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Multi-Order Diffractive (MOD) Lens Technology A conventional diffractive-optic lens utilizes a single diffraction order in which the optical power of the lens is directly proportional to the wavelength of light, see Fig. 1(a). Therefore with white light The key feature of a multi-order diffractive (MOD) lens is that it is designed to bring multiple wavelengths to a common focus with high efficiency, and is thereby is capable of forming sharp, clear images in white (or broadband)
Fig. 1. (a) A conventional diffractive lens is highly dispersive and focuses different wavelengths of light to different focal positions; (b) A MOD lens brings multiple wavelengths across the visible spectrum to a common focal point, and is thereby capable of forming high-quality images in white light. A MOD lens consists of concentric annular Fresnel zones (see Fig. 2). The step height at each zone boundary is designed to produce a phase change of 2Ï€p in the emerging wavefront, where p is an integer greater than one. Since the MOD lens is purely diffractive, the optical power of the lens is determined solely by choice of the zone radii, and is independent of lens thickness. Also, because a MOD lens has no refractive power, it is completely insensitive to changes in curvature of the substrate. Â Fig. 2. Cross section of a multi-order diffractive (MOD) lens. The phase jump at the edge of the various zones is 2Ï€p, where p is an integer. The zone radii, rj, are obtained by solving the equation f(rj) = 2Ï€pj, where f(r) represents the desired phase function for the lens. To illustrate its operation, consider the case of a MOD lens operating in the visible wavelength range with p = 10. Figure 3 illustrates the wavelength dependence of the diffraction efficiency (with material dispersion neglected). Note that several wavelengths within the visible spectrum exhibit 100% diffraction efficiency. As noted above, the principal feature of the MOD lens is that it brings the light associated with each of these high efficiency wavelengths to a common focal point; hence is capable of forming high quality white-light images. For reference, the photopic and scotopic visual sensitivity curves are also plotted in Fig. 3. Note that with the p = 10 design, high diffraction efficiencies occur near the peak of both visual sensitivity curves. Â Fig. 3. Diffraction efficiency versus wavelength for a p = 10 MOD lens. The performance that can be achieved using MOD lens technology is illustrated in Fig. 4.
Fig. 4. Performance comparison between an aspheric refractive lens and a MOD 20 lens. MOD lens technology provides high-quality imaging at a low cost. MOD lenses can be injection molded, replicated onto a glass substrate using a UV-cured optical polymer; or transferred directly into the substrate using reactive-ion etching (RIE) techniques. Let us show you how we can put Apollo’s MOD lens technology to work for you. MOD Lens Applications
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