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Download 4.8 Acceptance Angle and Numerical Aperture
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Transcript
4.8 Acceptance Angle and Numerical Aperture The Numerical Aperture (NA) is a measure of how much light can be collected by an optical system such as an optical fibre or a microscope lens. The NA is related to the acceptance angle a, which indicates the size of a cone of light that can be accepted by the fibre. Equipment Optical Bench Optical Mounts Ruler Optical fibre and holder Imaging screen Protractor cl addi ng n2 air co re co re n1 n1 a n2 cl addi ng n2 Figure 4.32 Acceptance angle of an optical fibre Both numerical aperture and acceptance angle are linked to the refractive index via: NA = naSin a = (n12 – n22)1/2 Where n1 = refractive index of core n2 = refractive index of cladding na = refractive index of air (1.00) Based on measurements of the critical angle and refractive index of plastic (assume the two plastic blocks are similar) calculate the acceptance angle and numerical aperture for the (2D) block. The cladding for the Lucite rod is air. Work out the NA using both equations and comment on the results The kit is supplied with polymer multimode fibre with a core diameter of 1000 microns or 1mm. Acton Instruments - ANU Page 1 6/23/2017 One way of measuring the NA of this fibre is to fill the fibre with light and measure the characteristics of the light leaving the fibre. Plug the fibre into the analog output and position the components on the optical bench as shown in figure 4.33. screen a Fibre Analog in Analog out Photodiode 1 Photodiode 2 BNC & LED BNC & LED Figure 4.33 Measuring numerical aperture The fibre output is a cone of light that spreads out wider as the distance from the fibre exit increases. The grid slide or screen and ruler can be used to measure diameters. The edges of the cone of light may appear fuzzy so there will be an error introduced into your measurements. Measurement of the edges is an approximation to the notion of Full Width Half Maximum (FWHM). This is how light boundaries are characterised as shown in figure 4.34. intensity FWHM distance Figure 4.34 Optical pattern of a LED showing the FWHM points Measure distance and spot diameter for several different distances and plot the results on graph paper to scale. Measure the acceptance (emission) angle and calculate the numerical aperture. The LED light source for the fibre has a lens incorporated into the design to match the numerical aperture of the fibre. Acton Instruments - ANU Page 2 6/23/2017
