Virendra N. Mahajan has written:

'Optical imaging and aberrations' -- subject(s): Aberration, Geometrical optics, Imaging systems

'Aberration theory made simple' -- subject(s): Aberration, Geometrical optics, Imaging systems

'Optical imaging and aberrations' -- subject(s): Aberration, Geometrical optics, Imaging systems

W. T. Welford has written:

'Aberrations of optical systems' -- subject(s): Aberration, Design and construction, Geometrical optics, Optical instruments

'High collection nonimaging optics' -- subject(s): Optical instruments

'Useful optics' -- subject(s): Optical instruments, Optics

'Aberrations of the symmetrical optical system' -- subject(s): Aberration, Design and construction, Geometrical optics, Optical instruments

H. A. Buchdahl has written:

'Concepts of classical thermodynamics'

'Optical aberration coefficients'

The further the aperture is from the optical axis of the lens, the more to the side of the lens the incident light falls. The further the light falls from the optical axis, the greater the effects of chromatic aberration. This is because different wavelengths of light have different refractive indices (dispersion). Because of Snell's Law, n1sintheta1=n2sintheta2, the greater the angle of incidence, the more pronounced the effects of the difference in refractive indices. Spherical aberration further enhances the chromatic dispersion.

optical analysis systems