The Science Behind the WaveDȳn® Platform

Explore foundational research behind dynamic aberrometry, objective refraction, HOA-correcting lens design and more

Research That Powers
Precision

At Wavefront Dynamics®, our commitment to clinical rigor is backed by decades of peer-reviewed research and published studies. This growing body of work spans wavefront aberrometry, objective refraction, and custom lens design for highly aberrated eyes.

Use the drop down arrows below to explore the foundational science behind the WaveDyn platform:

  • Accuracy of objective refraction from a wavefront sensor as glasses prescription (Jack Ma et al.) READ MORE
  • Comparison of Refraction Calculations for the Highly Aberrated Eye (Marcus R. Noyes, Xifeng Xiao, Daniel R. Neal, Christine W. Sindt) READ MORE
  • Investigation of the isoplanatic patch and wavefront aberration along the pupillary axis compared to the line of sight in the eye. READ MORE
  • Normal-eye Zernike coefficients and root-mean-square wavefront errors. READ MORE
  • Schallhorn – Wavefront-Guided Photorefractive Keratectomy with the Use of a New Hartmann-Shack Aberrometer in Patients with Myopia and Compound Myopic Astigmatism. READ MORE
  • Maeda – Clinical applications of wavefront aberrometry – A Review (Clin Experiment Ophthalmol 2009 Jan 37(1) p118-29). READ MORE
  • Ophthalmic Shack-Hartmann wavefront sensor applications. READ MORE
  • Testing highly aberrated large optics with a Shack-Hartmann wavefront sensor. READ MORE
  • Accuracy of WASCA aberrometer refraction compared to manifest refraction in Chinese adult myopes. READ MORE
  • Investigation of the isoplanatic patch and wavefront aberration along the pupillary axis compared to the line of sight in the eye. READ MORE
  • Liu+Thibos – Measurement of the time course of optical quality and visual deterioration during tar break-up IOVS. READ MORE
  • Recent advances in wavefront guided LASIK.4. READ MORE
  • Dynamic aberrometer/topographer designed for clinical measurement and treatment of highly aberrated eyes. (Neal et al.) 
    READ MORE
  • Shack-Hartmann sensor engineered for commercial measurement applications.
    READ MORE
  • Historical Development of the Shack-Hartmann Wavefront Sensor.
    READ MORE
  • Testing highly aberrated large optics with a Shack-Hartmann wavefront sensor.
    READ MORE
  • The JWST Infrared Scanning Shack Hartman System: A new inprocess way to measure large mirrors during optical fabrication at Tinsley.
    READ MORE
  • Application of Shack-Hartmann wavefront sensing technology to transmissive optic metrology.
    READ MORE
  • Evaluation of a clinical aberrometer for lower-order accuracy and repeatability, higher-order repeatability, and instrument myopia. Salmons & van de Pol.
    READ MORE
  • Shack-Hartmann wavefront sensor precision and accuracy.
    READ MORE
  • Effect on Lenslet Resolution on the Accuracy of Ocular Wavefront Measurements.
    READ MORE
  • Neal – Errors in Zernike Transformations and JRS 2005 Sep-Oct.21(5) pS558-62.
    READ MORE
  • Neal – Zonal Matrix Iterative Method for JRS 2005 Sep-Oct.21(5) pS563-S569.
    READ MORE
     

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