| | Drawing equipment and use of instruments. Lettering, Geometric
construction, Sketching and shape description. Basic descriptive
geometry, Developments and intersections. Axonometric, oblique and
perspective drawings, Multiview projection, Principal views,
Conventional practice, and sectional views. Auxiliary views.
Dimensioning techniques. Parallel: Introduction to computer drawing,
Drawing aids, Geometrical construction, and the appropriate commands
of text, editing, plotting, sections, layers, pictorial views, and
dimensioning. Auxiliary views. | First Year | | | Thermodynamic concepts and definitions, states, properties, systems,
control volume; processes, cycles, and units; pure substances, equation of
states, table of properties; work and heat; the first law, internal energy and
enthalpy; conservation of mass; SSSF and USUF processes; the second
law, heat engines and refrigerators, reversible processes, Carnot cycle;
entropy, Clausius inequality, principle of the increase of entropy,
Efficiencies. | Third Year | | | Introduction; basic principles of thermodynamics, fluid mechanics and heat transfer.
Thermodynamics concepts and definitions, properties of pure substances, first law of
thermodynamics, system and control volume analyses, second law of thermodynamics.
Basic principles of fluid dynamics, conservation laws, basics of dimensional analysis,
external and internal flows. Heat transfer modes; conduction, convection and radiation. | Second Year | | | A systematic development of programming via flowcharts and pseudo
codes; The course highlights include: assignment, repetition, decision
making, arrays, file processing and subprograms in program construction.
Program design includes: algorithm design, procedures and data program
structure, module design, programming standards, program
documentation, testing, debugging, verification and validation, file
organization and processing, array processing, abstract data structures,
data driven programs and simulation. Matlab language will be used.
Homework problems and projects of direct engineering applications will
be assigned. | Second Year | | | Force systems; resultant, moment of a force, equivalent force-couple
system. Particle and rigid body equilibrium in one plane. Trusses and
Frames. Beams; shear force and bending moment diagrams. Center of
gravity and centroid. Area moment of inertia. Planar kinematics and
kinetics (Newton's second Law and work-energy method) of particles and
rigid bodies in rectilinear and curvilinear motion (normal and tangential
coordinates). | Second Year | | | Mathematical preliminaries, numerical errors and, loss of significance and
error propagation. Numerical solution of nonlinear algebraic equations,
Review of linear algebra (Solution of systems of linear equations).
Numerical solutions of systems of linear and non-linear algebraic
equations. Interpolation and approximation and curve fitting. Numerical
differentiation and integration. Numerical solution of differential
equations. Eigen value problems. Introduction to numerical solution of
partial differential equation. Applied examples from various areas of
engineering. | Third Year | | | Report writing, basics of metrology, inspection and measurements. Errors
& error analysis, uncertainty analysis, statistical methods, least squares
method. Basics of transducers. Static and dynamic characteristics of
systems. Measurement of flow, pressure, and temperature. Strain gauges,
strain rosettes | Fourth Year |
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