Objective

To provide students a sound knowledge of calculus and analytic geometry to apply them in their relevant fields

Syllabus

1. Derivatives and their Applications
   1. Introduction
   2. Higher order derivatives
   3. Mean value theorem
      1. Rolle's Theorem
      2. Lagrange's mean value theorem
      3. Cauchy's mean value theorem
   4. Power series of single valued function
   5. Indeterminate forms; L'Hospital rule
   6. Asymptotes to Cartesian and polar curves
   7. Pedal equations to Cartesian and polar curves; curvature and radius of curvature
2. Integration and its Applications
   1. Introduction
   2. Definite integrals and their properties
   3. Improper integrals
   4. Differentiation under integral sign
   5. Reduction formula; Beta Gama functions
   6. Application of integrals for finding areas, arc length, surface and solid of revolution in the plane for Cartesian and polar curves
3. Plane Analytic Geometry
   1. Transformation of coordinates: Translation and rotation
   2. Ellipse and hyperbola; Standard forms, tangent and normal
   3. General equation of conics in Catersian and polar forms
4. Ordinary Differential Equations and their Applications
   1. First order and first degree differential equations
   2. Homogenous differential equations
   3. Linear differential equations
   4. Equations reducible to linear differential equations; Bernoulli's equations
   5. First order and higher degree differential equation; Clairaut's equation
   6. Second order and first degree linear differential equations with constant coefficients
   7. Second order and first degree linear differential equations with variable coefficients; Cauchy's equations
   8. Application in engineering field