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SEXTANT
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SEXTANT , an See also:instrument for measuring angles on the See also:celestial See also:sphere. The name (indicating that the instrument is furnished with a graduated arc equal to a See also:sixth See also:part of a circle) is now only used to designate an instrument employing reflection to measure an See also:angle; but originally it was introduced by Tycho See also:Brahe, who constructed several sextants with two See also:sights, one on a fixed, the other on a movable See also:radius, which the observer pointed to the two See also:objects of which the angular distance was to be measured. The imperfections of the See also:astrolabe and See also:cross-See also:staff for taking altitudes (see See also:NAVIGATION) were so evident that the See also:idea of employing reflection to remove them occurred independently to several minds. R. See also:Hooke contrived two reflecting See also:instruments. The first, described in his See also:Posthumous See also:Works (p. 503), had only one See also:mirror, which reflected the See also:light from one See also:object into a See also:telescope which is pointed directly at the other. Hooke's second See also:plan employed two single reflections, whereby an See also:eye placed at the See also:side of a quadrant could at the same See also:time see the images formed in two telescopes, the axes of which were radii of the quadrant and which were pointed at the two objects to be measured. This plan is described in Hooke's Animadversions to the Machina Coelestis of See also:Hevelius, published in 1674, while the first one seems to have been communicated to the Royal Society in 1666. See also:Newton also studied this subject, but nothing was known about his ideas till 1742, when a description in his own See also:handwriting of an instrument devised by him was found among See also:Halley's papers and printed in the Philosophical Trans-actions (No. 465). It consists of a sector of See also:brass, the arc of which, though only equal to one-eighth part of a circle, is divided into 9o°. A telescope is fixed along a radius of the sector, the object-See also:glass being See also:close to the centre and having outside it a See also:plane mirror inclined 450 to the See also:axis of the telescole, and intercepting See also:half the light which would otherwise fall on the object glass. One object is seen through the telescope, while a movable radius, carrying a second mirror close to the first; is turned See also:round the centre until the second object by See also:double reflection is seen in the telescope to coincide with the first. But before Newton's plan was published the sextant in its See also:present See also:form had come into See also:practical use. On May 13, 1731, See also: At the meeting of the Royal Society on See also:January 31, 1734, two affidavits sworn before the See also:mayor of Philadelphia were read, proving that Godfrey's quadrant was made about See also:November 1730, that on November 28 it was brought by G. See also: The limb AB is graduated so as to avoid the See also:necessity of doubling the measured angle, a space marked as a
' See See also:Professor See also:Rigaud, Naut. Mag. vol. ii. No. 21. John Hadley was a See also:country See also:gentleman of See also:independent means, and the fact that he was the first to bring the construction of reflecting telescopes to any perfection has made many authors believe that he was a professional instrument maker. His brother George, who assisted him, was a See also:barrister.degree on the limb being in reality only 30'. The vernier preferably of the extended type, i.e. a vernier whose divisions are twice the distance apart of those on the arc, should point to 0° o' o" when the two mirrors are parallel, or in other words, when the See also:direct and reflected images of a distant object coincide.
The sextant was formerly much used on See also:land for determining latitudes in which See also:case an qrtificial horizon (see below) is required, but it has now been largely superseded by the portable altazimuth cr See also:theodolite, while at sea it continues to be indispensable.
The telescopes employed in sextants are of two kinds: the direct, for the more See also:ordinary observations; and the inverting, for astronomical See also:work, one of the eyepieces of which should be of high magnifying See also:power, not less than 15 diameters. Each eyepiece has two pairs of wires, each pair perpendicular to the other, and dividing the See also: Both mirrors are supplied with coloured shades of different degrees of shade, and may be used either singly or combined for sea observations; they are subject to errors of See also:refraction, due to non-See also:parallelism of the sides of the glass. Coloured eyepieces of neutral glass of different intensities are fitted to slip on and off the conically ground See also:surface of the eyepieces of the telescope; they are used for index See also:error and for observations in the artificial horizon. Introducing no refraction error, they also ensure the suns being of the same brilliancy; a very important point. The up and down piece, when adjusted to equalize the suns, will bring the axis of the telescope nearly exactly in line with the edge of the silvered surface of the horizon glass, which is the best position for observing, and from this it must never be moved until the equal altitude or other observations are See also:complete. For observations on See also:shore the sextant should be mounted on a stand. In an improved form of stand, the bearing which carries the sextant is square, and the whole bearing revolving on a centre is controlled by a clamp and tangent screw. The counterpoise should exactly See also:balance the sextant, and they may be fitted to allow for See also:adjustment. A small spirit-level fixed on one of the arms of the sextant stand, and another level pivoting round the See also:pillar on the index See also:bar of the sextant carrying the microscope, working in a plane parallel to that of the instrument, and fixed by means of a set screw, are of use in placing the sextant exactly in the required position when observing faint stars. With the telescope pointing to the centre of the artificial horizon, the direct and reflected images of the sun at any convenient altitude are made to coincide. The levels are then adjusted and permanently fixed by their set screws. To observe a faint star, it is only necessary to set its- double altitude on the sextant, turn the instrument and the stand to bring the bubbles of their respective levels in the centre of their runs, and move the stand until the telescope points to the centre of the artificial horizon and in the direction of the star, when the direct and reflected images will be seen in the field. A small electric light fitted on the arm carrying the microscope, and worked by a dry See also:battery, enables the sextant to be read at See also:night. The artificial horizon in common use consists of a glass trough containing See also:mercury and protected from the See also:wind by a glass roof. The glass in the roof should be of the best quality, and the faces of each See also:pane of the trough accurately parallel. A new form of horizon consists of a shallow rectangular trough of See also:metal gilt. After cleansing the surface by wetting it with a few drops of dilute sulphuric See also:acid, a drop of mercury is rubbed on until the whole surface is See also:bright, when a very small quantity of amalgamated mercury added will form an even See also:horizontal surface. The dross is wiped off with a broad See also:camel-See also:hair See also:brush. In this shallow trough waves are killed almost instantaneously. The horizon is placed upon a stand, consisting of two See also:iron plates, the upper resting on the lower, supported by three See also:long large-headed screws, by means of which it can be levelled. If the stand is raised off the ground a See also:foot or so, on a See also:firm foundation, thus bringing the artificial horizon closer to the telescope, faint stars are more easily observed, and the See also:movement of the sextant necessary to keep the star in the field, owing to its motion in the heavens, will be lessened. A See also:lantern placed on the ground behind, or a little on one side of, the observer, and faintly showing on the artificial horizon, will sufficiently illuminate the wires of the telescope on a dark night. Adjustments.—The planes of both the index glass and the horizon glass should be perpendicular to the plane of the instrument, and they should also be parallel to one another when the vernier is set to zero. The line of collimation of the telescope must be parallel to the plane of the sextant. This adjustment, though less liable to alter than either of the others, should be examined from time to time as follows: With the sextant mounted on a stand, move the index so as to See also:separate the direct and reflected images of a star by a distance nearly equal to the length of the parallel wires of the telescope, and turn the eyepiece until, the direct image of the star coinciding with one extremity of the See also:wire, the reflected image coincides with the other extremity; the wires will then be parallel to the plane of the sextant. Select two bright stars and make a coincidence of the reflected and direct images on the See also:middle of one wire, and then on the middle of the other. If the two readings agree, the adjustment is correct; if not, the adjusting screws in the collar of the up and down piece must be moved' until the coincidence is exact. " Centring error " is very important, but cannot be corrected. In an indifferent instrument it may be sufficient to vitiate the result of any observations on one side only of the See also:zenith. It arises from the eccentricity of the centres of the index arm and of the arc, and varies with the angle measured, being generally greater as the angle in-creases; but the index arm becoming See also:bent, or any part of the See also:frame receiving a See also:blow which alters its shape, the flexure of the instrument from varying temperature, and defective See also:graduation, will all produce errors which it is generally impossible to disentangle, and they are all included in the one correction for centring. This correction is found by comparing the angle measured by the sextant (corrected for index error) with the true angle. The most accurate method, because it employs a large number of observations for the same or nearly the same angle, is by observations of pairs of circum-See also:meridian stars in the artificial horizon at various altitudes. Double the difference between the resulting See also:latitude by each star and the mean latitude will be the centring error for an angle equal to the double altitude of that star, that is, the angle actually measured by the sextant, index error being ascertained and applied before working out. Measurement of the angles between stars, compared with their calculated apparent distance, is another method. At See also:Kew See also:Observatory (See also:National See also:Physical Laboratory) the centring error is determined for certain angles by fixed collimators. Including, as it does, errors from so many causes, the correction does not remain perfectly steady, and it should be ascertained from time to time. In a See also:good sextant the error should not exceed one See also:minute over the whole of the arc. Additional information and CommentsThere are no comments yet for this article.
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