| Numerical Aperture |
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GENERAL OPTICS In most areas of optics, and especially in Microscopy , the numerical aperture of an optical system such as an Objective Lens is defined by : where ''n'' is the Index Of Refraction of the medium in which the lens is working (1.0 for Air , 1.33 for pure Water , and up to 1.56 for Oil s), and ''θ'' is the half-angle of the maximum cone of light that can enter or exit the lens. In general, this is the angle of the real Marginal Ray in the system. The Angular Aperture of the lens is approximately twice this value. The NA is generally measured with respect to a particular object or image point and will vary as that point is moved. In microscopy, NA is important because it indicates the Resolving Power of a lens. The size of the finest detail that can be resolved is proportional to λ/NA, where λ is the wavelength of the light. A lens with a larger numerical aperture will be able to visualize finer details than a lens with a smaller numerical aperture. Lenses with larger numerical apertures also collect more light and will generally provide a brighter image. Numerical aperture is a measure of the diameter of the Aperture compared to the Focal Length . In Photography , this relationship is usually expressed via the F-number , ''f/#'', which for a thin lens imaging an object at infinity is given by : (this is only good for very low numerical aperture lenses). LASER PHYSICS In Laser Physics , the numerical aperture is defined slightly differently. Laser beams spread out as they propagate, but slowly. Far away from the narrowest part of the beam, the spread is roughly linear with distance—the laser beam forms a cone of light in the "far field". The same relation gives the NA, :, but ''θ'' is defined differently. Laser beams typically do not have sharp edges like the cone of light that passes through the aperture of a lens does. Instead, the angle between the propagation direction and the angle for which the irradiance drops to 1/e2 times the peak irradiance. The NA of a Gaussian laser beam is then related to its minimum spot size by :, where ''λ'' is the wavelength of the light, and ''D'' is the diameter of the beam at its narrowest spot, measured between the 1/e2 irradiance points ("Full width at e-2 maximum"). Note that this means that a laser beam that is focused to a small spot will spread out quickly as it moves away from the focus, while a large-diameter laser beam can stay roughly the same size over a very long distance. FIBER OPTICS Multimode Optical Fiber will only propagate light that enters the fiber within a certain cone, known as the Acceptance Cone of the fiber. The half-angle of this cone is called the Acceptance Angle , ''θmax''. For Step-index multimode fiber, the acceptance angle is determined only by the indices of refraction: :, where ''nf'' is the refractive index of the fiber core, and ''nc'' is the refractive index of the cladding. This has the same form as the numerical aperture in other optical systems, so it has become common to ''define'' the NA of any type of fiber to be :, where ''no'' is the refractive index along the central axis of the fiber. Note that when this definition is used, the connection between the NA and the acceptance angle of the fiber becomes only an approximation. In particular, manufacturers often quote "NA" for Single-mode Fiber based on this formula, even though the acceptance angle for single-mode fiber is quite different and cannot be determined from the indices of refraction alone. In multimode fibers, the term ''equilibrium numerical aperture'' is sometimes used. This refers to the numerical aperture with respect to the extreme exit angle of a Ray emerging from a fiber in which Equilibrium Mode Distribution has been established. References SEE ALSO |
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