Plano-Convex Lenses are the best choice for focusing parallel rays of light to a single point, or a single line in the case of cylindrical lenses. This lens can be used to focus, collect and collimate light. It is the most economical choice for demanding applications. The asymmetry of these lenses minimizes spherical aberration in situations where the object and image are located at unequal distance from the lens. The optimum case is where the object is placed at infinity (parallel rays entering lens) and the final image is a focused point. Although infinite conjugate ratio (object distance/image distance) is optimum, plano-convex lenses will still minimize spherical aberration up to approximately 5:1 conjugate ratio. For the best performance, the curved surface should face the largest object distance or the infinite conjugate to reduce spherical aberration.
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Bi-Convex Lenses are the best choice where the object and image are at equal or near equal distance from the lens. When the object and image distance are equal (1:1 magnification), not only is spherical aberration minimized, but also coma, distortion, and chromatic aberration are identically canceled due to the symmetry. Bi-convex lenses function similarly to plano-convex lenses in that they have a positive focal length, and focus parallel rays of light to a point. Both surface are spherical and have the same radius of curvature, thereby minimizing spherical aberration. As a guideline, bi-convex lenses perform within minimum aberration at conjugate ratios between 5:1 and 1:5. Outside this magnification range, plano-convex lenses are usually more suitable.
Plano-Concave Lenses are the best choice where object and image are at absolute conjugate ratios greater than 5:1 and less than 1:5 to reduce spherical aberration, coma, and distortion. Plano-Concave lenses bend parallel input rays so they diverge from one another on the output side of the lens and hence have a negative focal length. The spherical aberration of the Plano-Concave lenses is negative and can be used to balance aberrations created by other lenses. Similar to the Plano-Convex lenses, the curvature surface should face the largest object distance or the infinite conjugate (except when used with high-energy lasers where this should be reversed to eliminate the possibility of a virtual focus) to minimize spherical aberration.
Bi-Concave Lenses are the best choice where object and image are at absolute conjugate ratios closer to 1:1 with converging input beam. The output rays appear to be diverging from a virtual image located on the object side of the lens; the distance from this virtual point to the lens is known as the focal length. Similar to the Plano-Concave lenses, the Bi-concave lenses have negative focal lengths, thereby causing collimated incident light to diverge. Bi-Concave lenses have equal radius of curvature on both side of the lens. They are generally used to expand light or increase focal length in existing systems, such as beam expanders and projection systems.
Positive Meniscus Lenses are designed to minimize spherical aberration and are generally used in small f/number applications (f/number less than 2.5). The Positive Meniscus Lenses have a larger radius of curvature on the convex side, and a smaller radius of curvature on the concave side. They are thicker at the center compared to the edges. Positive meniscus can maintain the same angular resolution of the optical system while decreasing the focal length of the other lens, resulting a tighter focal spot size. A positive meniscus lens can be used to shorten the focal length and increase the numerical aperture of an optical system when paired with another lens. For the best performance, the curved surface should face the largest object distance or the infinite conjugate to reduce spherical aberration.
Spherical Lens Material Options
Lens Type
N-BK7
UV Fused Silica
CaF2
MgF2
ZnSe
Crown/Flint
Plano-Convex
Bi-Convex
Plano-Concave
Bi-Concave
Achromatic Doublet
Cylindrical Lenses
Plano-Convex
Plano-Concave
Coatings
Optical coatings are generally applied as a combination of thin film layers on optical components to achieve desired reflection/transmission ratio. Important factors that affect this ratio include the material property used to fabricate the optics, the wavelength of the incident light, the angle of incidence light, and the polarization dependence. Coating can also be used to enhance performance and extend the lifetime of optical components, and can be deposited in a single layer or multiple layers, depending on the application. Newport’s multilayer coatings are incredibly hard and durable, with high resistance to scratch and stains.
Anti-Reflection Coating (AR coating)
Newport offers an extensive range of antireflection coatings covering the ultraviolet, visible, near infrared, and infrared regions. For most uncoated optics, approximately 4% of incident light is reflected at each surface, resulting significant losses in transmitted light level. Utilizing a thin film anti-reflection coating can improve the overall transmission, as well as minimizing stray light and back reflections throughout the system. The AR coating can also prevent the corresponding losses in image contrast and lens resolution caused by reflected ghost images superimposed on the desired image.
Newport offers three types of AR coating designs to choose from, the Single Layer Magnesium Fluoride AR coating, the Broadband Multilayer AR coating, and Laser Line AR V-coating. A single layer Magnesium Fluoride AR coating is the most common choice that offers extremely broad wavelength range at a reasonable price. It is standard on achromats and optional on our N-BK7 plano-convex spherical lenses and cylindrical lenses. Comparing to the uncoated surface, the MgF2 provides a significant improvement by reducing the reflectance to less than 1.5%. It works extremely well over a wide range of wavelengths (400 nm to 700 nm) at angles of incidence less than 15 degrees.
Broadband Multilayer AR coating improves the transmission efficiency of any lens, prism, beam-splitter, or windows. By reducing surface reflections over a wide range of wavelengths, both transmission and contrast can be improved. Different ranges of Broadband Multilayer AR coating can be selected, offering average reflectance less than 0.5% per surface. Coatings perform efficiently for multiple wavelengths and tunable laser, thereby eliminating the need for several sets of optics.
V-coatings offer the lowest reflectance for maximum transmission. With its high durability and high damage resistance, Laser line AR V-coating can be used at almost any UV-NIR wavelength with average reflectance less than 0.25% at each surface for a single wavelength. Valuable laser energy is efficiently transmitted through complex optical systems rather than loss to surface reflection and scattering. The trade off to its superior performance is the reduction in wavelength range. AR.33 for nm is available from stock on most Newport lenses. All other V-coating can be coated on a semi-custom basis.
Contact us to discuss your requirements of Double Convex Cylindrical Lenses. Our experienced sales team can help you identify the options that best suit your needs.
Coating
Wavelength Range
(nm)
Reflectance
Cost
Features
AR.10
Broadband
245–440
Ravg <0.5%
Moderate
Only available on UV fused silica lenses
MgF2
Broadband
Broadband
400–700
Ravg <1.5%
Low
Available on achromats, KPX series, and Cylindrical lenses
AR.14
430–700
Ravg <0.5%
Moderate
Best choice for broadband visible applications
AR.15
Broadband
250–700
Ravg <1.5%
Moderate
Great choice for broadband UV to visible applications
AR.16
Broadband
650–
Ravg <0.5%
Moderate
Excellent for NIR laser diode applications
AR.18
Broadband
–
Ravg <0.5%
Moderate
Ideal for telecom laser diode applications
V-Coat Multilayer, AR.27
Laser Line
532
Rmax <0.25%
High
Highest transmission at a single wavelength
V-Coat Multilayer, AR.28
Laser Line
632.8
Rmax <0.25%
High
Highest transmission at a single wavelength
AR.33
Laser Line
Rmax <0.25%
Moderate
Highest transmission at a single wavelength
Cylindrical lenses (also called cylindrical or semicylindrical lenses) are lenses with differing radii in their X and Y axes, creating cylindrical or semicylindrical shapes with image magnification in only a single direction. Common uses for laser line generators include setting laser lines at various distances or altering image height sizes or correcting for astigmatism in imaging systems. Lenses designed to focus light into a straight line rather than to one point can either be plano-concave or plano-convex in design; either will expand and focus light respectively. Cylindrical lenses may only focus or expand light along a single axis and may be used to alter laser beam profiles such as correcting for astigmatism and ellipticity or generate lines.
Cylindrical lenses have many uses within optometry, from correcting astigmatism to helping focus light from different angles of your eye at various distances – all to address specific refractive errors associated with astigmatism. Cylindrical lenses also play a crucial role when used alongside eye examination instruments like autorefractors for measuring and correcting refractive errors during eye exams.
To create a laser line generator, cylindrical lenses can help focus the laser beam into a line with controlled length and thickness determined by their radius and laser beam cross sectional size. By selecting an appropriate cylindrical lens you can control its length and thickness as desired by choosing its radius/cross-section size ratio and choosing an appropriate cylindrical lens thickness ratio based on laser module fan angle fan output. You may also utilize various products and DIY solutions available for creating laser line generators including optics modules compact laser modules and DIY solutions which may then be utilized for machine vision/microscopy/alignment tasks among many more tasks!
A popular method for producing circular beams from an elliptical one involves two cylindrical lenses; one magnifying minor axis of laser diode while a second cylindrical lens circles out its path – this method leads to circularized laser beams with greater efficiency than ever. This process can effectively change an elliptical beam into a circular one for various applications. Cylindrical lenses are purposefully created to focus or expand light along a single axis and are frequently employed for beam shaping purposes such as line generators and circularization of laser beams. Cylindrical lenses make an invaluable asset when manipulating light in one direction only and they play an invaluable role in optimizing laser beam characteristics for specific tasks.
Cylindrical lenses are specifically designed to focus light in an even line rather than at one particular point, rather than creating focal spots along their specific axes. Their cylindrical or semi-cylindrical forms contain differing radii in their X and Y axes to cause image magnification along only one particular direction. Cylindrical lenses come with various designs to condense, focus, or expand light depending on their design and the source of illumination they’re directed toward. Light spreaders, commonly made out of either plano-concave or plano-convex lenses designed to expand and focus light sources, come either in diameter or rectangular shapes to facilitate mounting. These lenses are widely utilized as laser line generators, to adjust image height size or correct for astigmatism in imaging systems, or correct for astigmatism in those systems. Their special properties make them well suited to serve a diverse selection of functions including laser beam shaping, imaging systems, spectroscopy manufacturing processes and optometry applications.
Taken into consideration, users can ensure cylindrical lenses are being utilized efficiently for their intended applications, whether that’s lasers systems imaging tasks or any other optical task.
When using cylindrical lenses, several essential considerations come into play – wedge angle, centration and axial tilt are among them.
Considerations such as these are necessary for the specification, production, and integration of cylindrical lenses into optical systems for maximum performance and accuracy.
If you want to buy cylindrical lenses for your applications, please Contact our experts for a consultation.
For more information, please visit Achromatic Cylindrical Lens.
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