![]() (credit: Tatyana Temirbulatova, Flickr)ĭiffraction is not only a problem for optical instruments but also for the electromagnetic radiation itself. Arecibo is still very useful, because important information is carried by radio waves that is not carried by visible light. Although D D for Arecibo is much larger than for the Hubble Telescope, it detects much longer wavelength radiation and its diffraction limit is significantly poorer than Hubble’s. It is the largest curved focusing dish in the world. 22 λ / D, so that two point objects are just resolvable if they are separated by the angleįigure 27.28 A 305-m-diameter natural bowl at Arecibo in Puerto Rico is lined with reflective material, making it into a radio telescope. The first minimum is at an angle of θ = 1. 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 directly over the first minimum of the diffraction pattern of the other. ![]() The accepted criterion for determining the diffraction limit to resolution based on this angle was developed by Lord Rayleigh in the 19th century. 22 λ / D (providing the aperture is large compared with the wavelength of light, which is the case for most optical instruments). It can be shown that, for a circular aperture of diameter D D, the first minimum in the diffraction pattern occurs at θ = 1. Just what is the limit? To answer that question, consider the diffraction pattern for a circular aperture, which has a central maximum that is wider and brighter than the maxima surrounding it (similar to a slit). How far away can you be and still distinguish the two lines? What does this tell you about the size of the eye’s pupil? Can you be quantitative? (The size of an adult’s pupil is discussed in Physics of the Eye.) Telescopes are also limited by diffraction, because of the finite diameter D D of their primary mirror.ĭraw two lines on a white sheet of paper (several mm apart). So diffraction limits the resolution of any system having a lens or mirror. Thus light passing through a lens with a diameter D D shows this effect and spreads, blurring the image, just as light passing through an aperture of diameter D D does. Be aware that the diffraction-like spreading of light is due to the limited diameter of a light beam, not the interaction with an aperture. The acuity of our vision is limited because light passes through the pupil, the circular aperture of our eye. There are many situations in which diffraction limits the resolution. This limit is an inescapable consequence of the wave nature of light. If they were closer together, as in Figure 27.25(c), we could not distinguish them, thus limiting the detail or resolution we can obtain. The pattern is similar to that for a single point source, and it is just barely possible to tell that there are two light sources rather than one. ![]() How does diffraction affect the detail that can be observed when light passes through an aperture? Figure 27.25(b) shows the diffraction pattern produced by two point light sources that are close to one another. (c) If they are closer together, they cannot be resolved or distinguished. (b) Two point light sources that are close to one another produce overlapping images because of diffraction. Real optical systems are complex, and practical difficulties often increase the distance between distinguishable point sources.Figure 27.25 (a) Monochromatic light passed through a small circular aperture produces this diffraction pattern. In low-contrast systems, the resolution may be much lower than predicted by the theory outlined below. The results below are based on mathematical models of Airy discs, which assumes an adequate level of contrast. The sections below describe the theoretical estimates of resolution, but the real values may differ. Resolution depends on the distance between two distinguishable radiating points. Each of these contributes (given suitable design, and adequate alignment) to the optical resolution of the system the environment in which the imaging is done often is a further important factor. Optical resolution describes the ability of an imaging system to resolve detail, in the object that is being imaged.Īn imaging system may have many individual components, including one or more lenses, and/or recording and display components. JSTOR ( November 2009) ( Learn how and when to remove this template message).Unsourced material may be challenged and removed.įind sources: "Optical resolution" – news Please help improve this article by adding citations to reliable sources in this article: "Optical resolution". This article: "Optical resolution" needs additional citations for verification.
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