DLPU140A May   2024  – September 2025 DLP160AP , DLP160CP , DLP2000 , DLP2010 , DLP2010LC , DLP2010NIR , DLP2021-Q1 , DLP230GP , DLP230KP , DLP230NP , DLP300S , DLP3010 , DLP3010LC , DLP301S , DLP3020-Q1 , DLP3021-Q1 , DLP3030-Q1 , DLP3034-Q1 , DLP3310 , DLP4500 , DLP4500NIR , DLP4620S-Q1 , DLP4621-Q1 , DLP470NE , DLP470TE , DLP4710 , DLP4710LC , DLP471NE , DLP471TE , DLP471TP , DLP480RE , DLP500YX , DLP5500 , DLP550HE , DLP550JE , DLP5530-Q1 , DLP5530S-Q1 , DLP5531-Q1 , DLP5531A-Q1 , DLP5532-Q1 , DLP5533A-Q1 , DLP5534-Q1 , DLP6500FLQ , DLP6500FYE , DLP650LE , DLP650LNIR , DLP650NE , DLP650TE , DLP651LE , DLP651NE , DLP660TE , DLP670RE , DLP670S , DLP7000 , DLP7000UV , DLP780NE , DLP780TE , DLP781NE , DLP781TE , DLP800RE , DLP801RE , DLP801XE , DLP9000 , DLP9000X , DLP9000XUV , DLP9500 , DLP9500UV

 

  1.   1
  2.   Abstract
  3. 1DMD Diffraction Efficiency Calculator Functionality
  4. 2Installation and setup
  5. 3Input Parameters
    1. 3.1  Pixel Models (DMD Micromirror)
    2. 3.2  Parameter Sweeps
    3. 3.3  Wavelength
    4. 3.4  Illumination Angle of Incidence
    5. 3.5  Tilt Angle
    6. 3.6  ƒ/Number (Illumination and Projection)
    7. 3.7  Enhance Slider
    8. 3.8  Diffraction Energy Plot
    9. 3.9  Array Size
    10. 3.10 Output File Name
    11. 3.11 Average Diffraction Efficiency and Photopic Diffraction Efficiency
    12. 3.12 Apodization
    13. 3.13 Run Simulation
  6. 4Coordinate System
  7. 5Examples
    1. 5.1 High F/Number Illumination
    2. 5.2 Mismatched Illumination and Projection F/Number
    3. 5.3 Cantilever Versus Torsional With Same Pixel Pitch
    4. 5.4 Side Diamond Diffraction Pattern
    5. 5.5 Apodization
  8.   Trademarks
  9. 6References
  10. 7Revision History

3.2 Parameter Sweeps

The diffraction modeling application allows the user to sweep over the wavelength, illumination angle, tilt angle, illumination and projection ƒ/# numbers. The application is initialized without the parameter sweep but can be turned on by selecting the Parameter Sweep button.

The user can input a start and stop value for the sweep along with a step size. For example, the wavelength can be swept over the visible spectrum in step sizes of 10nm as shown below:

Wavelegnth Parameter Sweep Figure 3-1 Wavelegnth Parameter Sweep

Likewise, the other parameters can be swept. A start and stop angle are selected for the Illumination Angle and Tilt Angle parameters and a start and stop ƒ/# is selected for the ƒ/# (Illumination) and ƒ/# (Projection) parameters.

Note: If the start and stop values for any parameter is the same, the model does not perform a sweep but runs the computation at that particular parameter only.

The step parameter is the scripts sampling rate. Step sizes can be any size. A smaller parameter step results in a finer, more accurate result but also takes longer to execute.

Another example is shown below for a tilt angle sweep. In this example the diffraction calculation calculates for 11º, 12⁰, and 13º mirror tilts.

Tilt Angle Paramater Sweep Figure 3-2 Tilt Angle Paramater Sweep