuit. Commutation in resonant parallel circuit. Control circuits. CONTROLLED RECTIFIERS Introduction. Single phase rectifier. Medium wave and bridge rectifier. Synchronisation pulse circuit. Simple polyphase rectifiers. INVERSORS Settings of the power circuit. The inverter as an intensity source. Regulation and filtration of output voltage. Study of a branch of an inverter bridge. Half bridge inverter. Full bridge inverter. Three-phase bridge. AC/AC CONVERTERS Introduction. Regulators of alternate current. Advantages of the modulation of vector space over the sinusoidal modulation. Applications. PRACTICE Basic CC circuit for pulsing a thyristor by gate. AC Circuit. Static switches. Control of pulse of a thyristor between 0º and 90º. AC Circuit. Control of pulse of a thyristor between 0º and 180º. CC-CC Converters, voltage elevator. CC-CC Converters, voltage reducer. Controlled rectifiers. Full wave controlled single phase rectifier.

Course description: Review of basic concepts. Language fundamentals C. Introduction to micro-controllers Micro-controller LPC4088. Organisational Chart Input/output ports. Timers. Analogue/digital converter. Interruptions. Point-to-point communication RS 232. Communication buses SPL I2C CAN, Ethernet, USB Real time systems.

Course description: CHARACTERISTICS OF THE ELECTRONIC MEASUREMENT DEVICES OSCILLOSCOPES FREQUENCY METERS AND METERS IMPENDANCE METERS AND PARAMETERS OF COMPONENTS SIGNAL GENERATORS AND SYNTHESIZERS INTERFERENCES PROGRAMMABLE ELECTRONIC INSTRUMENTS (GPIB. IEEE-488.2) SAMPLING AND QUANTIFICATION FRONTAL STAGE DIGITAL/ANALOGUE AND ANALOGUE/DIGITAL CONVERSION AND CLASSIFICATION OF SENSORS AND TRANSDUCTORS LINEAR DISPLACEMENT TRANSDUCERS AND POSITION SWITCHES ANGLE DISPLACEMENT TRANSDUCERS SPEED AND ACCELERATION TRANSDUCERS TEMPERATURE TRANSDUCERS PRESSURE TRANSDUCERS MEASURING FLOW MEASURING LEVEL PLACEMENTS IN LABORATORY

Course description: INTRODUCTION TO ENGINEERING PROJECT The engineering work: the industrial expert. The technical department and its organisation. Applications of computer science in the technical department. Assessments, valuations, technical reports and certificates. The industrial project: definition, object, stages, formal presentation and structure, processing. DOCUMENTS OF THE PROJECT Documents of the project: table of contents report and annexes. Documents of the project: planes. Documents of the project: tender specifications. Documents of the project: status of measurements. Documents of the project: budget. Documents of the project: reliable studies construction works management. REGULATIONS AND LEGISLATION The rules

Course description: The chemical engineering The industrial chemical processes Flowcharts UNIT OPERATIONS IN THE CHEMICAL INDUSTRY. Unit operation. Classification. Operations of matter transfer. Operations of heat transfer. Operations of transport of quantity of movement. Supplementary operations. Chemical unit operation. MACROSCOPIC BALANCES OF MATTER AND ENERGY Matter balances Energy balances

Course description: THERMAL ENERGY GENERATION POWER PLANTS ALTERNATIVE INTERNAL COMBUSTION ENGINES PRODUCTION OF COLD TURBO-MACHINES HYDRAULIC INSTALLATIONS

Course description: POWER TRANSMISSION IN MACHINES STRESS, TENSION AND DEFORMATION FAULTS BY STATIC CHARGE FAULTS BY FATIGUE AXLES AND SHAFTS SCREWS AND DETACHABLE JOINTS WELDING AND NON-DETACHABLE JOINTS SPRINGS BALL BEARINGS LUBRICATION AND DISPLACEMENT FLANGE GEAR WHEELS AND GEAR WHEELS REDUCERS BRAKES AND CLUTCHES STRAPS, CHAINS AND WIRES

Course description: SWITCHGEAR CALCULATION AND SIZING OF INDUSTRIAL ELECTRICAL INSTALLATIONS. ELECTRICAL PLANES AND SCHEMES OF INDUSTRIAL ELECTRICAL INSTALLATIONS. SOFTWARE FOR INDUSTRIAL ELECTRICAL INSTALLATIONS.

Course description:

Course description: INTRODUCTION TO CONTROL SYSTEMS NOT BASED ON MODELS MODELLING AND CONTROL WITH FUZZY LOGIC EXPERT SYSTEMS CONTROL SYSTEMS BASED ON NEURAL NETWORKS FAILURE-TOLERANT CONTROL INTRODUCTION TO GENETIC ALGORITHMS

Course description: CONTINUOUS TIME CONTROL SYSTEMS DISCRETE TIME CONTROL SYSTEMS ADAPTIVE CONTROL, PREDICTIVE CONTROL AND ROBUST CONTROL

Course description: INTRODUCTION Definition of signals. Operations with signals. Representation of signals. ANALYSIS AND TRANSMISSION OF SIGNALS Fourier series and transforms. Functions and properties of the Fourier transform. Transmission of signal through a linear system. Signal distortion over a communication channel. Energy of signal and energy spectral density. Power of signal and power spectral density. CONCEPTS AND ELEMENTS OF AN ELECTRONIC COMMUNICATION SYSTEM Introduction and elements of a communication system. Characteristics of emitters. Receivers. Antennas. LINEAR MODULATIONS Concept of modulation and reason to modulate. Amplitude modulation double side band with carrier (AM) (DSB). Amplitude modulation double side band with carrier suppressed (DSBCS). AM single side band (SSB). Vestigial side band (BSV). Generation scheme in linear modulations. Demodulation schemes. ANGLE MODULATIONS Basic concepts Narrow band FM. Wideband FM. Phase modulation (PM). FM modulators. FM demodulation. DIGITAL PASSBAND TRANSMISSION Geometric representation of signals and noise. Digital Amplitude-shift keying (ASK). Digital Frequency-shift keying (FSK). Phase-shift keying demodulation (PSK). Multilevel modulations. Error detection and probability. RANDOM PROCESSES Introduction. Definition of random process. Stationary process. Ergodic process. Central tendency measures. Covariances and correlation function. Transmission of a random process through a linear system. Passband random process. Power spectral density in a random process. Gaussian process. Noise and narrow band noise. BEHAVIOUR OF ANALOGUE SYSTEMS UNDER NOISE CONDITIONS Baseband systems. Amplitude modulation systems. Angle modulation systems. Optimal pre emphasis and de emphasis systems. BEHAVIOUR OF DIGITAL COMMUNICATION SYSTEMS UNDER NOISE CONDITIONS Optimal threshold detection. General analysis: optimal binary receiver. ASK, FSK, PSK and DPSK Systems. INTRODUCTION TO INFORMATION THEORY Measurement of information, uncertainty and entropy. Source encoding. Failure free communication through a channel with noise. Discrete memoryless sources. Discrete sources with memory. Mutual information. Channel capacity. Channel coding theorem. Information capacity theorem. Implications. Channel capacity of information with coloured noise. Rate-distortion theory.

Course description: ELECTRONIC INSTRUMENTATION IN RENEWABLE ENERGIES MONITORING OF RENEWABLE ENERGY SYSTEMS ELECTRONIC METEOROLOGICAL INSTRUMENTATION ELECTRONIC INSTRUMENTATION OF THE SYSTEM ELECTRONIC INSTRUMENTATION OF THE ELECTRICAL PRODUCTION DATA COLLECTION SYSTEMS