Principles of Optics
 [0065]
[0131]

Clinical Visual Optics
 [0065]
[0131]

Raytracing trough nonspherical surfaces. Proc Physical Soc (UK)
 [0228]

The optical design of intraocular lens implants
 [0228]

Intraocular lens power calculation
 [0228]

Calculation of the power of an iris clip lens for distant vision
 [0228]

Accuracy and reproducibility of biometry using partial coherence interferometry
 [0228]

Partial coherence interferometry: a novel approach to biometry in cataract surgery
 [0228]

The shape of the anterior and posterior surface of the aging human cornea
 [0228]

Radius and asphericity of the posterior corneal surface determined by corrected Scheimpflug photography
 [0228]

Normal variations of the posterior corneal surface
 [0228]

Influence of operator experience on the performance of ultrasound biometry compared to optical biometry before cataract surgery
 [0228]

Calculation of the optical power of intraocular lenses
 [0228]

Intraocular lens planning. Geometricoptical and SandersRetzlaffKraff I and II formulas
 [0228]

In: Handbuch der physiologischen Optik
 [0228]

In: Helmholtz's Treatise on Physiological Optics
 [0228]

Pseudophakic correction factors for optical biometry
 [0228]

In: Intraocular lens power calculations
 [0228]

Comparison of immersion ultrasound biometry and partial coherence interferometry for intraocular lens calculation according to Haigis
 [0228]

The Hoffer Q formula: a comparison of theoretic and regression formulas
 [0228]
[0228]

Clinical results using the Holladay 2 intraocular lens power formula
 [0228]

A threepart system for refining intraocular lens power calculations
 [0228]

Determination of the velocity of ultrasound in the human lens and vitreous
 [0228]

Refractive outcome of cataract surgery using partial coherence interferometry and ultrasound biometry: clinical feasibility study of a commercial prototype II
 [0228]

On the calculation of power from curvature of the cornea
 [0228]

Prediction of intraocular lens position after cataract extraction
 [0228]

Theoretical approach to intraocular lens calculation using Gaussian optics
 [0228]

Theoretical vs empirical prediction of aphakic refraction
 [0228]

Theoretical, computerassisted prediction versus SRK prediction of postoperative refraction after intraocular lens implantation
 [0228]

On the StilesCrawford effect and ocular imagery
 [0228]

In: Intraocular lens calculations
 [0228]

Prediction of the effective postoperative (intraocular lens) anterior chamber depth
 [0228]

Calculation of intraocular lens power: a review
 [0228]

We don't need fudge factors in IOL power calculation
 [0228]

Intraocular lens power calculation with an improved anterior chamber depth prediction algorithm
 [0228]

Raytracing analysis of intraocular lens power in situ
 [0228]

Phacoemulsification, capsulorhexis, and intraocular lens power prediction accuracy
 [0228]

Prediction of postoperative intraocular lens chamber depth
 [0228]

Prediction of pseudophakic anterior chamber depth with the newer IOL calculation formulas
 [0228]

Theoretical versus SRK I and SRK II calculation of intraocular lens power
 [0228]

Accuracy of the newer generation intraocular lens power calculation formulas in long and short eyes
 [0228]

Calibration of axial length measurements with the Zeiss IOLMaster
 [0228]
[0228]

Immersion Ascan compared with partial coherence interferometry: outcomes analysis
 [0228]

A new intraocular lens calculation formula
 [0228]

Development of the SRK/T intraocular lens implant power calculation formula
 [0228]

Comparison of the accuracy of the Binkhorst, Colenbrander, and SRK implant power prediction formulas
 [0228]

Comparison of the SRK II formula and other second generation formulas
 [0228]

Comparison of the SRK/T formula and other theoretical and regression formulas
 [0228]

The luminous efficiency of rays entering the eye pupil at different points
 [0228]

Reproducibility of optical biometry using partial coherence interferometry : intraobserver and interobserver reliability
 [0228]
