The first part of the course deals with the evaluation of trigonometric functions and solutions of trigonometric equations and its inverse, graphic representations of the trigonometric functions and operations on complex numbers. Also included are simple engineering applications involving right and oblique triangles. The second part discusses solid mensuration that includes calculation of the area of plane figures and volume of different solids. Volume calculations cover only solids whose formula is equal to Bh, where B is the area of the base and h is the altitude.

This is the 2nd part of the Engineering calculus course. The concept of integration process is introduced. Various formulas and techniques of integration are taken up for both single and multi-varied functions. Applications of the single and multiple integrals are provided through problems involving the evaluation of areas, volumes, work, and force.

Ordinary differential equations with emphasis on their applications in the analysis and solution of problems in engineering such as mixing, decomposition and growth, heat conduction, electric circuits, etc. Topics include ordinary differential equations of order one, degree one, higher order ordinary differential equations, Laplace transform and solution of differential equation by Laplace transform.

Basic concepts of probability, random variable, expectation, joint distributions, special discrete and continuous probability distribution, frequency distribution and statistical measures and sampling theory, hypothesis testing, and linear regression.

Concepts, techniques, quantitative tools, and decision-making process in the design planning, implementation, control and operation of production systems. These include work methods design and measurement, quality control, inventory control, plant location and layout, materials handling systems, production planning and scheduling.

Application of algebraic axioms on the operation and simplification of algebraic expressions including the various methods of solving algebraic, exponential, logarithmic equations, and inequalities. Word problems to provide ample ground to apply the principles learned are to give training on the logical approach to problem solving.

3 units The course is divided into two parts - a continuation of solid mensuration and analytic geometry. Solid mensuration part includes pyramids, sphere, frustum and similar figures. The analytic geometry part includes lines, conics and algebraic and polar curves.

Basic concepts of calculus such as limits, continuity, differentiability of functions. It aims to develop in the students the skills of differentiation of algebraic and transcendental functions involving one or more variables. Applications include maxima/minima, rate of change and related rates, tangents and normals and approximation problems.

Conceptual foundations of Newtonian mechanics. In examining Newton’s three laws of motion and their relevant consequences, vector methods as well as the basic concepts of calculus will be used.

Fundamental concepts of electricity and magnetism, It deals with Coulomb’s Law, electric field, Gauss’ Law, electric potential, capacitance, current and resistance, circuits, magnetic field, Ampere’s Law, Faraday’s Law of Induction, and Maxwell’s equations. In examining the concepts mentioned and its relevant consequences, vector methods, as well as the basic concepts of calculus will be used.

Algorithm development, programming concepts such as variables and constants, computer organization, memory systems. Hands-on experience on a personal computer is required to develop programs in C. language.

Mechanics of Rigid Bodies I (Statics) (MECAONE)
3 units Components and resultant of plane and space forces; equilibrium of forces; analysis of trusses, frames and beams; analysis of simple friction and belt friction; centroids of plane areas; centroids of volumes; moment of inertia of plane areas; moment of inertia of solid volumes; vector notation and its application.

Kinematics of particles and rigid bodies; rectilinear and curvilinear motion; motion of a projectile; motion of freely-falling bodies; kinetics of particles and rigid bodies; angular displacement, velocity and acceleration; application to connected systems.
Pre-requisite: Mechanics of Rigid Bodies I (Statics)

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