Fact-checked by Grok 2 weeks ago

Optical instrument

An optical instrument is a device that manipulates light using optical elements such as lenses, mirrors, prisms, or other transparent media to enhance human vision, form images, or perform measurements, often by magnifying objects or extending the range of observation beyond the capabilities of the unaided eye.^[1] These instruments operate on fundamental principles of optics, including refraction and reflection, where converging lenses or mirrors form real or virtual images depending on the object's position relative to the focal point.^[2] Common examples encompass simple magnifiers like eyeglasses, as well as compound systems such as cameras, microscopes, telescopes, and binoculars.^[3] The development of optical instruments traces back to the late 16th and early 17th centuries in the Netherlands, where spectacle makers pioneered key advancements.^[4] The compound microscope, utilizing two lenses for higher magnification, was introduced around 1590 by Hans and Zacharias Janssen, enabling the visualization of microscopic structures.^[4] Independently, the refracting telescope was invented in 1608 by Hans Lippershey, consisting of an objective lens and eyepiece to enlarge distant objects, a design later refined by Galileo Galilei for astronomical observations.^[5] These early innovations laid the foundation for diverse applications in science, medicine, and everyday life. Optical instruments are broadly classified into simple and compound types, with variations incorporating refraction or reflection.^[2] Simple instruments, such as the magnifying glass, employ a single converging lens to produce an enlarged virtual image when the object is placed within the focal length, achieving angular magnification of approximately 250 divided by the focal length in millimeters.^[6] Compound microscopes use an objective lens to form a real intermediate image, which the eyepiece then magnifies further, yielding total magnifications often exceeding 100x for biological and material studies.^[3] Telescopes, designed for distant viewing, include refracting models like the Keplerian (inverted image) and Galilean (erect image) configurations, as well as reflecting types such as the Newtonian, which use parabolic mirrors to gather light proportional to the square of the objective diameter.^[2] Cameras and projectors extend these principles to capture or display images, while specialized instruments like spectrometers analyze light spectra for scientific measurement.^[1] In modern contexts, optical instruments have evolved with advancements in materials and design, supporting fields from astronomy and microscopy to lithography and medical imaging, though their core reliance on light manipulation remains unchanged.^[3] Limitations, such as chromatic aberration in lenses or diffraction in small apertures, are addressed through multi-element systems or hybrid designs combining optics with digital technologies.^[2]

Fundamentals

Definition and Scope

An optical instrument is a device or system that manipulates light through the use of optical elements such as lenses, mirrors, prisms, diffracting gratings, or other components to form images, measure physical properties, or analyze the characteristics of light or objects.^[7] These instruments extend the capabilities of the human eye by enhancing magnification, resolution, or detection of details beyond normal visual perception.^[8] The scope of optical instruments encompasses both passive systems, which rely on non-powered elements like lenses and mirrors to passively redirect and focus incoming light, and active systems that incorporate powered components such as lasers for coherent light generation or modulators for dynamic control.^[7] However, this scope excludes non-optical sensors, such as electronic imagers or detectors that operate without optical components to manipulate light, as they do not involve light manipulation via refractive, reflective, or diffractive principles. Key performance metrics define the effectiveness of optical instruments, including magnification, which quantifies the enlargement of an object's apparent size (either linearly as the ratio of image to object height or angularly as the ratio of subtended angles); resolution, determined by the minimum separable distance or angle limited primarily by diffraction effects; field of view, representing the angular extent of the observable scene; and light-gathering power, which scales with the aperture area and enables detection of faint sources.^[8]^[9] Optical instruments broadly fall into categories such as imaging devices for forming visible or recorded representations of objects, spectroscopic instruments for dispersing and analyzing light by wavelength to identify material composition, and metrological instruments for precise measurement of dimensions, surfaces, or wavefronts using interference or other light-based techniques.^[10]^[11]^[12]

Basic Optical Principles

Optical instruments rely on the principles of geometric optics to model the propagation of light as rays, which approximate the behavior of light waves when the wavelength is much smaller than the optical elements involved. Ray tracing is a fundamental technique in geometric optics that predicts the path of light rays through optical systems by applying laws of reflection and refraction at interfaces.^[13] The law of reflection states 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. For refraction at the boundary between two media with refractive indices n_1 and n_2, Snell's law governs the bending of rays: n_1 \sin \theta_1 = n_2 \sin \theta_2, where \theta_1 and \theta_2 are the angles of incidence and refraction, respectively.^[13] This law enables the calculation of ray directions in lenses and prisms, forming the basis for designing focusing elements.^[14] Lenses, key components in optical instruments, focus light through curvature-induced refraction, quantified by the lensmaker's formula for a thin lens in air:

\frac{1}{f} = (n - 1) \left( \frac{1}{R_1} - \frac{1}{R_2} \right),

where f is the focal length, n is the refractive index of the lens material, and R_1 and R_2 are the radii of curvature of the lens surfaces (with sign convention based on the center of curvature relative to the incoming light).^[14] Positive f indicates a converging lens, essential for image formation in microscopes and telescopes.^[15] While geometric optics provides a ray-based approximation, wave optics accounts for light's wave nature, particularly in phenomena like interference and diffraction that limit instrument performance. Interference occurs when two or more coherent light waves superpose, producing constructive or destructive patterns depending on phase differences; this principle underlies anti-reflection coatings and interferometric instruments.^[16] The diffraction limit sets the ultimate resolution of optical systems, approximated by \delta \approx \frac{[\lambda](/page/Lambda)}{2 \mathrm{[NA](/page/Numerical_aperture)}}, where \lambda is the wavelength and \mathrm{NA} is the numerical aperture (\mathrm{NA} = n \sin \alpha, with \alpha the half-angle of the maximum cone of light).^[17] This Rayleigh criterion defines the minimum resolvable distance, beyond which wave effects blur fine details regardless of geometric design.^[18] Aberrations arise from deviations in ray paths that degrade image quality, necessitating corrections in high-performance instruments. Chromatic aberration results from wavelength-dependent refraction, causing different colors to focus at varying points; it is mitigated by achromatic doublets, which combine crown and flint glass lenses with opposing dispersion to achieve color-neutral focus.^[19] Spherical aberration occurs when peripheral rays focus closer than paraxial rays due to lens sphericity, leading to blurred edges; it is reduced using aspheric surfaces or stopped apertures.^[20] Astigmatism, prominent in off-axis imaging, produces line foci instead of points due to differing curvatures in meridional and sagittal planes, often corrected by cylindrical lenses or symmetric doublets.^[21] Relevant properties of light influencing instrument design include its wavelength range and polarization. Visible light spans approximately 400–700 nm, but optical instruments extend to ultraviolet (below 400 nm) for high-resolution applications and infrared (above 700 nm) for thermal imaging, requiring materials transparent in those bands.^[22] Polarization, the orientation of light's electric field vector, affects reflection and transmission at interfaces via Fresnel equations; birefringent materials exploit this for waveplates and polarimeters in instruments.^[23]

Historical Development

Early Innovations

The earliest known optical innovations emerged in ancient civilizations, where rudimentary lenses and reflective devices laid the groundwork for later instruments. In ancient Egypt, during the Old Kingdom around 2500 BCE, rock crystal was ground into lens-like shapes for the eyes of funerary statues, creating unique optical effects such as the gaze appearing to follow the observer and reduced spherical aberration, indicating early experimentation with light manipulation.^[24] In the 3rd century BCE, Greek mathematician Archimedes is attributed with employing polished bronze mirrors to concentrate sunlight, purportedly to ignite enemy ships during the siege of Syracuse—a legendary feat that highlights early experimentation with parabolic reflection, though historical accounts remain anecdotal and unverified by physical evidence.^[25] Medieval advancements in optics were significantly advanced by Arab scholars, particularly Ibn al-Haytham (Alhazen), whose work in the early 11th century formalized key principles of image formation. Around 1011 CE, in his seminal Book of Optics, Ibn al-Haytham described the camera obscura—a darkened chamber with a small aperture that projects inverted images of external objects onto a surface—demonstrating how light rays travel in straight lines to form clear projections without lenses.^[26] He conducted systematic experiments with pinhole imaging, theorizing that the size of the aperture inversely affects image sharpness, thus establishing foundational theories of refraction and perspective that influenced European optics. These contributions shifted optics from philosophical speculation to empirical science, emphasizing controlled observation over myth.^[27] The Renaissance marked a pivotal era for practical optical instruments, driven by Italian and Dutch innovators who built on medieval theories. The first wearable spectacles, consisting of convex glass lenses mounted in frames to correct presbyopia, enabling clearer reading for the elderly and scholars, appeared around 1286 in Italy—a breakthrough that spread rapidly across Europe despite initial crude craftsmanship.^[28] By 1590, Dutch spectacle-maker Zacharias Janssen and his father Hans experimented with arranging multiple lenses in a tube, producing sketches of a compound microscope that achieved modest magnification of small objects, though no original devices survive and attribution relies on 17th-century testimonies.^[29] In 1608, Dutch spectacle-maker Hans Lippershey invented the refracting telescope, consisting of a convex objective lens and concave eyepiece to enlarge distant objects. In 1609, Galileo Galilei independently constructed an improved refracting telescope with a convex objective and concave eyepiece, achieving up to 30x magnification; he used it to observe celestial bodies, revealing Jupiter's moons and Venus's phases, which supported heliocentric models.^[30] Despite these milestones, early optical instruments suffered from key limitations rooted in material constraints. Rudimentary glass production in the pre-industrial era yielded lenses with high inhomogeneity, bubbles, and impurities, resulting in severe chromatic aberration and spherical distortion that severely limited resolution to blurry, colored images unsuitable for precise scientific use.^[31] This poor optical quality confined applications to basic magnification or projection, hindering broader adoption until advancements in glassmaking in later centuries.

Modern Advancements

The 19th century marked a pivotal era in optical instrumentation through industrialization, enabling precise manufacturing and widespread application of advanced devices. In 1814, Joseph von Fraunhofer invented the diffraction grating by ruling fine lines on glass using a diamond tool, allowing the measurement of light wavelengths and laying the foundation for modern spectroscopy.^[32] This innovation facilitated the analysis of spectral lines, revolutionizing the study of light composition. By 1839, Louis Daguerre introduced the daguerreotype process, the first practical photographic method using a silver-plated copper sheet exposed in a camera obscura, which captured permanent images and spurred the mass production of cameras for scientific and commercial use.^[33] In the 1870s, Ernst Abbe developed the oil-immersion microscope at Carl Zeiss, employing immersion oil between the objective lens and specimen to increase numerical aperture and resolution beyond the diffraction limit of air-based systems, achieving magnifications up to 1,500x for biological observations.^[34] The 20th century saw optical instruments confront physical limits, prompting transitions to complementary technologies and space-based solutions. By the early 20th century, the resolution barrier of light microscopes—limited to about 200 nm due to visible light's wavelength—drove the development of electron microscopy starting in 1931, which used electron beams for atomic-scale imaging but highlighted the enduring role of optical methods for non-vacuum applications.^[35] The Hubble Space Telescope, launched in 1990, represented a leap in astronomical optics with its 2.4-meter primary mirror free from atmospheric distortion, enabling ultraviolet and infrared observations that revealed distant galaxies and cosmic expansion at resolutions unattainable from Earth.^[36] In the 1990s, adaptive optics emerged as a transformative technology for ground-based telescopes, using deformable mirrors and wavefront sensors to correct atmospheric turbulence in real-time, improving image sharpness by factors of 10 or more, as demonstrated in early systems on 3.5-meter telescopes.^[37] Advancements in optical materials significantly enhanced aberration correction, reducing chromatic and spherical distortions in lenses. The development of fluorite crystals in the mid-20th century provided low-dispersion properties that, when combined with standard glass, minimized color fringing by matching refractive indices across wavelengths, enabling apochromatic objectives for high-contrast imaging in microscopes and telescopes.^[38] Similarly, extra-low dispersion (ED) glass, introduced in the late 20th century, offered superior correction for secondary spectrum aberrations compared to conventional crown glass, allowing compact designs in telephoto lenses and binoculars with minimal color artifacts.^[39] Entering the 21st century, digital integration fused photonics with electronics, miniaturizing instruments for versatile applications. Integrated photonics, advancing since the early 2000s, embeds waveguides and modulators on silicon chips to manipulate light at nanoscale speeds, enabling compact spectrometers and sensors for telecommunications and biomedical diagnostics with bandwidths exceeding 100 Gbps.^[40] Post-2000, femtosecond lasers—emitting pulses as short as 10^-15 seconds—revolutionized precision instruments like optical coherence tomography systems, allowing non-invasive tissue imaging at micrometer resolutions in ophthalmology and materials processing without thermal damage.^[41] In the 2020s, AI-enhanced image processing has integrated with optical systems to automate analysis, using deep learning algorithms to denoise and reconstruct images from microscopes and telescopes, improving detection of subtle features in 2D materials or astronomical data by up to 50% in signal-to-noise ratio.^[42]

Classification

By Function

Optical instruments are classified by their primary function, encompassing how they process light to serve distinct purposes such as visualization, property assessment, or precise quantification.^[43] This purpose-driven categorization emphasizes the end goal rather than the underlying hardware, allowing for a structured understanding of their roles in science, engineering, and technology.^[44] Key functional categories include imaging instruments, which create visible representations of objects by collecting and focusing light to form coherent images. Analytical instruments, in contrast, examine light's intrinsic properties, such as wavelength distribution or polarization, to derive information about materials or phenomena. Measuring instruments focus on quantifying specific physical attributes through optical means, often producing numerical outputs for calibration or verification.^[43] Representative examples illustrate these categories without overlapping into detailed designs: telescopes exemplify imaging by enabling observation of remote celestial bodies, spectrometers represent analytical functions through material composition assessment via light dispersion, and autocollimators demonstrate measuring capabilities in alignment tasks for optical systems.^[45]^[46]^[47] Criteria for this classification hinge on output type, distinguishing image-based results from data-driven metrics; scale, spanning microscopic details to vast astronomical vistas; and environment, differentiating ground-based applications from space-oriented ones.^[43]^[44] 19th century developments marked an evolution in these functions, transitioning from qualitative visual aids to quantitative tools enabled by rigorous optical theories, such as those formalized by Carl Friedrich Gauss in geometrical optics.^[44] This shift, prominent in the late 1800s, facilitated precise measurements of light and matter, aligning with broader historical advancements in instrumentation.^[48]

By Optical Components

Optical instruments can be classified based on their primary optical components, which determine how light is manipulated through refraction, reflection, diffraction, or other means. This classification emphasizes the materials and configurations used in constructing the instruments, focusing on elements such as lenses, mirrors, gratings, and fibers. Such categorization highlights the trade-offs in performance, including aberration control, compactness, and wavelength dependence.^[49] Refractive components, primarily lenses and prisms, rely on the bending of light at material interfaces to focus or disperse beams. Lenses, made from glass or plastic, are central to many systems, altering light paths via differences in refractive index. Prisms, similarly refractive, deviate or disperse light for applications like beam steering. These components excel in simplicity and broadband operation but suffer from chromatic aberration, where different wavelengths focus at varying points, limiting performance in polychromatic light. To mitigate this, achromatic doublets combine convex and concave lenses of different materials./25:_Vision_and_Optical_Instruments/25.2:_Other_Optical_Instruments)^[49] Reflective components, such as mirrors and catadioptric elements, use polished surfaces to redirect light without material transmission, avoiding chromatic aberration entirely. Mirrors, often parabolic or spherical, reflect light to form images or collimate beams, enabling larger apertures in systems like telescopes due to reduced weight compared to equivalent lenses. Catadioptric configurations integrate mirrors with refractive elements, such as in Cassegrain designs featuring a primary concave mirror and a secondary convex mirror, to correct spherical aberration while maintaining compactness. However, reflective systems introduce off-axis aberrations like coma, where rays from peripheral field points form comet-shaped images, and require precise alignment to minimize stray light. Their advantages include durability against thermal expansion and suitability for ultraviolet or infrared wavelengths where refractive materials absorb light./25:_Vision_and_Optical_Instruments/25.2:_Other_Optical_Instruments)^[49] Diffractive components, including gratings and holograms, manipulate light through interference patterns etched or recorded on surfaces. Gratings, with periodic rulings, diffract light into specific orders for wavelength separation, as in spectrometers. Holograms, volume or surface variants, reconstruct wavefronts using recorded interference fringes, enabling complex beam shaping. These elements offer thin, lightweight alternatives to traditional optics, with precise control over phase and polarization, but are wavelength-sensitive, performing best with coherent sources like lasers and suffering efficiency losses in broadband applications.^[50]^[49] Instruments vary in configuration by the number and arrangement of components. Single-element systems, such as simple magnifiers using a convex lens, provide basic magnification with minimal complexity but limited field correction. Compound configurations assemble multiple elements, like multi-lens objectives in microscopes, to reduce aberrations and achieve higher resolution through combined focal powers. Fiber-optic based systems employ bundles of thin fibers for light transmission or imaging, offering flexibility and access to confined spaces, as in endoscopes; advantages include high durability in harsh environments and immunity to electromagnetic interference, though they may degrade image quality due to numerical aperture limits./25:_Vision_and_Optical_Instruments/25.2:_Other_Optical_Instruments)^[51] Hybrid systems combine component types for enhanced performance. Refractive-reflective hybrids, like catadioptric telescopes, leverage mirrors for primary focusing and lenses for aberration correction, balancing compactness with wide fields of view. Optoelectronic hybrids integrate optical elements with electronic detectors, such as photodiodes or CCD arrays, converting light signals to electrical outputs for processing; this enables real-time analysis but introduces noise from electronic components. These approaches optimize for specific demands, such as minimizing size in portable devices./25:_Vision_and_Optical_Instruments/25.2:_Other_Optical_Instruments)^[49]

Imaging Instruments

Telescopes

Telescopes are optical instruments that collect and focus light from distant objects to produce magnified images, primarily for observing astronomical phenomena or terrestrial features. They achieve this through objective elements that gather light and eyepieces that magnify the formed image, with performance determined by their ability to resolve fine details and collect sufficient light for faint objects. Unlike near-field imaging devices, telescopes target remote sources where angular magnification is key, building on basic principles of light refraction and reflection to form real or virtual images at infinity for comfortable viewing. Refracting telescopes employ lenses to bend incoming parallel rays to a focal point. The Galilean configuration, consisting of a convex objective lens of long focal length and a concave eyepiece of short focal length, produces an upright image without an intermediate real image, making it compact and ideal for initial designs. In contrast, the Keplerian refractor uses a convex objective and a convex eyepiece, forming an inverted real image at the focal plane that is then magnified, allowing for additional accessories like reticles but requiring erecting prisms for upright viewing in terrestrial applications. These designs suffer from chromatic aberration, where different wavelengths focus at different points, limiting their use to smaller apertures. Reflecting telescopes utilize mirrors to reflect light, avoiding chromatic issues and enabling larger apertures. The Newtonian reflector features a concave parabolic primary mirror that focuses light onto a flat secondary mirror angled at 45 degrees, directing the beam to an eyepiece at the side of the tube for a straightforward, cost-effective setup popular among amateurs. The Cassegrain variant employs a concave parabolic primary and a convex hyperbolic secondary mirror, which reflects light back through a central hole in the primary, resulting in a folded optical path that shortens the tube length while maintaining a long effective focal length, thus improving portability for professional observatories. Catadioptric telescopes integrate refractive and reflective elements to minimize aberrations in compact forms. The Schmidt-Cassegrain design incorporates a spherical primary mirror, a spherical secondary mirror, and a thin aspheric corrector plate at the front aperture, which compensates for spherical aberration and coma, yielding a wide field of view and high magnification in a portable enclosure suitable for both amateur and survey applications. Key performance parameters include the focal length f, defined as the distance from the objective to the point where parallel incident rays converge, which influences the scale of the image and overall system length. The aperture D, or diameter of the primary optic, governs light-gathering capability proportional to D^2 and sets the scale for diffraction-limited performance. Angular magnification [M](/page/M) is given by M = \frac{f_\text{objective}}{f_\text{eyepiece}}, determining how much larger the image appears compared to the naked eye. Resolving power, the smallest resolvable angular separation \theta, follows the Rayleigh criterion as \theta = \frac{1.22 \lambda}{D}, where \lambda is the wavelength, highlighting the trade-off between aperture size and detail for a given light. In astronomical applications, telescopes enable detailed study of stars, galaxies, and planets; for instance, the Hubble Space Telescope's 2.4-meter primary mirror has captured ultraviolet and visible images of distant cosmic structures, revolutionizing understanding of the universe's expansion and formation. Terrestrial uses include spotting scopes, typically refracting designs with erecting optics for upright images, employed in wildlife observation, surveying, and sports viewing. Hybrid radio-optical systems, such as those integrating submillimeter receivers with optical alignment, facilitate multi-wavelength observations of astrophysical phenomena like star-forming regions. A primary limitation for ground-based telescopes is atmospheric distortion from turbulence, which blurs images and reduces resolving power to about 1 arcsecond under typical seeing conditions. This is addressed by adaptive optics systems, which use wavefront sensors to measure distortions in real time and deformable mirrors to apply corrective shapes, achieving near-diffraction-limited performance over narrow fields.

Microscopes

Microscopes are optical instruments designed to magnify small objects at close range, enabling detailed observation of structures invisible to the naked eye. Unlike telescopes, which focus on distant objects, microscopes achieve high resolution for proximal specimens through precise lens arrangements and light manipulation. The fundamental limit of optical microscopes is governed by diffraction, as described by Ernst Abbe in 1873, which sets the minimum resolvable distance d according to the formula

d = \frac{0.61 \lambda}{NA},

where \lambda is the wavelength of light used and NA is the numerical aperture of the objective lens, defined as NA = n \sin \theta with n as the refractive index of the medium and \theta as the half-angle of the maximum cone of light entering the lens.^[52] This Abbe diffraction limit typically restricts resolution to about 200 nm for visible light, beyond which electron microscopy extends capabilities to atomic scales.^[53] Key components of a compound light microscope include the objective lens, which provides primary magnification (typically 4x to 100x) by forming a real intermediate image of the specimen; the eyepiece (ocular lens), which further magnifies this image (usually 10x) for viewing; and the condenser lens, which concentrates and focuses illumination onto the specimen to optimize contrast and brightness.^[54] Illumination techniques vary: brightfield microscopy directs uniform light through the specimen for standard viewing of stained samples, while darkfield microscopy employs an opaque stop to block direct light, allowing only scattered light to reach the objective and producing bright specimens against a dark background, ideal for enhancing visibility of fine structures in unstained materials.^[54]^[55] Common types of optical microscopes include compound light microscopes, which achieve total magnifications up to 1500x by combining multiple lenses and are suited for high-resolution imaging of thin sections.^[54]^[53] Stereo microscopes provide lower magnification (2x to 100x) with binocular viewing for three-dimensional observation of larger, opaque specimens, such as in dissection or assembly tasks.^[56] Confocal microscopes use a pinhole to eliminate out-of-focus light, enabling optical sectioning of thick samples with laser scanning for three-dimensional reconstruction, particularly in fluorescently labeled biological tissues.^[57] Phase-contrast microscopes, developed by Frits Zernike, convert phase shifts in light passing through transparent, unstained specimens into amplitude differences via an annular diaphragm and phase plate, enhancing contrast for live cell structures like organelles without dyes. In biological applications, optical microscopes facilitate cell imaging, such as observing cellular processes in living tissues or identifying microorganisms, supporting research in cytology and pathology.^[59] Industrially, they enable material inspection, including defect analysis in semiconductors, quality control in manufacturing, and surface examination of alloys or composites.^[60] These instruments bridge to electron microscopy, where optical limits necessitate electron beams for sub-200 nm resolutions in ultrastructural studies.^[53]

Cameras

Cameras are optical instruments designed to capture and record images of scenes by focusing light onto a sensitive medium, such as photographic film or digital sensors, through a lens or aperture system.^[61] This process relies on the principles of refraction and projection to form a two-dimensional representation of a three-dimensional subject, enabling the preservation of visual information for later viewing or analysis. Unlike viewing instruments like telescopes or microscopes, cameras emphasize image fixation and storage, transforming transient light patterns into durable records.^[62] Various types of cameras illustrate the diversity in design to suit different imaging needs. The pinhole camera, a simple lensless device, uses a small aperture to project an inverted image onto a surface, producing sharp results with infinite depth of field due to the absence of lens aberrations, though it requires long exposures for sufficient light capture.^[63] Single-lens reflex (SLR) cameras employ a movable mirror and pentaprism to provide a through-the-lens viewfinder, allowing precise composition while the light path is redirected to the film or sensor only during exposure, minimizing parallax errors.^[62] Digital cameras utilize electronic sensors, primarily charge-coupled devices (CCD) or complementary metal-oxide-semiconductor (CMOS) types; CCD sensors transfer charge sequentially for high uniformity and low noise, ideal for scientific applications, while CMOS sensors integrate amplification and processing on-chip for lower power consumption and faster readout, dominating consumer markets.^[64] Cinematic cameras often incorporate anamorphic lenses, which horizontally compress the image to achieve wide aspect ratios like 2.39:1 when projected, enhancing dramatic field of view and shallow depth effects in motion pictures.^[65] Key optical features govern image quality in cameras. The focal plane, located at the lens's focal length from the optical center, is where light rays from a distant object converge to form a sharp image on the sensor or film.^[61] Depth of field (DOF), the range of distances appearing acceptably sharp, is approximated by the formula

\text{DOF} \approx \frac{2 u^2 N c}{f^2}

where u is the subject distance, N is the f-number (aperture ratio), c is the circle of confusion (acceptable blur diameter), and f is the focal length; larger N or u increases DOF, while longer f decreases it.^[66] Shutter speed, the duration the focal plane is exposed to light, directly affects exposure (total light captured) and motion rendering; faster speeds (e.g., 1/1000 second) freeze action but require wider apertures or higher sensitivity to maintain brightness, while slower speeds (e.g., 1/30 second) risk blur from subject or camera movement but allow deeper DOF in low light.^[67] The evolution of cameras traces from the 1839 daguerreotype process, which fixed mercury-amalgamated silver plate images via chemical development, marking the birth of practical photography, to digital innovations.^[68] By the 1980s, Kodak developed the first megapixel sensor in 1986, enabling 1.4 million pixel prints at 5x7 inches, paving the way for electronic capture without film.^[68] Post-2000, smartphone cameras integrated compact sensors, starting with VGA (0.3 megapixel) modules in devices like the 2002 Nokia 7650 and evolving to multi-megapixel arrays by the mid-2000s, with computational enhancements boosting effective resolution and low-light performance.^[69] Cameras find broad applications across fields. In photography, they enable artistic expression through controlled exposure and composition, capturing portraits, landscapes, and events with high fidelity.^[68] Surveillance systems deploy fixed or pan-tilt-zoom cameras for real-time monitoring and security, using wide-angle lenses to cover large areas and detect intrusions via motion analysis.^[70] In scientific documentation, digital cameras with CCD sensors record experimental phenomena, such as cellular processes in microscopy or astronomical events, providing quantitative data through precise pixel measurements and time-lapse sequences.^[71]

Analytical Instruments

Spectrometers

Spectrometers are optical instruments designed to disperse incoming light into its spectral components based on wavelength, allowing for the detailed analysis of light sources to infer material composition and properties.^[72] These devices operate by separating polychromatic light into a spectrum, where the intensity distribution as a function of wavelength reveals information about atomic, molecular, or structural characteristics of the sample or source.^[73] Unlike imaging systems, spectrometers prioritize wavelength resolution over spatial detail, making them essential for analytical applications in science and engineering.^[74] The core components of a typical optical spectrometer include an entrance slit that limits the spatial extent of the input light to improve resolution, a collimator that transforms the diverging beam into parallel rays, a disperser element responsible for wavelength separation, and a detector array or photodiode that captures the dispersed spectrum for readout.^[75] The performance of these instruments is quantified by their spectral resolution, defined as R = \frac{\lambda}{\Delta \lambda}, where \lambda is the central wavelength and \Delta \lambda is the full width at half maximum of the instrumental response function, determining the smallest distinguishable wavelength difference.^[76] Higher resolution enables finer discrimination of closely spaced spectral lines, often limited by factors such as slit width, disperser quality, and detector pixel size.^[74] Prism-based spectrometers employ a triangular prism as the disperser, relying on the wavelength-dependent refractive index of the material—typically glass or flint—to refract shorter wavelengths more than longer ones, producing a continuous spectrum.^[77] These were among the earliest designs, offering simplicity but limited resolution due to material dispersion and absorption at certain wavelengths.^[78] In contrast, grating spectrometers use a diffraction grating, a surface etched with periodic grooves, to disperse light via interference; the grating equation governs this process:

d \sin \theta = m \lambda

where d is the groove spacing, \theta is the diffraction angle, m is the integer diffraction order, and \lambda is the wavelength.^[79] This mechanism provides higher resolution and broader wavelength coverage compared to prisms, with efficiency enhanced by blazed gratings that direct more light into specific orders.^[80] Fourier transform spectrometers, particularly in the infrared range as Fourier transform infrared (FTIR) systems, achieve dispersion through interferometry rather than direct spatial separation, recording an interferogram from a moving mirror in a Michelson setup and applying a Fourier transform to recover the spectrum.^[81] This approach offers superior signal-to-noise ratios via the Fellgett (multiplex) advantage, where all wavelengths are measured simultaneously, and high resolution up to R > 10^6 in advanced configurations.^[82] FTIR systems typically incorporate a broadband source, beam splitter, detector, and computational processing for spectrum reconstruction.^[83] Optical spectrometers find widespread applications in chemical analysis, such as atomic emission spectroscopy where excited atoms emit line spectra characteristic of their elements, enabling quantitative identification and concentration measurements.^[73] In astronomy, they measure Doppler shifts in spectral lines to determine redshifts, quantifying the recession velocities of galaxies and thus the expansion rate of the universe.^[84] For material science, spectrometers assess composition and phase purity, for instance, by analyzing vibrational modes in FTIR to detect impurities or structural defects in solids and polymers.^[85] These tools exclude non-optical variants like mass spectrometers, focusing solely on light-matter interactions for spectral profiling.^[72]

Interferometers

Interferometers are optical instruments that utilize the interference of light waves to achieve high-precision measurements of distances, displacements, and other physical properties. By splitting a coherent light beam into multiple paths and recombining them, these devices produce interference patterns where constructive interference occurs when the path difference is an integer multiple of the wavelength, resulting in bright fringes, and destructive interference when the path difference is a half-integer multiple, yielding dark fringes.^[86] The effectiveness of interference relies on the temporal coherence of the light source, characterized by the coherence length l_c = \frac{\lambda^2}{\Delta \lambda}, where \lambda is the central wavelength and \Delta \lambda is the spectral bandwidth; this length determines the maximum path difference over which stable fringes can form.^[87] Key types of interferometers include the Michelson, Mach-Zehnder, and Fabry-Pérot configurations. The Michelson interferometer splits a beam using a partially reflecting beamsplitter, directs the two paths to fixed and movable mirrors, and recombines them to form fringes; the fringe shift \Delta = \frac{2d}{\lambda} quantifies the path difference $2d introduced by mirror displacement.^[88] In the Mach-Zehnder interferometer, the beam is divided by a first beamsplitter into two paths that propagate separately before recombination at a second beamsplitter, enabling the measurement of phase shifts due to environmental changes along one path without requiring movable components.^[89] The Fabry-Pérot interferometer employs two parallel highly reflective mirrors forming a resonant cavity, where multiple reflections create sharp transmission peaks; its performance is described by the finesse F = \frac{\pi \sqrt{R}}{1 - R}, with R as the intensity reflectivity, indicating the resolution of the interference peaks.^[90] These instruments find critical applications in precision metrology and scientific research. In gravitational wave detection, the Laser Interferometer Gravitational-Wave Observatory (LIGO) uses a large-scale Michelson interferometer with 4 km arm lengths to sense minute spacetime distortions, achieving the first direct observation of gravitational waves from a binary black hole merger on September 14, 2015.^[91] For surface profiling, interferometers like the Twyman-Green variant (a Michelson derivative) map nanometer-scale topography by analyzing phase shifts in reflected light from test surfaces, essential for quality control in optics manufacturing.^[92] In holography, interferometric setups record and reconstruct wavefronts to visualize three-dimensional deformations or vibrations on objects, leveraging interference between object and reference beams for non-contact analysis.^[93] Historically, the Michelson interferometer gained prominence through the 1887 Michelson-Morley experiment, which sought to detect Earth's motion through the luminiferous ether but yielded a null result, influencing the development of special relativity.^[94]

Measuring and Alignment Instruments

Refractometers

Refractometers are optical instruments designed to measure the refractive index of liquids, solids, and gases by exploiting the bending of light at interfaces between media of different optical densities. The core principle relies on Snell's law, which quantifies the relationship between the angles of incidence and refraction: n_1 \sin \theta_1 = n_2 \sin \theta_2, where n denotes the refractive index and \theta the angle. In practice, the instrument applies this law through calibrated scales that convert observed light deflections or boundary positions into refractive index values, enabling assessments of both liquids (via immersion or droplet methods) and solids (via contact prisms). Calibration typically involves standard liquids like distilled water (n_D = 1.3330 at 20°C) to ensure accuracy across temperature variations, as refractive index is sensitive to thermal changes.^[95]^[96] Common types include the Abbe refractometer, which employs the critical angle method for high-precision measurements. In this design, a sample is placed between a high-index prism and a cover plate; monochromatic light illuminates the interface, and total internal reflection occurs at the critical angle, producing a light-dark boundary observable through a telescope. The refractive index is calculated as n = \frac{\sin i}{\sin r}, where i is the angle of incidence in the prism and r the refraction angle in the sample, often simplified at the critical point where r = 90^\circ. The Pulfrich refractometer, an immersion-type variant, directs a near-horizontal light beam through the sample against a prism face at grazing incidence, measuring the resulting deflection to determine the index, particularly suited for solids and requiring adjustable telescope positioning for calibration. Differential refractometers, by contrast, detect small differences in refractive index between a sample and a reference solvent, using beam deflection or interference at two parallel cells to quantify concentration changes with high sensitivity.^[97]^[98]^[99] These instruments find widespread use in quality control across industries. In the food sector, refractometers assess sugar content via the Brix scale, where degrees Brix (°Bx) correspond to the percentage of sucrose by weight, aiding in monitoring fruit juices, honey, and beverages during production to ensure consistency and ripeness. Pharmaceutical applications leverage them to verify the purity of raw materials like solvents and excipients, as deviations in refractive index signal impurities or incorrect concentrations, supporting compliance with stringent regulatory standards. In gemology, refractometers identify and authenticate gemstones by measuring their refractive indices—such as 2.42 for diamond or 1.76 for ruby—facilitating differentiation between natural stones, synthetics, and treatments without invasive methods.^[100]^[101]^[102]^[103]^[104]^[105] Modern digital refractometers achieve remarkable precision, with accuracies as fine as ±0.00002 refractive index units through automated boundary detection, temperature compensation, and LED illumination, surpassing traditional analog models and enabling reliable measurements in controlled environments.^[106]^[107]

Autocollimators

An autocollimator is an optical instrument that integrates the principles of a collimator and a telescope to measure small angular deviations with high precision, typically used for alignment and metrology tasks in optics and engineering. The core design features an objective lens that collimates light from an illuminated reticle, a beam splitter to direct the outgoing beam and redirect the return path, and the reticle itself positioned at the focal plane of the objective. When the collimated beam strikes a flat reflector perpendicular to the optical axis, the reflected beam retraces its path and superimposes on the reticle; any tilt in the reflector causes the returned image to shift laterally in the focal plane.^[108]^[109] The angular deviation δθ is calculated from the observed image shift s using the formula δθ = s / (2 f), where f is the focal length of the objective lens and δθ is in radians for small angles. This relationship arises because the double pass through the focal length effectively doubles the optical path, magnifying the displacement proportional to the reflector's tilt. The instrument's sensitivity depends on the focal length, with longer f providing finer resolution for the same s.^[110]^[111] Autocollimators are classified into several types based on detection and illumination methods. Visual autocollimators rely on an eyepiece for direct observation of the reticle image by an operator, suitable for manual alignments. Digital autocollimators incorporate charge-coupled device (CCD) sensors to capture the image shift electronically, enabling automated data acquisition and higher throughput in production environments. Laser autocollimators employ a coherent laser beam as the light source, offering extended working distances and reduced divergence for applications requiring measurements over larger ranges.^[111]^[112]^[113] Key applications include machine tool alignment, where autocollimators verify the straightness and parallelism of slides and spindles to sub-micrometer tolerances over extended lengths. They are also used for collimating telescope optics by aligning mirrors and lenses to ensure parallel light paths. In semiconductor manufacturing, autocollimators assess wafer flatness and surface tilt during processing to maintain nanoscale uniformity. High-end models achieve sub-arcsecond resolution, such as 0.01 arcseconds, enabling detection of minute angular errors in precision assemblies.^[114]^[115]^[116]^[117]^[118]

References

[1]
Optical instruments - Physics
Aug 5, 1999 · Optical instruments, like magnifying glasses, telescopes, and microscopes, use converging lenses to make things look bigger, often using ...Missing: definition | Show results with:definition
[2]
Optical instruments
Optical instruments include magnifying glasses, simple cameras, slide projectors, telescopes, and microscopes. Telescopes use two elements, and microscopes use ...
[3]
[PDF] S. Blair August 29, 2003 29 3.3. Optical Instruments There are many ...
Aug 29, 2003 · Some examples include eyeglasses, cameras, microscopes, telescopes, binoculars, and projection lithography. We will discuss only a few simple ...
[4]
[PDF] A History of Imaging:
In 1590, the father and son team of. Hans and Zacharias Janssen introduced the compound microscope, a two-ele- ment optical system. Apparently society was ready ...
[5]
[PDF] The History of Telescopes and Binoculars - The University of Arizona
Hans Lipperhay of the Netherlands is credited with inventing the telescope in 1608.
[6]
[PDF] Elementary Optical Systems Section 13 Magnifiers and Telescopes
Magnifiers are single lenses providing enlarged virtual images. Telescopes change the apparent angular size of an object, and can magnify or minify.
[7]
Optical system | Britannica
Sep 15, 2025 · An optical system consists of a succession of elements, which may include lenses, mirrors, light sources, detectors, projection screens, reflecting prisms, ...
[8]
PPLATO | FLAP | PHYS 6.4: Optical instruments - Physics@Brock
This module covers magnification, aberration, resolution, the eye, simple instruments, and complex instruments like microscopes and telescopes.
[9]
Telescopes - RP Photonics
Performance Parameters of Optical Telescopes · Magnification and Exit Pupil · Focal Ratio and Image Scale · Angular Resolution and Light‑gathering Power · Field of ...Missing: metrics | Show results with:metrics
[10]
Types of Optical Instruments and Their Applications - Shiksha
Sep 5, 2025 · These instruments can be categorised into imaging, spectroscopy, measurement, vision correction, light control, medical and industrial ...
[11]
Spectrometers - RP Photonics
An optical spectrometer is an instrument which can be used for investigating wavelength-dependent properties of light, substances or objects.
[12]
Optical Metrology – interferometer, measurement - RP Photonics
Optical metrology is the science and technology of performing measurements with light. In many cases, extremely high precision is achieved.
[13]
[PDF] Basic Geometrical Optics
Snell's law. Snell's law enables us to calculate the direction of the refracted ray if we know the refractive indexes of the two media and the direction of the ...
[14]
[PDF] Lecture Notes on Geometrical Optics (02/10/14)
Lecture Notes on Geometrical Optics (02/10/14). 2.71/2.710 Introduction to Optics –Nick Fang. G. The Lens Maker's Formula. Typically a lens is formed with two ...
[15]
[PDF] Lecture 29 – Geometric Optics - Purdue Physics department
• Spherical aberration depends on the lens arrangement: Page 10. Spherical Aberration of Mirrors. • Spherical mirrors also suffer from spherical aberration. – ...
[16]
[PDF] Wave Optics 2 - Duke Physics
Overview: obstructing part of a wave causes diffraction. When part of a wavefront is obstructed, the progress of the wave energy into the region.Missing: basics | Show results with:basics
[17]
27.6 Limits of Resolution: The Rayleigh Criterion - UCF Pressbooks
The Rayleigh criterion for the diffraction limit to resolution states that two images are just resolvable when the center of the diffraction pattern of one is ...
[18]
[PDF] Optical Microscopy: Principles and Applications
Jan 8, 2018 · Numerical Aperture and Resolution. d. FWHM. ≈ 0.353 λ /NA α. NA = n sin(α). D. f. Resolution. ≈ 0.61 λ / NA. Axial Resolution. ≈ 2 λ / NA2.
[19]
[PDF] Aberration Theory - Quantitative Light Imaging Laboratory
Chromatic Aberrations. ECE 460 – Optical Imaging. ▫ Recall the dispersion ... ▫ Most common correction: the achromatic doublet. → S d i h ft l iti ti.
[20]
26.6 Aberrations – College Physics - UCF Pressbooks
Another common aberration is spherical aberration where rays converging from the outer edges of a lens converge to a focus closer to the lens and rays closer to ...
[21]
Anatomy of the Microscope - Optical Aberrations
Sep 11, 2018 · For chromatic aberration correction, a typical 10x achromat microscope objective is built with two lens doublets, as illustrated in Figure 5, on ...
[22]
A survey of performance characterization for spectropolarimetric ...
Apr 24, 2013 · The range of the electromagnetic (EM) spectrum that is visible to humans has wavelengths of 400 nm (blue light) to 700 nm (red light).
[23]
[PDF] Bioinspired Polarization Imaging Sensors: From Circuits and Optics ...
Most of the light waves en- countered in nature are partially polarized, a linear combi- nation of unpolarized light waves and completely polarized light waves.
[24]
lenses fabricated ca 2620-2400 BC or roughly 4600 years ago
Ancient (in fact, first known) lenses (ca. 4600 years ago) mainly from the IVth and Vth Dynasties of Egypt had truly remarkable and unique optical properties.Missing: instruments | Show results with:instruments
[25]
Telling Time in Ancient Egypt - The Metropolitan Museum of Art
Feb 1, 2017 · 1500 B.C.), there is evidence that sundials, shadow clocks ( 12.181.307 ), and water clocks ( 17.194.2341 ) were used to measure the passing ...
[26]
Archimedes and the Burning Mirrors of Syracuse - Project MUSE
Jun 23, 2023 · The statement that Archimedes set fire to the Roman fleet under Marcellus besieging Syracuse in 212 bc with burning mirrors is fre quently found in scientific ...
[27]
Ibn Al-Haytham: Father of Modern Optics - PMC - PubMed Central
He is known for the earliest use of the camera obscura and pinhole camera. As stated above, he contradicted Ptolemy's and Euclid's theory of vision that ...
[28]
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 which he observed on the wall opposite ...Missing: evidence | Show results with:evidence
[29]
The biology of imaging - PMC - PubMed Central
Feb 14, 2022 · Every problem has a solution and around 1284 Salvino D'Armate is credited with the development of the first spectacles or eyeglasses thanks to ...Missing: evidence | Show results with:evidence
[30]
The Microscope | Science Museum
Aug 19, 2019 · It's not clear who invented the first microscope, but the Dutch spectacle maker Zacharias Janssen (b.1585) is credited with making one of ...
[31]
Galileo and the Telescope | Modeling the Cosmos
After hearing about the "Danish perspective glass" in 1609, Galileo constructed his own telescope. He subsequently demonstrated the telescope in Venice. His ...
[32]
(PDF) Optical glass and glass ceramic historical aspects and recent ...
... glass lens, should have. caused rapid progress of optical systems, but poor. glass quality restricted possible success. The glass. was inhomogeneous and full ...Missing: rudimentary | Show results with:rudimentary
[33]
Joseph von Fraunhofer
Using a diamond, he constructed a diffraction grating with grooves spaced only 0.003 millimeters apart. This enabled him to measure the wavelength of light in ...Missing: historical | Show results with:historical
[34]
Daguerre (1787–1851) and the Invention of Photography
Oct 1, 2004 · Each daguerreotype (as Daguerre dubbed his invention) was a one-of-a-kind image on a highly polished, silver-plated sheet of copper. Daguerre's ...
[35]
Ernst Abbe - physicist, inventor, entrepreneur, and social reformer
Inventions ; 1870. Apertometer ; 1874. Spectrometers ; 1877/78. First microscope with homogeneous immersion (oil immersion) ; 1880. Stereo eyepiece ; 1886. New ...
[36]
History of Electron Microscope - Thermo Fisher Scientific
Sep 13, 2018 · The history of the electron microscope, spanning from the origins of light microscopy to modern techniques such as cryo electron microscopy.
[37]
The History of Hubble - NASA Science
Hubble was launched April 24, 1990, aboard Space Shuttle Discovery's STS-31 mission. Soon after launch, astronomers realized that the primary mirror had a flaw ...
[38]
Adaptive Optics Look Farther Than Ever Before - Photonics Spectra
The initial prototypes of astronomical AO appeared in the late 1980s; the first general-use AO facility became available on an astronomical telescope in 1990.
[39]
Fluorite lenses: Corrective capabilities beyond the limits of ordinary ...
It has long been known that using a fluorite lens in conjunction with a glass lens can reduce chromatic aberration to extremely low levels.
[40]
Extra-low Dispersion Glass | Materials | Nikon About Us
Extra-low dispersion glass has a unique refractive index, allowing for effective chromatic aberration correction, especially for the secondary spectrum, and is ...<|control11|><|separator|>
[41]
Integrated photonics in the 21st century - Optica Publishing Group
We review the emergence and development of integrated photonics and its status today. The treatise is focused on information and communications technology ...
[42]
Fundamentals of Femtosecond Laser and Its Application in ...
With femtosecond laser processing, optical devices can be seamlessly integrated with other components, enabling new applications such as 3D microfluidic ...6. Direct Writing · 6.2 Micromachining Via... · 8.1 Refractive Surgery
[43]
Symbiotic evolution of photonics and artificial intelligence
AI is also significantly transforming the field of optical imaging with improved performance. In addition, AI-driven techniques have revolutionized optical ...
[44]
Optical Measuring Instrument - an overview | ScienceDirect Topics
An optical measuring instrument is defined as a device that detects and quantifies optical radiant energy, often employing calibration to establish a ...
[45]
Optics | History, Applications, & Facts | Britannica
An optical system consists of a succession of elements, which may include lenses, mirrors, light sources, detectors, projection screens, reflecting prisms, ...
[46]
https://www.sciencedirect.com/science/article/pii/B9780127661506500049
[47]
https://osa.magnet.fsu.edu/terms/instruments.html
[48]
Optical Instruments and Systems - Exploring the Science of Light
A. Alignment telescope – An optical tooling instrument consisting of an objective lens, a focusing lens, an optical micrometer, a reticle and an eyepiece.
[49]
[PDF] Chapter 1: Introduction
Chapter 3 discusses the late 19th century as a crucial period in the gradual transition from qualitative to quantitative methods in the measurement of light.
[50]
Types of Optical Systems - Shanghai Optics
In this article, we will discuss the different components of optical systems and types, including refractive and reflective, diffractive and holographic, and ...The Components Of An Optical... · Light Source · Mirrors
[51]
What is Diffractive Optics? - Ansys
Apr 25, 2025 · Diffractive optics describes light as an electromagnetic wave. Light diffraction happens when light waves encounter microstructures (micro-optic elements)Diffraction Gratings · Diffractive Beam Splitters · Advanced Diffractive Optical...Missing: instruments | Show results with:instruments<|control11|><|separator|>
[52]
Fiber-Optic Bundles Create a World of Pure Imagination
Apr 1, 2023 · Durability and Flexibility: This is arguably the greatest benefit, as you can deploy bundle assemblies in very harsh and rugged environments ...
[53]
The Diffraction Barrier in Optical Microscopy | Nikon's MicroscopyU
The diffraction-limited resolution theory was advanced by German physicist Ernst Abbe in 1873 (see Equation (1)) and later refined by Lord Rayleigh in 1896 ...
[54]
Where the tiny becomes mighty: light vs electron microscopy - Abberior
Conventional optical microscopes magnify a specimen up to 1,500x. However, their resolving power is limited by the wavelength of visible light. The performance ...
[55]
Brightfield Microscope: Principle, Parts, Applications - Microbe Notes
Aug 23, 2024 · Eyepiece (Ocular lens) – it has two eyepiece lenses at the top of the microscope which focuses the image from the objective lenses. · The ...
[56]
https://www.isu.edu/biology/biolab/instructor-training/technology/microscopes/
[57]
Microscopes | Idaho State University
Stereo microscopes have low magnifications that can range from 2 to 100x depending on the microscope and are designed for viewing whole objects like rocks, ...
[58]
Confocal Microscopy: Principles and Modern Practices - PMC
The basic principle of confocal microscopy is that the illumination and detection optics are focused on the same diffraction-limited spot, which is moved over ...
[59]
Optical Microscopy - Microscope World
Apr 27, 2023 · Applications For Optical Microscopy. Biological research: Optical microscopy is extensively used in biological research to visualize biological ...
[60]
Material Analysis Microscopes | Applications - Leica Microsystems
These material analysis microscopes are important for different industrial applications, whether in quality control, failure analysis, or research and ...
[61]
[PDF] CS231A Course Notes 1: Camera Models
The distance between the image plane and the pinhole O is the focal length f. Sometimes, the retinal plane is placed between O and the 3D object at a.
[62]
Single Lens Reflex Cameras - HyperPhysics Concepts
The multi-element lens in a single-lens reflex camera helps to correct for lens aberrations. The mirror allows the viewer to see through the lens.
[63]
[PDF] The Pinhole Camera and Image Resolution
Now think about Huygens' principle, where each point inside the pinhole can be thought of as a source of secondary spherical wavelets. (see Figure 2). The waves ...
[64]
[PDF] CCD vs. CMOS: Facts and Fiction
CCDs transfer charge sequentially to a common output, while CMOS converts charge to voltage in each pixel, with most functions integrated into the chip.
[65]
Cinematography – Introduction to Film & TV - OPEN OKSTATE
Figure 20. 2.35:1 Anamorphic widescreen, a lens that squeezes a larger image into a smaller frame (Figure 21). Figure ...Framing · Visual Effects · Camera Movement
[66]
[PDF] Defocus & Depth of field - MIT
In one "look," it calculates the distance and direction the lens must be moved to cancel the phase differences. It then commands the lens to move the ...
[67]
Understanding Exposure for Photography and Film: Shutter Speed
Oct 5, 2022 · Shutter speed controls how long your camera's censor is exposed to light. therefore, the Shutter speed is measured in fractions of a second.
[68]
Display Textbook - Digital History
1986, Kodak scientists invented the world's first megapixel sensor, capable of recording 1.4 million pixels that could produce a 5x7-inch digital photo-quality ...Missing: smartphone | Show results with:smartphone
[69]
https://dspace.mit.edu/bitstream/handle/1721.1/55244/612306873-MIT.pdf
[70]
[PDF] Lens and Camera Arrays for Sky Surveys and Space Surveillance
Eventually portrait lenses were adapted for use as wide-field cameras for survey and star mapping work, followed by meteor photography, asteroid and comet ...<|separator|>
[71]
Use of commercial off-the-shelf digital cameras for scientific data ...
Commercial off-the-shelf digital cameras are inexpensive and easy-to-use instruments that can be used for quantitative scientific data acquisition.Missing: surveillance | Show results with:surveillance
[72]
Optical Spectrometers introduction - Must read - Avantes
How Does a Spectrometer Work? A spectroscopic instrument, or spectrometer, generally consists of entrance slit, collimator, a dispersive element such as a ...Missing: disperser R = λ / Δλ
[73]
Spectroscopy: A Measurement Powerhouse | NIST
Mar 28, 2025 · Scientists use spectroscopy to analyze starlight and other signals from outer space, to define the ticks in atomic clocks, to detect chemical pollutants in the ...
[74]
[PDF] Spectrographs - NMSU Astronomy
The effective focal length is often quoted in millimeters [mm] and is on the order of 103 to 104. in units of [arcsec] where the factor 206,265 is the ...
[75]
[PDF] Spectrographs - Leiden Observatory
The resolution element is the minimum resolution of the spectrograph. This will depend of the spectral size of the image, which is a factor of image size, ...
[76]
Understanding Spectrometer Resolution Specifications - Avantes USA
Jan 11, 2021 · The resolution of a spectrometer is expressed in the following: R=λ/Δλ. When is Resolution Important, or Not? The spectral resolution of an ...
[77]
[PDF] THE DESIGN AND CONSTRUCTION FOR THE SPECTRAL ...
The optical arrangement of any spectrometer can be divided into three main parts; the foreoptics, the monochromator, and the detector optics. In general, the ...
[78]
3.3: Diffraction Gratings - Physics LibreTexts
Oct 10, 2025 · ... d ⁢ sin ⁡ θ = m ⁢ λ . It is for this reason that diffraction gratings are generally characterized by their grating density – the number of ...
[79]
The Grating Equation - Newport
The grating equation mλ= d (sinα + sinβ) (2-1) which governs the angular locations of the principal intensity maxima when light of wavelength λ is diffracted ...Missing: θ = | Show results with:θ =
[80]
Fourier Transform Spectroscopy - RP Photonics
Fourier transform spectroscopy is a method where one computes an optical spectrum from raw data by applying a Fourier transform algorithm.What is Fourier Transform... · Operation Principle · Calibration of Spectral Power...
[81]
[PDF] High Accuracy Ultraviolet Index of Refraction Measurements Using a ...
UV Fourier transform spectrometer (UV-FTS). The. UV-FTS has the advantage of high throughput, signal- averaging, high resolution, and wavelength accuracy,.<|control11|><|separator|>
[82]
How an FTIR Spectrometer Operates - Chemistry LibreTexts
Apr 9, 2023 · FTIR spectrometers (Fourier Transform Infrared Spectrometer) are widely used in organic synthesis, polymer science, petrochemical engineering, pharmaceutical ...
[83]
Spectra and What They Can Tell Us
Spectroscopy can be very useful in helping scientists understand how an object like a black hole, neutron star, or active galaxy produces light, how fast it is ...
[84]
Fourier transform infrared spectroscopic technique for analysis ... - NIH
It has a wide range of applications, from chemical composition analysis, structure identification, and phase identification to surface analysis of inorganic ...
[85]
https://pmc.ncbi.nlm.nih.gov/articles/PMC12426772/
[86]
Coherence Length - RP Photonics
The coherence length is a measure of temporal coherence, expressed as the propagation distance over which the coherence significantly decays.Missing: λ^ Δλ
[87]
[PDF] The Michelson Interferometer - UMD Physics
The Michelson interferometer causes interference by splitting a beam of light into two parts. Each part is made to travel a different path and brought back ...
[88]
[PDF] How does a Mach–Zehnder interferometer work? - cs.Princeton
The Mach–Zehnder interferometer is a particularly simple device for demonstrating interference by division of amplitude. A light beam is first split into.
[89]
Fabry-Perot Interferometer Tutorial - Thorlabs
The overall finesse of a system, Ft, is given by the relation4. Often, the reflectivity finesse, Equation (8), is presented as an effective finesse, which is ...
[90]
Observation of Gravitational Waves from a Binary Black Hole Merger
Feb 11, 2016 · The observation on September 14, 2015, was the first direct detection of gravitational waves and a binary black hole merger, with a signal ...
[91]
Contributions of holography to the advancement of interferometric ...
Jan 1, 2022 · Contributions of holography to the advancement of interferometric measurements of surface topography.
[92]
The discovery of holographic interferometry, its development and ...
Jun 16, 2022 · This paper recounts the discovery of holographic interferometry, discusses its development, and itemizes some of its major applications.
[93]
November 1887: Michelson and Morley report their failure to detect ...
Nov 1, 2007 · In 1887 Albert Michelson and Edward Morley carried out their famous experiment, which provided strong evidence against the ether.
[94]
Refractometers - RP Photonics
The Abbe refractometer exemplifies a critical angle refractometer, which although involving beam deflection, stands apart due to its distinct operational ...
[95]
Basics of refractometry - Anton Paar Wiki
The operation of the refractometer is based on the physical principle of light refraction – Snell's law – which is further described in the next chapter. Light ...Missing: Abbe | Show results with:Abbe
[96]
How an Abbe Refractometer Works: The Principle of Critical Angle
Start with the general form of Snell's Law: nssin(θs)=npsin(θp). At the critical angle condition, the incident light from the sample is at a grazing angle, ...
[97]
Refractometer - an overview | ScienceDirect Topics
A two-prism configuration with the critical-angle method is used in the Abbe refractometer, shown in Figure 5a. The liquid under test is placed between two ...
[98]
Pulfrich refractometer
Mar 17, 2025 · A beam of monochromatic light is directed almost horizontally through the substance so that it meets the prism face at grazing incidence. the ...
[99]
The Refractometer, How It Works and Role in the Food Industry
May 3, 2024 · A refractometer is a device used to measure the refractive index (n) of a substance. This physical property can be used to make a variety of assessments.
[100]
Brix: The Essential Knowledge - Mettler Toledo
The Brix scale is used to measure sugar content in substances such as soft drinks, fruit juices and tomato concentrates, as well as products such as cutting oil ...
[101]
Applications of Refractometers in Pharmaceutical Industry - GAO Tek
Refractometers are utilized to test the purity and quality of raw materials used in pharmaceutical manufacturing, such as solvents, excipients, and reagents.
[102]
Review Refractive Index Measurement of Pharmaceutical Solids
Refractive index characterization of pharmaceutical solids has been used in multiple applications to improve understanding of pharmaceutical drug products.
[103]
Refractometer - The Gemology Project
Dec 13, 2016 · The refractometer is one of the most important tools in a gemological laboratory. It indicates (not measures) the refraction index of a gemstone.
[104]
The Complete Guide To Gemological Refractometers - arcarda
Feb 14, 2025 · Modern gemological instruments, particularly the professional gem refractometer, have transformed how we identify and verify gemstones. Whether ...
[105]
Refractive Index: All You Need to Know
When using a digital refractometer, liquids and semi-liquid samples can be measured with high accuracy (e.g. down to - / + 0.00002). Gas and solid samples ...
[106]
Refractometer for demanding labs from Rudolph Research
Wide refractive index range of 1.26-1.72. · Measures beyond instruments with only a food refractive index range of 1.33-1.53.
[107]
Autocollimators - RP Photonics
The basic principle of an autocollimator is simple: one directs a collimated beam, which by definition has a small beam divergence, to a flat reflecting object ...Missing: reticle | Show results with:reticle
[108]
[PDF] 2. Fundamentals of Beam Alignment | Duma Optronics
Apr 2, 2025 · After passing through the beam splitter, the light enters the objective lens where it is collimated prior to exiting the instrument ...
[109]
Measurements with autocollimators | TRIOPTICS
... autocollimator and the tilt angle of the reflector: d=2 α f. (α in radians).The tilt angle can be ascertained with the formula: α = d/(2f). where f is the ...Missing: δθ = | Show results with:δθ =
[110]
Autocollimators Selection Guide: Types, Features, Applications
In this diagram of an autocollimator, the angle of the y-axis mirror displacement ( α ) is calculated using the formula α = Δy/2f where f = focal length of the ...Missing: δθ = | Show results with:δθ =
[111]
Digital Autocollimators - Taylor Hobson
Taylor Hobson's range of Autocollimators are designed for measuring angle, straightness, flatness, squareness and parallelism.
[112]
https://www.taylor-hobson.com/products/alignment-level/autocollimators
[113]
Measuring angle, straightness, flatness, squareness & parallelism
Digital Autocollimators – Dual axis, with clear results Using the latest CCD technology the Ultra Dual Axis Autocollimator is a highly versatile instrument ...
[114]
Electronic Autocollimator and Alignment Telescope - PLX Inc.
The Autocollimator/Telescope can be used for checking the accuracy of machine slides. To check the slides, mount a mirror to the machine table.Missing: collimation semiconductor wafer
[115]
AstroSystems Collimating Tools
The Autocollimator is used only after close collimation with one of the above tools and has very high accuracy because it is a "multiple pass" tool, as many ...Missing: machine semiconductor wafer flatness
[116]
https://www.astrosystems.biz/coltlsm1.htm
[117]
[PDF] Application Note - Advanced Electronic Autocollimators
• Non-contact angular measurement down to sub-arcsecond resolution. • Large dynamic range covering fractions of arcseconds to several degrees. • Multi-tasking ...