Engineering and design

Engineering Maths 1B

Module code: H1034
Level 4
15 credits in spring semester
Teaching method: Workshop, Lecture
Assessment modes: Unseen examination, Multiple choice questions

On this module, you’ll explore topics of relevance to engineers.

In the physical world many quantities change over space and time. You’ll examine their characteristics as scalar or vector quantities. Then, you’ll develop the mathematical tools needed to describe these changes. This will build to the application of vector calculus to problems in one, two and three dimensions, in both scalar and force fields.

You’ll continue to develop the tools necessary for the rest of the year. You’ll offer feedback in lectures, and use worked and guided examples and questions for practice.

Topics include:

  • integration of vectors – co-ordinates of centres of mass and moments of inertia
  • sequences and series – summation notation, arithmetic and geometric series
  • convergence to a limit, absolute and conditional convergence and tests for convergence
  • binomial series, the Binomial Theorem, general power series, and Maclaurin and Taylor series expansions and error estimations
  • classification of differential equations
  • solution of first order ordinary differential equations using separable variable and integrating factor methods
  • solution of second order ordinary differential equations with constant coefficients (homogeneous and non-homogenous)
  • matrices – calculation of eigenvalues and eigenvectors, linear independence of eigenvectors and basic properties
  • double integrals as surface integrals over rectangular and non-rectangular regions
  • volume integrals using cartesian, cylindrical and spherical co-ordinates
  • scalar field and vector fields
  • gradient of a scalar field – divergence of curl of a vector field
  • scalar and vector line integrals
  • surface and volume integrals in a vector field
  • the use of Gauss and Stokes’ Theorems to facilitate vector integration.

Module learning outcomes

  • Be able to apply differential and integral multivariate calculus to the evaluation of line, surface and volume integrals and have an appreciation of the applications in engineering analysis.
  • Understand how to calculate power series expansions and have an appreciation of the applications in engineering analysis.
  • Be familiar with matrix algebra, including the calculation of Eigenvalues and Eigenvectors, and have an appreciation of their applications in engineering analysis.
  • Understand a variety of methods used to solve first and second order ordinary differential equations and have an appreciation of their applications in engineering analysis.