Optical Design Using ZEMAX

Who should attend: Engineers who need to learn optical design theory, principles, and the use of the ZEMAX Optical Design Program. This course covers first and third order theory, imaging properties, glass properties and selection, and classical design techniques.

Attendees will learn how to use ZEMAX, including defining optical systems, constructing merit functions, and performing optimizations. Diagnostic tools are also covered.

This is the perfect course for those who need a basic knowledge about optical system theory and design.

You do not need any prior knowledge of optical design or ZEMAX to benefit from this class.

This introductary course also includes a half-day session on Designing for Manufacture, taught by Eddie Judd of Davin Optronics. Eddie has many years' experience in the design and manufacture of optical systems.

First order optics

Refraction and reflection
Glass: definition and properties
Image formation and ray tracing
Stops, pupils, marginal and chief rays

Aberration theory

Aberration descriptions
Seidel coefficients
Identifying aberrations
Aberration balancing
Chromatic aberrations

Use of ZEMAX

How optical design programs model lenses
The surface model
Overview of the manual and help system
The ZEMAX user interface
Conventions and definitions
Surface, field, wavelength, system data
Apertures, F/#???s
Use of solves and variables
Surface apertures
Co-ordinate transformations

ZEMAX diagnostic tools

Ray fans and spot diagrams
RMS and through-focus plots
2D, 3D, wireframe, and solid model layouts
MTF plots
Field curvature and distortion
Diffraction effects
Other diagnostic tools

Singlet design

Defining the initial system
Merit function construction
Using optimization
setting variables
Boundary constraints

Designing achromats

Controlling magnification, EFL, spacings
Use of solves
Correcting chromatic aberrations
Glass selection and optimization

More complex systems

Diffraction
Double Gauss
Collimation
Spectrometers
Relay lenses
Beam expanders
Designing with stock lenses
Zoom lens design
Tilted and decentered systems
Scanning systems
Afocal systems

Pupil Modelling

Vignetting factors
Apodization
Ray aiming

Designing with mirrors

Telescopes, fold mirrors
Newtonian, Maksutov
Off axis designs

Introduction to tolerancing

Tolerance types
Tolerance analysis
Test plate fitting

Designing for Manufacture

(this section is taught by Eddie Judd of Davin Optronics)

Manufacturing methods and limits of accuracy [How the manufacturing process and the lens shape control the limits of precision and the costs]
Mounting of lenses [How the design of the mounting influences the precision of centration and spacing]
Using the merit function to control manufacturability [Control of thickness, curvature, ray incidence angles, for example]
Environmental Considerations [How vibration and atmosphere influence glass choice, spacing techniques, lens thickness etc.]
Effects of the design on coating performance [Interaction of surface curvatures and ray incidence angles on the uniformity of coatings and their efficiencies]
Desensitising techniques [Using the multi-configuration editor to reduce sensitivity to decentration errors, for example]
Dimensioning of components [Reducing errors in manufacture by using round figure dimensions]
Glass selection [Selection of glasses for optimum cost, design suitability and reducing risks of non-availability]
Use of tool lists [Whether to work to a tool list or not!]
Measurement and testing [Never forget that a lens has to be tested and measured throughout its manufacture]

Timetable

Registration Form

Course Instructor

Neil Barrett is Director of Optima Research.

Leo Chen is Optical Engineer at Optima Research.

Eddie Judd is Former Technical Director of Davin Optronics.