Fact-checked by Grok 2 weeks ago

Catoptrics

Catoptrics is the branch of optics that studies the reflection of light rays from surfaces, particularly mirrors, and the resulting visual appearances and image formation.^[1] The term originates from the Greek katoptron, meaning "mirror," combining kata ("against" or "down") and optos ("seen" or "visible"), reflecting its focus on reflective phenomena.^[2] Distinct from dioptrics, which examines refraction through transparent media, catoptrics emphasizes geometric principles governing how light bounces off opaque surfaces to produce images, often employing the law of reflection where the angle of incidence equals the angle of reflection.^[3]^[4] The foundational text on catoptrics is Euclid's Catoptrics, composed around 300 BCE, which treats reflection geometrically and assumes light travels in straight lines from the eye in a visual cone, enabling theorems on apparent sizes and positions of reflected objects.^[1]^[5] Euclid's work established core propositions, such as the equality of incident and reflected angles, building on earlier intuitive understandings of mirrors in ancient cultures.^[4] Subsequent advancements came from Hero of Alexandria in the 1st century CE, who in his Catoptrics derived the reflection law using a shortest-path principle and explored infinite light speed, while also addressing image localization via the "cathetus rule."^[1]^[4] By the 2nd century CE, Claudius Ptolemy expanded catoptrics in his Optics, empirically verifying reflection laws and analyzing images in plane, convex, and concave mirrors, including detailed ray-tracing for spherical surfaces.^[5]^[4] In the Islamic Golden Age, Ibn al-Haytham (Alhazen, c. 965–1040 CE) revolutionized the field in Books IV and V of his Kitāb al-Manāẓir (Book of Optics), conducting experiments to confirm reflection principles and solving complex problems like Alhazen's problem—involving rays from two points reflecting off a spherical mirror to meet at a specific point.^[4] These developments laid the groundwork for later optical instruments, such as burning mirrors studied by Diocles (late 2nd century BCE), who proved parabolic mirrors focus sunlight to a point.^[5] Catoptrics thus evolved from ancient geometric theory to a cornerstone of optical science, influencing applications in telescopes and modern mirror-based systems.^[1]

Fundamentals of Reflection

Definition and Scope

Catoptrics is the branch of optics that exclusively studies the reflection of light from mirrors and other specular surfaces, focusing on the formation of images through such reflections.^[6] The term derives from the Greek word katoptron, meaning "mirror," which combines kata (against or down) and optos (seen or visible), reflecting its origins in ancient inquiries into mirrored vision.^[2] The scope of catoptrics encompasses specular reflection, where light rays from smooth surfaces like polished metals or glass mirrors bounce off at predictable angles, enabling clear image formation, in contrast to diffuse reflection from rough surfaces, which scatters light in multiple directions without forming distinct images.^[7] It deliberately excludes phenomena involving refraction, as studied in dioptrics, and wave-based effects like diffraction, concentrating instead on geometric principles of ray tracing.^[8] Within broader optics, catoptrics forms one foundational pillar alongside these other branches, providing essential tools for understanding reflective optical systems. Originating in ancient Greek scholarship, catoptrics laid early groundwork for systematic optical analysis, with detailed historical developments explored elsewhere.^[8] Central to its study are key concepts such as the incident ray (the incoming light path), the reflected ray (the outgoing light path), the normal line (a perpendicular at the point of reflection), the angle of incidence (between the incident ray and normal), and the angle of reflection (between the reflected ray and normal).^[9] These elements underpin all catoptric investigations, emphasizing the precise geometry of light paths on reflective interfaces.

Basic Properties of Reflected Light

Upon reflection, light wavefronts behave according to Huygens' principle, which posits that every point on an incident wavefront acts as a source of secondary spherical wavelets propagating forward at the speed of light, with the reflected wavefront forming as the envelope tangent to these wavelets. For a plane wave incident on a flat mirror, this results in a reflected plane wave that maintains parallelism, enabling the formation of virtual images behind the mirror surface. In catoptric systems, such wavefront propagation explains how coherent light sources produce focused real images in converging setups, though the principle applies universally to reflection phenomena.^[10]^[11] Reflection alters the polarization state of light, particularly for unpolarized incident beams interacting with dielectric or metallic surfaces. At Brewster's angle—the incidence angle where the reflected ray is perpendicular to the refracted ray—the reflected light becomes fully polarized parallel to the reflecting surface (s-polarization), while the transmitted component retains partial polarization. This effect arises from the differential reflection coefficients for parallel (p-) and perpendicular (s-) polarizations, with metals exhibiting stronger polarization changes due to their conductive properties compared to dielectrics. Such polarization shifts are observable in everyday scenarios, like glare reduction on water surfaces, and underpin catoptric polarizers.^[12]^[13] The intensity of reflected light adheres to energy conservation, where the sum of reflected and transmitted intensities equals the incident intensity for non-absorbing interfaces, as described qualitatively by Fresnel coefficients. These coefficients predict partial reflection at most angles, with higher reflectivity for perpendicular polarization and near-total reflection at grazing incidence, but total internal reflection occurs only in refraction contexts. In catoptrics, metallic mirrors approach total reflection with minimal energy loss, preserving photon flux while directing it specularly.^[14]^[15] Reflected light exhibits either specular or diffuse characteristics depending on surface microstructure. Specular reflection occurs on smooth, polished surfaces like mirrors or calm water, where incident rays reflect coherently at equal angles, preserving image sharpness and directionality. In contrast, diffuse reflection scatters light in multiple directions from rough surfaces such as paper or matte paint, due to microscopic facets redirecting rays randomly, which diffuses brightness without forming distinct images. This distinction is evident in applications: specular reflection enables clear catoptric imaging, while diffuse reflection contributes to uniform illumination in non-imaging optics.^[7]^[16] The speed of light remains invariant upon reflection, continuing at c = 3 \times 10^8 m/s in vacuum or the medium's phase velocity post-reflection, as the process involves no medium change or absorption. This constancy ensures that reflected wavefronts propagate without temporal distortion, a fundamental property exploited in catoptric timing and interferometry.^[17]^[18]

Mathematical Principles

Laws of Reflection

The laws of reflection form the cornerstone of catoptrics, governing the behavior of light rays at a reflecting surface in geometric optics. These laws, first systematically articulated by Euclid around 300 BCE, ensure predictable ray paths essential for image formation and optical design.^[1] The first law of reflection states that the incident ray, the reflected ray, and the normal to the reflecting surface at the point of incidence all lie within the same plane. This coplanarity arises from the boundary conditions in electromagnetic theory, where the tangential components of the electric and magnetic fields must be continuous across the interface, implying that any out-of-plane component would violate these conditions. To demonstrate this mathematically using vector notation, let \vec{i} be the unit incident ray direction vector pointing toward the surface, \vec{r} the unit reflected ray direction vector pointing away, and \vec{n} the unit normal vector to the surface (outward). The reflected direction satisfies the vector equation

\vec{r} = \vec{i} - 2 (\vec{i} \cdot \vec{n}) \vec{n},

which is derived by decomposing \vec{i} into components parallel and perpendicular to \vec{n}, reversing the perpendicular component upon reflection, and recombining. Since \vec{r} is expressed as a linear combination of \vec{i} and \vec{n}, it lies in the plane spanned by these two vectors, confirming the first law.^[19]^[20] The second law of reflection states that the angle of incidence \theta_i, measured between the incident ray and the normal, equals the angle of reflection \theta_r, measured between the reflected ray and the normal: \theta_i = \theta_r. This equality can be derived using Fermat's principle, which posits that light follows the path of least time between two points. For reflection in a homogeneous medium where the speed of light c is constant, minimizing time is equivalent to minimizing the optical path length. Consider points A and B on the same side of a plane mirror; the light path A to incidence point P on the mirror to B has length L = AP + PB. To find the minimizing P, construct the mirror image B' of B across the mirror plane; the straight-line path from A to B' intersects the mirror at the optimal P, with length AP + PB = AB' (constant for the minimum). By geometry, the triangle APP' (where P' is the projection) and the isosceles properties yield \angle API = \angle RP I, where I is the intersection with the normal, proving \theta_i = \theta_r.^[21]^[22] In a typical diagram, the incident ray approaches the surface, striking at point O where the normal is drawn perpendicular to the surface; \theta_i is the angle between the incident ray and the normal, while \theta_r is the corresponding angle for the reflected ray emanating from O, with both rays and the normal coplanar and \theta_i = \theta_r.^[23] The law of reflection bears a close analogy to Snell's law of refraction, n_1 \sin \theta_i = n_2 \sin \theta_r, derived similarly from Fermat's principle but accounting for varying speeds in different media (optical path length L = \sum n \, ds). For reflection at an air-mirror interface, the effective refractive indices are equal (n_1 = n_2 = 1), simplifying Snell's law to \sin \theta_i = \sin \theta_r, or \theta_i = \theta_r since angles are between 0° and 90°—a special case highlighting reflection's simpler form without medium change.^[20]^[24] Experimental verification of these laws, with a mathematical focus, traces to Euclid's Catoptrics, where he employed geometric constructions to confirm coplanarity and equal angles. In one setup, visual rays from an object are traced to a mirror, and the equality is shown by inscribing equal arcs on circles centered at the incidence point, demonstrating that deviations from \theta_i = \theta_r lengthen the path, aligning with least-time minimization—though empirical, the proof emphasizes axiomatic geometry over direct measurement.^[1]

Geometry of Image Formation

In geometric optics, the formation of images through reflection relies on tracing rays from an object to determine where they converge or appear to diverge after interacting with a mirror surface. Real images occur when reflected rays actually converge at a point in front of the mirror, allowing the image to be projected onto a screen, as seen in concave mirrors when the object is positioned beyond the focal point.^[25] Virtual images, by contrast, form when reflected rays diverge and appear to emanate from a point behind the mirror upon backward extension, preventing projection onto a screen; this is characteristic of plane mirrors and convex mirrors, as well as concave mirrors for objects inside the focal length.^[26]^[25] Ray diagrams illustrate these concepts by constructing principal rays that follow the law of reflection. For a plane mirror, a ray from the object incident normally on the mirror reflects back along the same path, while another ray strikes at an angle and reflects such that the angle of incidence equals the angle of reflection; their backward extensions intersect behind the mirror at the virtual image, equidistant from the mirror as the object.^[26] In introductory curved mirror cases, such as a concave spherical mirror, additional rays include one passing through the center of curvature (reflecting back along itself) and one parallel to the axis (reflecting through the focal point); for objects outside the focal point, these converge to form a real, inverted image, whereas inside, they diverge to yield an upright virtual image.^[25] For spherical mirrors, the mirror equation quantitatively predicts image location under the paraxial approximation, relating object distance u, image distance v, and focal length f:

\frac{1}{f} = \frac{1}{u} + \frac{1}{v}

This equation derives from the geometry of similar triangles formed by paraxial rays in a concave mirror. Consider an object at distance u from the vertex, with the image at v; a ray parallel to the principal axis reflects through the focal point f, while another through the center of curvature $2f reflects back along itself. The small-angle triangles sharing the angle at the vertex—one with height proportional to the object and base u - f, the other with image height and base v - f—yield \frac{h_o}{u - f} = \frac{h_i}{v - f}. A second set of similar triangles from the parallel ray gives \frac{h_o}{f} = \frac{h_i}{v}. Solving these proportions eliminates heights and leads to the mirror equation, with f = R/2 where R is the radius of curvature.^[27] Sign conventions assign negative values to u (object side), positive v for real images, and negative f for convex mirrors.^[25] Magnification quantifies image size and orientation. The lateral magnification is m = -\frac{v}{u} = \frac{h_i}{h_o}, where h_i and h_o are image and object heights; the negative sign indicates inversion for real images (m < 0), while positive m denotes upright virtual images. Longitudinal magnification, relevant for extended objects along the axis, is m_L = \left( \frac{v}{u} \right)^2, but it is typically smaller in magnitude for distant objects.^[25] The paraxial approximation underpins these relations, assuming rays make small angles with the optical axis and lie close to it, such that the mirror's curvature is treated as locally parabolic to neglect higher-order effects. This simplifies calculations but limits accuracy for wide fields or large apertures, where deviations introduce errors on the order of the angle cubed.^[27]^[28] One such limitation is spherical aberration, arising from non-paraxial rays parallel to the axis but striking the mirror far from the vertex; these focus at points closer to the mirror than the paraxial focal point, blurring the image edge.^[25]^[28]

Types of Mirrors

Plane Mirrors

Plane mirrors are flat, polished surfaces that reflect light according to the laws of reflection, producing virtual images without converging or diverging the rays. The image formed by a plane mirror is virtual, meaning the reflected rays appear to diverge from a point behind the mirror rather than converging to a real point in front of it. This virtual image is erect, maintaining the same upright orientation as the object, and is the same size as the object, with no magnification or minification. Additionally, the image is laterally inverted, such that the left side of the object appears as the right side in the image, and vice versa. The apparent distance of the image behind the mirror equals the actual distance of the object in front of it, resulting in a one-to-one correspondence in positioning relative to the reflecting surface.^[29]^[30]^[31]^[29] Multiple reflections occur when light encounters more than one plane mirror, leading to a series of virtual images. In the case of two parallel plane mirrors, an object placed between them produces an infinite number of images, each successive one appearing farther away and created by reflections bouncing back and forth indefinitely. This effect arises because each mirror reflects the image from the other, extending the apparent depth without limit. The kaleidoscope operates on a similar principle but uses two or three plane mirrors arranged at an angle, such as 60 degrees, to generate a finite set of symmetrical images that form intricate, repeating patterns from a single object or light source.^[32]^[33] Plane mirrors find practical applications in everyday devices due to their simplicity and ability to redirect views without altering image size. In vehicles, planar rearview mirrors provide drivers with a direct, undistorted view of the area behind the car, essential for safe maneuvering and compliance with safety standards. Periscopes, often constructed using two plane mirrors at 45-degree angles, enable viewing over obstacles or around corners by reflecting light paths to the observer's eye, a simple catoptric system used in submarines and trench warfare. These applications leverage the mirror's capacity to deviate rays by 180 degrees while preserving image parity in basic configurations.^[34]^[35] Despite their utility, plane mirrors have inherent limitations that restrict their use in certain optical systems. They provide no magnification or focusing power, as the reflected rays remain parallel to the incident rays, preventing the formation of real images or convergence at a focal point. When viewed at non-perpendicular angles, or obliquely, the image can suffer from perspective distortion, appearing foreshortened or compressed in the direction away from the observer, though this is a geometric effect rather than an aberration of the mirror itself. In manufacturing, achieving optical quality requires stringent flatness tolerances, typically on the order of a fraction of a wavelength of light (e.g., λ/10 or better for visible light), to minimize wavefront distortions and ensure high-fidelity reflection; deviations from flatness introduce scatter and degrade image clarity.^[29]^[36]

Curved Mirrors

Curved mirrors, unlike plane mirrors which produce virtual images at equal distance behind the surface, bend incoming rays to converge or diverge them, enabling image formation with magnification or minification depending on the object's position relative to the focal point.^[37] They are classified primarily as concave or convex based on the reflecting surface's curvature.^[37] Concave mirrors, which reflect from the inner curved surface, focus parallel incident rays to a real focal point ahead of the mirror.^[37] The focal length f is half the radius of curvature R, given by the relation f = \frac{R}{2}, under the paraxial approximation for small angles.^[37] For distant objects, where rays are effectively parallel, these mirrors form real, inverted images at the focal plane.^[37] When the object is placed inside the focal point, such as in shaving mirrors, a virtual, upright, and magnified image forms behind the mirror, allowing close inspection of facial features.^[27] Convex mirrors reflect from the outer curved surface and cause parallel rays to diverge, appearing to originate from a virtual focal point behind the mirror.^[37] They always produce virtual, upright, and diminished images regardless of object position.^[37] This divergence provides a wider field of view compared to plane or concave mirrors, making convex mirrors suitable for applications like security mirrors in stores, where a broad surveillance area is monitored from a single point.^[38] Parabolic mirrors offer an ideal alternative to spherical ones for focusing parallel rays, as their shape ensures all rays converge precisely to a single focal point without deviation.^[39] The surface follows the equation y^2 = 4fx, where f is the focal length and the focus lies at (f, 0) in Cartesian coordinates with the vertex at the origin.^[40] This geometry inherently avoids spherical aberration for on-axis parallel incident light, unlike spherical mirrors where peripheral rays focus differently.^[39] Despite their advantages, curved mirrors suffer from optical aberrations that degrade image quality beyond the paraxial approximation. Spherical aberration arises when rays at varying heights from the optical axis focus at different points along it, causing a blurred image spot; it can be corrected by using parabolic or aspheric surfaces instead of spherical ones.^[41] Coma, an off-axis aberration, produces comet-shaped images for point sources not on the axis due to asymmetric focusing of ray bundles; correction often involves positioning an aperture stop to limit off-axis rays.^[42] Astigmatism occurs in off-axis imaging, where the mirror focuses rays in the sagittal and meridional planes to different lines, resulting in elliptical blur; it is mitigated by adjusting the stop location or using multi-element systems.^[43] To analyze image formation consistently, the Cartesian sign convention is applied: distances are measured from the mirror's pole along the optical axis, with the positive direction defined as that of the incident light (typically from object to mirror). Object distances are positive for real objects ahead of the mirror, image distances are positive for real images (formed by converging rays ahead of the mirror for concave cases), and the focal length is positive for concave mirrors and negative for convex ones.^[37]

Historical Development

Ancient and Classical Contributions

The study of catoptrics in ancient and classical antiquity was deeply intertwined with philosophical inquiries into the nature of vision and light, particularly among the atomists. Democritus (c. 460–370 BCE), a pre-Socratic philosopher, conceptualized reflection as the rebound of atomic images or effluences emanating from objects, which interact with the observer's eye to produce visual perceptions, assimilating the process to a mechanical bounce without invoking divine or immaterial causes.^[44] This atomistic view framed reflection as a corpuscular phenomenon, where indivisible particles maintain their paths until colliding with surfaces, influencing later geometrical treatments by emphasizing the physicality of light rays.^[45] Euclid (c. 300 BCE) advanced catoptrics through his treatise Catoptrics, adopting an axiomatic, geometrical approach to the laws of reflection, postulating that light propagates in straight lines from the eye to objects in homogeneous media.^[1] He correctly formulated the law of reflection, stating that the incident ray, reflected ray, and normal to the surface lie in the same plane, with the angle of incidence equaling the angle of reflection, and applied this to plane and spherical mirrors to explain image formation.^[1] Diocles (late 3rd–2nd century BCE) contributed significantly to the practical aspects of catoptrics in his work On Burning Mirrors, where he provided the first known mathematical proof that a parabolic mirror focuses parallel rays, such as sunlight, to a single point. This established the principles for optical concentration devices capable of igniting objects at a distance.^[5] In the 1st century CE, Hero of Alexandria expanded practical applications in his Catoptrics, deriving the reflection law geometrically using the principle of the shortest path, arguing that light follows the minimal trajectory between points, and described polyhedral mirrors for creating multiple images or visual illusions, bridging theory with engineering.^[1] Hero's work emphasized infinite light speed and rectilinear propagation, influencing stagecraft and optical devices in antiquity.^[5] Ptolemy (c. 100–170 CE) integrated experimental methods in Book I of his Optics, conducting observations on reflection angles from plane, convex, and concave mirrors to verify and refine the equal-angles law, while extending analyses to image distortion and location.^[46] His approach combined Euclidean geometry with empirical data, such as measuring ray deviations in spherical mirrors, though he maintained the extramission theory of vision where rays emanate from the eye.^[47] Ptolemy's contributions marked a shift toward quantitative optics, influencing subsequent Hellenistic and Islamic scholars.^[46] These ancient and classical works remained strictly geometrical, treating light as discrete rays without incorporating wave-like propagation or interference, limiting explanations to macroscopic phenomena like image formation and focusing.^[1]

Medieval and Renaissance Advances

In the 11th century, the Persian polymath Ibn al-Haytham, known as Alhazen in the Latin West, made foundational advances in catoptrics through his seminal work Kitab al-Manazir (Book of Optics), composed between 1011 and 1021 CE. This comprehensive treatise, spanning seven volumes, systematically explored the properties of reflected light, including experiments on plane and curved mirrors to demonstrate how images form through reflection.^[48] Alhazen debunked the ancient emission theory of vision, which posited that light emanates from the eye, by arguing instead for an intromission model where light rays reflect off objects and enter the eye, supported by empirical observations of mirror images.^[49] He further utilized the camera obscura—a darkened chamber with a small pinhole—to demonstrate the rectilinear propagation of light rays and to support his intromission theory, observing phenomena such as the inverted image of solar eclipses.^[50] Building on Alhazen's framework in the 13th century, the Polish scholar Witelo authored Opticae Thesaurus (also known as Perspectiva), around 1270 CE, which became a cornerstone of European optics for centuries. Witelo expanded Alhazen's reflection experiments by detailing the behavior of light on various mirror surfaces, including spherical and parabolic types, and emphasized quantitative analysis of angles of incidence and reflection to predict image locations.^[4] His work integrated Aristotelian and Neoplatonic ideas with empirical testing, treating catoptrics as a branch of perspectiva that explained visual perception through ray tracing, and it included discussions of atmospheric reflections as natural catoptric phenomena.^[51] During the Renaissance, Witelo's Opticae Thesaurus profoundly influenced figures like Johannes Kepler, whose 1604 Ad Vitellionem Paralipomena supplemented and critiqued Witelo's catoptric theories, refining models of image formation in mirrors and laying groundwork for later optical instruments.^[52] René Descartes, in his 1637 La Dioptrique, devoted sections to catoptrics, deriving the law of reflection mechanically by analogizing light rays to bouncing balls, while focusing on how curved mirrors alter ray paths to form focused images, though he prioritized refraction in anaclastic lenses.^[53] Medieval and Renaissance scholars also revisited the ancient legend of Archimedes' burning mirrors, with Islamic opticians like Ibn al-Haytham analyzing parabolic mirrors for concentrating solar rays to ignite objects, inspiring experimental tests in Europe to verify focal heating effects.^[54] These developments bridged theoretical geometry and practical experimentation, fostering pre-Galilean ideas for catoptric devices that magnified distant objects via concave mirrors, as hinted in works by Giambattista della Porta, who explored mirror combinations for enhanced vision in his 1558 Magia Naturalis, paving the way for reflecting telescopes.^[55]

Catoptric Instruments

Reflecting Telescopes

Reflecting telescopes utilize curved mirrors to collect and focus light, forming images without the need for lenses, a principle rooted in catoptric optics.^[56] These instruments emerged as a solution to the limitations of early refracting telescopes, particularly chromatic aberration, where different wavelengths of light focus at varying points due to refraction.^[56] By reflecting light off mirrors, catoptric designs achieve sharper images across a broad spectrum and enable larger apertures, facilitating observations of faint celestial objects.^[57] The Newtonian telescope, invented by Isaac Newton in 1668 and first presented to the Royal Society in 1671, represents the foundational catoptric design.^[58] It features a primary concave parabolic mirror at the base of the tube that collects incoming parallel rays and reflects them toward a flat secondary mirror positioned at a 45-degree angle near the open end.^[59] This diagonal secondary folds the light path sideways, directing it to an eyepiece for viewing, which shortens the overall instrument length compared to equivalent refractors.^[59] Newton's innovation addressed the color fringing in refractors by eliminating glass elements, using speculum metal—a tin-copper alloy—for the mirrors to achieve high reflectivity.^[58] Building on this, the Cassegrain design, proposed by French priest Laurent Cassegrain in 1672, introduces a more compact configuration.^[60] It employs a primary concave parabolic mirror and a convex secondary hyperbolic mirror placed near the tube's top, which reflects light back through a central hole in the primary to the eyepiece at the rear.^[61] This folded path results in a shorter tube length relative to the Newtonian, making it suitable for mounting on alt-azimuth or equatorial platforms.^[61] A key variant, the Ritchey-Chrétien telescope, developed in 1910 by astronomers George Willis Ritchey and Henri Chrétien, modifies the Cassegrain by using hyperbolic surfaces for both mirrors to correct spherical aberration and coma, enhancing off-axis performance for wide-field imaging.^[62] This design has become standard for professional observatories due to its improved image quality over classical Cassegrains.^[63] Reflecting telescopes offer significant optical advantages over refractors, primarily the absence of chromatic aberration since mirrors reflect all wavelengths equally, producing achromatic images.^[56] Additionally, mirrors can be cast and polished to much larger diameters—often exceeding 8 meters—without the sagging issues of massive lenses, allowing greater light-gathering power for deep-space observations.^[57] However, these instruments face limitations, including coma distortion in off-axis fields where stars appear comet-like due to the parabolic primary's shape, which is particularly pronounced in Newtonian designs.^[64] Alignment of the secondary mirror is also challenging, requiring precise adjustments to maintain focus, as even minor misalignments can degrade image quality across the field.^[65] The historical impact of these designs is exemplified by modern implementations, such as the Hubble Space Telescope, a Ritchey-Chrétien reflector launched in 1990.^[66] Despite its groundbreaking capabilities, Hubble's primary mirror suffered from a spherical aberration flaw—a 2-micrometer error in the polish—resulting in blurry images until corrected by the 1993 servicing mission, which installed corrective optics.^[66] A more recent example is the James Webb Space Telescope (JWST), launched on December 25, 2021, featuring a 6.5-meter primary mirror composed of 18 hexagonal beryllium segments coated in gold, employing a three-mirror anastigmat design derived from catoptric principles to achieve unprecedented infrared observations.^[67] This incident underscored the precision required in catoptric manufacturing and alignment for space-based applications.^[68]

Other Optical Devices

Reflecting microscopes employ catoptric designs, utilizing only mirrors to form images and thereby circumventing the absorption issues inherent in glass lenses for ultraviolet (UV) and infrared (IR) wavelengths.^[69] Cassegrain-style configurations, featuring a primary concave mirror and a secondary convex mirror, are particularly suited for these spectral regions, as they maintain low optical absorption from deep UV (~190 nm) through mid-wave IR while achieving high numerical apertures for detailed imaging.^[70] Historically, advancements in such systems trace back to the late 19th century, with the Mangin mirror—invented in 1876 by Alphonse Mangin—serving as a meniscus reflector that corrects spherical aberration when integrated into reflecting microscope objectives.^[71]^[72] Periscopes rely on multiple plane mirrors, typically two arranged at 45-degree angles, to redirect light rays and enable viewing around obstacles without altering image size or orientation.^[73] This catoptric arrangement produces virtual images through successive reflections, maintaining the object's apparent distance while inverting the image twice for upright viewing. Endoscopes, particularly rigid variants, incorporate similar multiple-mirror systems, such as sliding mirror sleeves that adjust the line of sight from 0° to angles like 70°, 90°, or 110°, facilitating inspection in confined or angled spaces like body cavities.^[74] Headlight reflectors in vehicles predominantly use parabolic shapes to collimate light from a source into a parallel beam, ensuring efficient illumination over long distances with minimal divergence.^[75] This catoptric geometry focuses divergent rays from bulbs or LEDs onto a focal point, then reflects them forward as a directed beam, enhancing road visibility while reducing glare through precise curvature control.^[76] Solar concentrators leverage catoptric elements to harness sunlight efficiently. Heliostats consist of flat mirrors mounted on tracking mechanisms that orient toward the sun, reflecting rays to a central receiver in tower systems for thermal energy generation.^[77] Dish systems, by contrast, employ curved parabolic or catoptric subsets of mirrors to concentrate solar flux onto a focal receiver, achieving high temperatures for applications like power production, with subsets of flat mirrors enabling modular, high-efficiency designs.^[78] Laser cavities, or optical resonators, utilize high-reflectivity mirrors to confine and amplify light through repeated reflections, forming standing waves essential for lasing action.^[79] These end mirrors, often coated with dielectric multilayers achieving reflectivities exceeding 99.999%, minimize losses and support high-power operation across wavelengths, with one mirror typically partially transmitting to output the beam.^[80]

Applications and Modern Uses

Scientific and Astronomical Applications

In astronomical observatories, catoptric systems form the backbone of large-scale reflecting telescopes, enabling high-resolution imaging and spectroscopy of distant celestial objects. The W. M. Keck Observatory features two 10-meter primary mirrors, each composed of 36 hexagonal segments made from low-expansion glass-ceramic, which collectively provide an effective aperture for gathering faint light from deep space.^[81] These segmented designs overcome manufacturing limitations of monolithic mirrors while maintaining structural rigidity. Adaptive optics systems at Keck employ deformable mirrors to dynamically correct for atmospheric distortions, reducing wavefront aberrations and achieving near-diffraction-limited performance across near-infrared wavelengths.^[82] For instance, the Keck II telescope's adaptive optics upgrades, including high-order deformable mirrors with up to 2,900 actuators, minimize fitting errors from atmospheric turbulence, enhancing image sharpness for exoplanet studies and galaxy observations.^[83] Space-based catoptric instruments extend these capabilities beyond Earth's atmosphere, avoiding distortions from air turbulence. The James Webb Space Telescope (JWST) utilizes a primary mirror array of 18 hexagonal beryllium segments, coated with gold for optimal infrared reflectivity, and designed to operate at cryogenic temperatures around 40 K to minimize thermal emissions that could interfere with faint cosmic signals.^[84] This segmented, foldable design allows for a 6.5-meter effective aperture, far larger than Hubble's 2.4-meter mirror, while the cryogenic cooling—achieved through a multi-layer sunshield—enables detection of light from the universe's earliest epochs.^[85] In contrast to Hubble's initial spherical aberration, which required post-launch corrective optics, JWST's mirrors were precision-aligned on the ground and fine-tuned in orbit using actuators, ensuring sub-wavelength accuracy for infrared astronomy.^[86] In astronomical spectroscopy, catoptric pre-optics enhance the performance of echelle gratings by delivering collimated, aberration-free beams to these high-dispersion elements. Echelle gratings, which operate in high orders for broad wavelength coverage and resolving powers exceeding 100,000, often pair with all-reflective telescopes to avoid chromatic dispersion in refractive systems, as seen in instruments like the High Resolution Echelle Spectrometer (HIRES) on Keck.^[87] These catoptric feeds focus stellar light onto the grating, enabling precise radial velocity measurements for exoplanet detection and chemical abundance analysis in distant stars.^[88] Beyond astronomy, catoptric systems play a critical role in particle physics detectors for efficient light collection from particle interactions. Ring Imaging Cherenkov (RICH) detectors, such as those in the NA62 experiment at CERN, employ arrays of spherical mirrors to focus Cherenkov radiation—emitted by charged particles traversing a radiator medium—onto photon-sensitive detectors like hybrid photodiodes.^[89] These mirrors, often lightweight composites to reduce material interactions, achieve high reflectivity in the UV-visible range, improving particle identification by reconstructing Cherenkov ring patterns with minimal light loss.^[90] Similar mirror configurations in calorimeters collect scintillation light from energy deposits, aiding momentum reconstruction in high-energy collisions.^[91] In metrology, catoptric interferometry provides the gold standard for realizing and disseminating length units with traceability to fundamental constants. The NIST Length Scale Interferometer uses a stabilized helium-neon laser and high-precision mirrors to measure gauge blocks via fringe counting, achieving uncertainties below 1 nm over scales up to 1 meter, directly linking to the meter definition via the speed of light.^[92] Michelson and Fabry-Pérot interferometers, relying on partially reflecting mirrors to create stable interference patterns, enable absolute length calibrations in national metrology labs, supporting applications from semiconductor fabrication to gravitational wave detection.^[93] These systems compensate for environmental factors like temperature and pressure, ensuring reproducibility at parts-per-billion levels.^[94]

Everyday and Industrial Applications

In automotive applications, convex mirrors are widely employed in passenger-side exterior rearview mirrors to expand the field of view and reduce blind spots, diverging incoming light rays to provide a broader but minified image of surrounding traffic.^[95] This design complies with Federal Motor Vehicle Safety Standard No. 111, which mandates a specific radius of curvature between 889 mm and 1651 mm for such mirrors and requires the etched warning "Objects in Mirror Are Closer Than They Appear" to alert drivers to the distortion in perceived distance.^[96] Interior rearview mirrors often incorporate automatic anti-dazzle technology, where an electrochromic layer darkens the reflective surface in response to intense rear light, substantially reducing glare from headlights while maintaining visibility; this system uses photosensors to detect light levels and apply voltage to alter the mirror's reflectivity from around 80% to as low as 10%.^[97] Architectural designs leverage catoptric effects for artistic and immersive experiences, such as anamorphic installations that distort reflections to create illusions viewable from specific angles. For instance, Felice Varini's site-specific works superimpose geometric shapes on building facades, appearing coherent only when observed from a designated viewpoint, transforming urban architecture into interactive optical art.^[98] Similarly, Dan Graham's pavilions, like the 1999 Bisbentunnel/Hedge Two Elbe, employ curved two-way mirrors to blend interior and exterior spaces, reflecting viewers and surroundings in distorted, anamorphic patterns that challenge spatial perception.^[99] Yayoi Kusama's Infinity Mirror Rooms extend this into immersive environments, using mirrored walls and ceilings to multiply objects like lanterns or sculptures into infinite arrays, evoking boundless space within enclosed architectural volumes; these installations, such as Infinity Mirrored Room – Filled with the Brilliance of Life (2011), have been adapted for museum architectures worldwide to enhance visitor engagement.^[100] In solar energy systems, parabolic trough collectors utilize curved mirrors to concentrate sunlight onto receiver tubes, achieving concentration ratios of 30 to 100 times normal intensity to heat a heat-transfer fluid for steam generation in thermal power plants.^[101] The Solana Generating Station in Arizona, operational since 2013, exemplifies this with 2.1 million square meters of mirrors tracking the sun to produce 280 MW, storing excess heat in molten salt for up to six hours of dispatchable power after sunset.^[102] While power tower systems like Ivanpah (2014) employ flat heliostat mirrors for similar focusing, trough designs dominate for their scalability in utility-scale concentrated solar power, contributing over 1,700 MW in the U.S. as of 2021.^[103] Manufacturing processes rely on catoptric elements for precision tasks, particularly in laser cutting where dielectric or metal-coated mirrors direct and focus CO2 laser beams along optical paths. Gold-plated copper mirrors, valued for their high reflectivity (over 99% at 10.6 μm) and thermal conductivity, steer the beam in systems like those used for cutting metals or polymers, enabling tolerances down to 0.1 mm.^[104] In quality control, optical reflection testing assesses surface integrity through specular or diffuse reflectance measurements; automated systems, such as those using machine vision to detect defects on reflective parts like die-cast aluminum, achieve sub-micron resolution by analyzing light bounce-back anomalies.^[105] Medical devices incorporate catoptric components for minimally invasive procedures, as seen in rigid endoscopes and laparoscopes where angled-view models (e.g., 30° or 45°) use internal prisms or mirrors to redirect light and images around anatomical curves.^[106] In fiber-coupled laparoscopes, a reflector at the distal end bounces illumination from optical fibers onto tissues while relaying reflected views through rod lenses, enabling high-resolution imaging in procedures like cholecystectomy.^[107] These mirrors, often coated for minimal loss, support illumination levels up to 50,000 lux, crucial for identifying subtle pathologies without direct incision.^[108] Emerging research on metamaterials advances catoptrics toward engineered optical properties, where subwavelength structures enable phenomena like unidirectional reflectionlessness in PT-symmetric configurations by balancing gain and loss.^[109] These structures, often layered dielectrics or plasmonic arrays, promise applications in compact beam steering and cloaking across microwave to optical regimes.

References

[1]
History of Geometric Optics
The earliest surviving optical treatise, Euclid's Catoptrics 1 (280BC), recognized that light travels in straight-lines in homogeneous media.
[2]
Catoptric - Etymology, Origin & Meaning
Origin and history of catoptric "pertaining to mirrors or a mirror," 1774, from Latinized form of Greek katoptrikos, from katoptron "mirror," from kata " ...Missing: definition | Show results with:definition
[3]
Projecting Spirits: Preface | Stanford University Press
Catoptrics focused on the production of appearances by reflective surfaces such as mirrors, while dioptrics studied refractions of light on transparent bodies ...Missing: definition | Show results with:definition<|control11|><|separator|>
[4]
Optics to the Time of Kepler - Encyclopedia of the History of Science
The most obvious example of the extramissionist alternative is the visual ray theory at the heart of Euclid's Optics and Catoptrics (c. 300 BCE), Hero of ...
[5]
History of Optics - UF Physics
reflection and refraction (the field called catoptrics). The most extensive survey of optical phenomena is a. treatise attributed to the astronomer Ptolemy (2nd.
[6]
catoptrics | Photonics Dictionary
Catoptrics is the field of optics concerned with the reflection of light from reflective surfaces such as mirrors. It encompasses the study and analysis of how ...Missing: definition | Show results with:definition
[7]
Specular vs. Diffuse Reflection - The Physics Classroom
Specular reflection occurs on smooth surfaces, like mirrors, while diffuse reflection occurs on rough surfaces, like clothing or paper.
[8]
The History of the Catoptric Optical System - AZoOptics
Aug 6, 2014 · Catoptrics were first introduced by the ancient Greeks, with two of their main texts mentioning catoptrics. The first telescope which was built ...Missing: etymology | Show results with:etymology<|control11|><|separator|>
[9]
The Law of Reflection - The Physics Classroom
The angle between the incident ray and the normal is known as the angle of incidence. The angle between the reflected ray and the normal is known as the angle ...
[10]
1.7: Huygens's Principle - Physics LibreTexts
Mar 16, 2025 · Huygens's principle states that every point on a wave front is a source of wavelets that spread out in the forward direction at the same speed as the wave ...Learning Objectives · Reflection · Refraction · Solution
[11]
Huygens' principle - Richard Fitzpatrick
Every point on a wave-front may be considered a source of secondary spherical wavelets which spread out in the forward direction at the speed of light. The new ...
[12]
Polarization by Reflection - HyperPhysics Concepts
The angle at which this occurs is called the polarizing angle or the Brewster angle. At other angles the reflected light is partially polarized. From Fresnel's ...
[13]
Brewster's Angle - Evident Scientific
This tutorial demonstrates the polarization effect on light reflected at a specific angle (the Brewster angle) from a transparent medium.
[14]
Fresnel Equations - The University of Arizona
Developed in the years 1821-1823, the Fresnel equations[1] describe the amplitude of transmitted and reflected light at the boundary between two materials.
[15]
Fresnell's Equations: Reflection and Transmission
Fresnel's equations describe the reflection and transmission of electromagnetic waves at an interface.
[16]
Specular and Diffuse Reflection - Evident Scientific
Specular reflection is light reflected from a smooth surface at a definite angle, while diffuse reflection is from rough surfaces reflecting light in all ...
[17]
Speed of Light - Evident Scientific
Light traveling in a uniform substance, or medium, propagates in a straight line at a relatively constant speed, unless it is refracted, reflected, diffracted, ...
[18]
Speed of Light - Physics Van - University of Illinois Urbana-Champaign
The speed of light in a vacuum is 3x10^8 meters per second, which is not infinite. Light travels slower in transparent mediums.
[19]
[PDF] 2) First order optics
Reflection from a Plane mirror θr θi normal. Law of reflection θi = θr. Reflected ray in plane with incident ray and surface normal. In vector form: nnk kk i i.
[20]
[PDF] derivation of the basic laws of geometric optics
Feb 6, 2017 · We remedy this situation here by re-deriving the basic laws of geometrical optics starting with the Fermat Principle that a light rays will ...
[21]
[PDF] Fermat's Principle and the Laws of Reflection and Refraction ( )2
Fermat's principle states that “light travels between two points along the path that requires the least time, as compared to other nearby paths.
[22]
26 Optics: The Principle of Least Time
The first way of thinking that made the law about the behavior of light evident was discovered by Fermat in about 1650, and it is called the principle of least ...
[23]
[PDF] Law-of-Reflection-Fermat-Principle.pdf
Use Fermat's Principle to determine the valid ray path at a reflective boundary. The ray propagates from point a to point b. The variable y defines the ray.
[24]
3.Fermat's Principle of Least Time - Galileo and Einstein
Fermat famously stated in the 1630's that a ray of light going from point A to point B always takes the route of least time.
[25]
2.2 Spherical Mirrors - University Physics Volume 3 | OpenStax
Sep 29, 2016 · Describe image formation by spherical mirrors. Use ray diagrams and the mirror equation to calculate the properties of an image in a spherical ...<|control11|><|separator|>
[26]
2.1 Images Formed by Plane Mirrors - University Physics Volume 3
Sep 29, 2016 · By the end of this section, you will be able to: Describe how an image is formed by a plane mirror. Distinguish between real and virtual images.
[27]
Spherical Mirrors - Richard Fitzpatrick
The approximation in which we neglect spherical aberration is called the paraxial approximation. Likewise, the study of image formation under this ...
[28]
Aberrations
Lenses with spherical surfaces only image P to P' in the paraxial approximation, when the light stays close to the optic axis and rays make small angles ...
[29]
Physics of Light and Color - Introduction to Mirrors
The image produced by a plane mirror appears equal in size to the object, and is erect (right side up). Interior decorators often utilize the optical properties ...
[30]
[PDF] Tutorial: Ray tracing for plane mirrors
Properties of image formed in plane mirror:. Same size as object.. Laterally inverted (Left becomes right, right becomes left).. Upright.. Virtual.
[31]
[PDF] PHY 171 Chapter 35: Geometric Optics
Jan 18, 2012 · The image is laterally inverted (your right is left in the mirror). Spherical Mirrors. Now, observe how curved surfaces reflect light – notice ...
[32]
[PDF] Bob Miller Light Artist - Exhibits - Exploratorium
Many children have had the experience of standing between parallel mirrors and seeing their image multiply reflected off onto infinity. This exhibit, Look Into ...
[33]
Mirrors and Lenses
This is the principle of a Kaleidoscope. Each point on the object appears as five images for a total of six things to look at!
[34]
[PDF] Synthesis Study of Light Vehicle Non-Planar Mirror Research
Planar rearview mirrors, consisting of a flat surface. (effectively, an infinite ROC), provide a more limited FOV while providing a non-minified image which ...
[35]
[PDF] Water Tank Diffraction - UCSB HEP
Devise a system of plane mirrors that will let you see the back of your head. Trace the rays to prove your point. 34. Design a periscope, taking advantage of ...
[36]
Batch Specular Plane Flatness Measurements Based on Phase ...
Apr 24, 2024 · And the flatness of the optical mirror directly affects image quality or beam quality [3]. It is evident that flatness plays a crucial role in ...
[37]
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/02%3A_Geometric_Optics_and_Image_Formation/2.03%3A_Spherical_Mirrors
[38]
Convex Mirrors | CK-12 Foundation
Convex mirrors provide a wide angle view and they provide an upright image. Wide angle images have benefits in rearview mirrors, in-store customer monitors, ...
[39]
[PDF] Lecture 29 – Geometric Optics - Purdue Physics
– Parabolic mirrors do not suffer from spherical aberration, but they distort images from points that do not lie on the optical axis. • Schmidt corrector ...
[40]
[PDF] Focusing properties of spherical and parabolic mirrors
(1). The equation for the circle of radius r, whose center is located at C with coordinates (0,r) is given by x2 + (y − r)2 = r2 ,Missing: 4fx aberration avoidance
[41]
18.7 Aberration
For a mirror, this aberration may be corrected if the mirror is ground to be part of a parabola of revolution instead of a sphere.Missing: definition | Show results with:definition
[42]
[PDF] Lecture 33 – Geometric Optics - Purdue Physics
– Parabolic mirrors do not suffer from spherical aberration, but they distort images from points that do not lie on the optical axis. • Schmidt corrector ...
[43]
https://labman.phys.utk.edu/phys136core/modules/m10/aberrations.html
[44]
[PDF] the justification of the existence of higher natures in - DADUN
tion in Democritus's theory of vision, whereby vision is assimilated to the phenomenon of reflection, a phenomenon which is clearly caused by and of the ...
[45]
Democritus - Stanford Encyclopedia of Philosophy
Aug 15, 2004 · Democritus' theory of taste, for example, shows how different taste sensations are regularly produced by contact with different shapes of atoms.Missing: reflection | Show results with:reflection
[46]
[PDF] THE SCIENCE OF OPTICS TO THE TIME OF KEPLER
18 Euclid, Catoptrics, 340-42. Page 18. The Science of Optics to the Time of Kepler. Encyclopedia of the History of Science.
[47]
Science, Optics and You - Timeline - Ptolemy - Molecular Expressions
This series of works was dedicated to the study of color, reflection, refraction, and mirrors of various shapes. The establishment of theory by experiment ...
[48]
The Attraction of Ibn al-Haytham's Optics - Muslim Heritage
Sep 4, 2023 · Its seven books treat of the function of the eye, direct vision, reflection and images seen by reflection, refracted light and false images.
[49]
Ibn Al-Haytham: Father of Modern Optics - Europe PMC Article
Ibn al-Haytham was the first to describe accurately the various parts of the eye and give a scientific explanation of the process of vision. In medicine and ...<|separator|>
[50]
Alhazen Builds the First Camera Obscura - History of Information
A revealing experiment introduced the camera obscura in studies of the half-moon shape of the sun's image during eclipses.
[51]
Atmospheric refraction: a history - Optica Publishing Group
The concept that the atmosphere could refract light entered Western science in the second century B.C. Ptolemy, 300 years later, produced the first clearly ...
[52]
Optics to the Time of Kepler - Encyclopedia of the History of Science
This, most likely, was the edition of Witelo's Perspectiva to which Kepler was responding in the Paralipomena of 1604. ... Optics: Paralipomena to Witelo and ...
[53]
[PDF] Descartes' Optics | Scholars at Harvard
In his Dioptrics, Descartes proposes to derive the law of reflection by attending to Page 3 Descartes' “Optics” to appear in The Cambridge Descartes Lexicon, ...Missing: Dioptrique | Show results with:Dioptrique
[54]
Arab Origins of the Discovery of the Refraction of Light
He analyzed burning mirrors, both parabolic and ellipsoidal; he considered hyperbolic plano-convex lenses and hyperbolic biconvex lenses. This treatise ...
[55]
[PDF] Inside the Camera Obscura – Optics and Art under the Spell of the ...
Vision: Some Optical Ideas as a Background to the Invention of the Telescope. ... projected images had no place in the medieval optical tradition. A less ...
[56]
[PDF] Taking a Closer Look: Examining Light and Telescopes
Another advantage of reflectors is that there is no chromatic aberration, a feature of refractors where the different wavelengths of light pass through the lens ...
[57]
[PDF] Preliminary considerations of optical telescopes for lunar surface use
because a reflecting mirror provides more nearly perfect color rendition than a lens and can be made in much larger sizes.
[58]
Newton's telescope, an examination of the reflecting ... - Journals
Isaac Newton (1642-1727, FRS 1672, PRS 1703-1727) is generally I credited with the invention of the reflecting telescope, having conceived the idea in 1666.
[59]
Newton's Reflecting Telescope | Multiwavelength Astronomy - eCUIP
Newton used a mirror. He experimented with different metals and polishing methods and made his first reflecting telescope in 1668.
[60]
Laurent Cassegrain - Linda Hall Library
Aug 31, 2020 · The Cassegrain telescope was first described (and diagramed) in a short paper in the Journal des Scavans in 1672 (first image), based on a ...
[61]
The Early Reflecting Telescope:Cassegrain and Mersenne
Sep 19, 2019 · Over the last 120 years, almost all of the largest optical telescopes were reflecting telescopes with a "Cassegrain" configuration.
[62]
The history of the Ritchey-Chrétien telescope | Astronomy.com
Mar 2, 2020 · Henri Chrétien was a brilliant astronomer and optical engineer. Together, they created one of today's best telescope designs.
[63]
Scientist of the Day - Henri Chretien, French Optician and Astronomer
Feb 2, 2021 · However, the Ritchey-Chrétien telescope was a superior design, and it was eventually adopted by most of the world's large telescopes ...
[64]
[PDF] Telescopes I
Off axis images become bad quickly. Telescope design = para boload the ... [but paraboloids have problems off-axis]. "transverse spherical aberration.Missing: challenges | Show results with:challenges
[65]
[PDF] ASTRONOMICAL TELESCOPES: A NEW GENERATION
Off-axis, however, it suffers from coma, astigmatism, and field curvature. These are re- duced by changing the primary mirror to a hyperbola, resulting in a ...
[66]
Hubble's Mirror Flaw - NASA Science
Shortly after the Hubble Space Telescope's launch in 1990, scientists and engineers discovered that the observatory's primary mirror had an aberration that ...
[67]
[PDF] The Hubble Telescope Failure Rewrt
Approximately two months after launch, on June 21, 1990, the Hubble Space. Telescope Project Manager announced that there was a major flaw in one or both of the ...
[68]
Specialized Microscope Objectives | Nikon's MicroscopyU
Reflected light is the technique of choice for infrared microscopy, and several specialized catoptric objectives have been designed to capture images with ...<|separator|>
[69]
Design and Numerical Analysis of an Infrared Cassegrain ... - PMC
Moreover, the SiO2 plus Al material combination has quite low optical absorption from deep-ultraviolet (DUV, ~190 nm) all the way to the mid-wave infrared ...Missing: Mangin | Show results with:Mangin
[70]
Teaching an old mirror new tricks - SPIE
Jun 1, 2003 · Invented in 1876, the Mangin mirror consists of a meniscus negative lens with a mirrored convex second surface (see figure).Missing: microscopy | Show results with:microscopy
[71]
The Design of Reflecting Microscope Objectives
An objective using a concave reflector alone has the advantage of negative field curvature which can compensate the positive curvatures of an eyepiece. However, ...
[72]
[PDF] Section 2 Mirrors and Prism Systems
Plane mirrors can deviate, fold, and change image parity. Two parallel mirrors act as a periscope. Two non-parallel mirrors can deviate rays. A roof mirror is ...
[73]
Mirror sleeve endoscopes
Mirror sleeve endoscopes have a basic line of sight of 0° straight ahead and variable lines of sight of 70°, 90° and 110° thanks to sliding mirror sleeves.Missing: catoptric | Show results with:catoptric
[74]
Design of free-form reflector for vehicle LED low-beam headlamp
Aug 1, 2016 · A method is proposed for the design of a vehicle low-beam headlamp system comprising a reflector and an LED light source.
[75]
Custom parabolic & ellipsoidal reflectors | Precision grade cold mirror
The use of a parabolic for focusing, or collimating, is the removal of spherical aberration that occurs with a spherical reflector surface. The reflectors have ...<|separator|>
[76]
Heliostats - an overview | ScienceDirect Topics
Heliostats are multiple reflecting mirrors that concentrate sunlight onto a receiver, often using thin glass mirrors supported by a backing.Missing: catoptric | Show results with:catoptric
[77]
Performance evaluation of a linear Fresnel collector with catoptric ...
In this paper, the optical, thermal and overall performance of a linear Fresnel collector with catoptric subsets is reported. Subsets consist of mirrors ...<|separator|>
[78]
https://www.researchgate.net/publication/340733877_Performance_evaluation_of_a_linear_Fresnel_collector_with_catoptric_subsets
[79]
Cavity Mirror / End Mirror - Laser Components
Resonator end mirrors, also known as cavity mirrors, are designed to have high reflectivity at the desired laser wavelength in order to maximize the efficiency ...
[80]
Telescopes - W. M. Keck Observatory
Keck Observatory's scientists and engineers have learned to remove the effects of atmospheric blurring using adaptive optics (AO). AO measures and then corrects ...
[81]
W. M. Keck Observatory's Adaptive Optics System Upgraded to 'See ...
Sep 28, 2020 · Keck Observatory can now provide adaptive optics (AO) correction using light from cosmic objects at wavelengths invisible to the naked eye. Near ...
[82]
Adaptive optics at W. M. Keck Observatory - SPIE Digital Library
Aug 27, 2024 · The Keck II HAKA project to implement a high order deformable mirror (DM) will reduce atmospheric fitting error and uncorrectable static ...
[83]
Webb's Mirrors - NASA Science
NASA's James Webb Space Telescope sits inside Chamber A at NASA's Johnson Space Center in Houston after having completed its final cryogenic testing on Nov. 18, ...
[84]
Webb Space Telescope primary mirror development: summary and ...
The largest cryogenic mirror under development was the 0.85-m diameter Infrared Telescope Technology Testbed (ITTT) Beryllium primary mirror, which would ...
[85]
Webb's Primary Mirror Segments Go into Cryogenic Testing
Aug 28, 2025 · NASA engineer Ernie Wright looks on as the first six flight-ready primary mirror segments are prepped to begin final cryogenic testing at NASA's ...
[86]
Echelle Grating Spectroscopic Technology for High-Resolution and ...
Echelle grating provides high spectral resolving power and diffraction efficiency in a broadband wavelength range by the Littrow mode.Missing: catoptric | Show results with:catoptric
[87]
Echelle Gratings - Thorlabs
Echelle Gratings are special low period reflective gratings designed for use in the high orders. They are generally used with a second grating or prism.Missing: catoptric pre-
[88]
Particle identification with the NA62 RICH detector - ScienceDirect
The RICH mirror system is comprised of 20 mirrors with the focal length of ... Each PM is complemented by a Winston cone [5] to improve light collection.
[89]
Light composite mirrors for RICH detectors - ScienceDirect.com
Many RICH detectors use spherical mirrors in order to focus on the photodetectors the Cherenkov photons emit along the trajectory of a charged particle. A usual ...
[90]
Calorimetry and light-based detectors for future experiments
Jun 26, 2025 · The radiator is usually a gas, the optical system an array of mirrors and the camera an array of single-photon sensitive sensors, which will ...
[91]
The NIST Length Scale Interferometer
An interferometer using a stabilized laser light source as a length standard for measuring scales. Measuring devices for temperature, barometric pressure ...Changes in Length... · The NIST Length Scale... · Measurement Assurance
[92]
A Review of Optical Interferometry for High-Precision Length ... - MDPI
Optical interferometry has emerged as a cornerstone technology for high-precision length measurement, offering unparalleled accuracy in various scientific ...
[93]
Interferometers – types, operation principle, Mach - RP Photonics
Interferometers are devices utilizing interference, for example for high precision measurements. Many different types are used.Fabry–Pérot Interferometers · Michelson Interferometers · Fizeau Interferometers<|control11|><|separator|>
[94]
49 CFR § 571.111 - Standard No. 111; Rear visibility.
Each motor vehicle using a convex mirror to meet the requirements of S5. 3 shall comply with the following requirements: S5. 4.1 When each convex mirror is ...
[95]
Interpretation ID: kesler23584 - NHTSA
If convex mirrors are used, they must have a radius of curvature between 35 and 65 inches and they must be marked with the warning: "Objects in Mirror are ...
[96]
US10266119B2 - Interior rearview mirror system for vehicle - Google ...
An interior rearview mirror system for a vehicle includes an interior rearview mirror assembly having a mirror head with a mirror reflective element.
[97]
The Illusionist: The Mind-Bending Installations of Artist Felice Varini
Nov 11, 2016 · The project is called Cercle et suite d'éclats, and features around two dozen white circles superimposed on the beautiful old buildings. Like ...
[98]
Dan Graham - Marian Goodman Gallery
Made of two-way mirror glass and steel, using the curved anamorphic surfaces that have been increasingly present in Dan Graham's work, this pavilion refers ...
[99]
Yayoi Kusama: Infinity Mirror Rooms | Tate Modern
Infinity Mirrored Room – Filled with the Brilliance of Life is one of Kusama's largest installations to date and was made for her 2012 retrospective at Tate ...Exhibition guide · Kusama with Fizz · Here · Members Hours
[100]
Solar thermal power plants - U.S. Energy Information Administration ...
Because of its parabolic shape, a trough can focus the sunlight from 30 times to 100 times its normal intensity (concentration ratio) on the receiver pipe, ...
[101]
CONCENTRATING SOLAR PROJECTS - Department of Energy
Rising 450 feet above the California Desert, Ivanpah is the world's largest concentrating solar power facility. ... parabolic trough concentrating solar power ...
[102]
[PDF] Manufacturing Cost Analysis of Advanced Parabolic Trough Collector
The United States is home to 3 operational power tower plants totaling 392 MWe. (Ivanpah project) and 14 operating parabolic trough projects totaling 1,746 MWe ...
[103]
The Manufacturing and Applications of Optical Mirrors
Sep 4, 2025 · In laser machines, mirrors direct beams through a series of optical components for cutting, engraving, or welding. In microscopes, they redirect ...
[104]
Automated optical system for quality inspection on reflective parts
Mar 7, 2025 · This work presents the development of an automated optical inspection system for reflective parts, focusing on components made of high-pressure diecast ...
[105]
Laparoscopic Light Source Demonstration By Dr R K Mishra
Aug 26, 2020 · Reflector: The reflector is a mirror located at the end of the laparoscope. It reflects the light transmitted through the fiber-optic cable onto ...
[106]
Endoscopic Imaging Technology Today - PMC - NIH
May 18, 2022 · Bozzini introduced a mirror to reflect the light of a candle directly into the direction of view through the hollow endoscope tube into the body ...
[107]
Illuminating the human body | SCHOTT
Modern endoscopes, which evolved from simple systems of candlelight and mirrors, now transmit high-resolution images and allow for complex procedures through ...
[108]
A Review on Metamaterial Absorbers: Microwave to Optical - Frontiers
Apr 28, 2022 · Out of all the unnatural properties, metamaterial-based absorbers (MMAs) offer perfect absorption, thus making them highly efficient to capture ...
[109]
Perfect Metamaterial Absorber | Phys. Rev. Lett.
May 21, 2008 · We present the design for an absorbing metamaterial (MM) with near unity absorbance A ⁡ ( ω ) . Our structure consists of two MM resonators that couple ...Missing: post- | Show results with:post-