Page:EB1911 - Volume 26.djvu/363

 inferred either from the vertical angle included between two well-defined points on the staff and the known distance between them, or by readings of the staff indicated by two fixed wires in the diaphragm of the telescope. The difference of height is computed from the angle of depression or elevation of a fixed point on the staff and the horizontal distance already obtained. Thus all the measurements requisite to locate a point both vertically and horizontally with reference to the point Where the tachometer is centred are determined by an observer at the instrument without any assistance beyond that of a man to hold the staff.

The simplest system of tacheometry employs a theodolite without additions of any kind, and the horizontal and vertical distances are obtained from the angles of depression or elevation of Sublease two well-defined points on a staff at known heights from method. the foot, the staff being held vertically. In fig. 1 let T be the telescope of a theodolite centred] over the point C, and let AB be the staff held truly vertical on the ground at A. Let P and P′ be the two well-defined marks on the face of the staff,

. 1.

both of them at known heights above A, and enclosing a distance PP′=s between them. Let and  be the measured angles of elevation of P and P′, and let d be the horizontal distance TM of the staff from the theodolite, and h the height PM of P above T. Then since

P′M =d tan and PM =d tan ,

we have s=P′M-PM=d(tan -tan ).

Therefore &emsp; d = $s⁄tan − tan$; h= $s tan⁄tan − tan$.

If TC, the height of the rotation axis of the telescope above the ground, =q, and if AP =p, then the height of A above C is h−p+g. If, as is usually the case, a number of points are determined from one station of the theodolite, and hi, ha, ha, &e., be the values of 11 for the different points Al, AZ, Aa, &e., then the difference of level of A1 and A2 will be hg-hi, that of A1 and A3 will be h3−h1, and so on. To ensure the essential condition that the staff is held vertical, it is usually provided with a small circular spirit-level, and the staff-holder must always keep the bubble in the centre of its run. No graduation of the staff is required beyond two well-defined black lines across the white face at P and P′, but the marks can be; very usefully supplemented by wings fastened on the two } sides of the staff, having their tops at right angles to the staff, at the same height as the points P and P', and forming a continuation of the black lines. A convenient length for the staff is 12 ft., with the point P 2 ft. from the foot, and the point P' at the top of) the staff, so that A s=10 ft.

With the above arrangement the staff can easily be read with a 5-inch theodolite at half a mile distance. But while it is frequently very useful to determine approximately points a long way off, the determinations will not be nearly so accurate as those of near points. Thus suppose that the distance of the staff is d, and the intercept on the staff is's, and suppose that the personal and instrumental error is 5a. (ar being the angle subtended by's at the telescope); then since d = $s⁄tan$, $d(d)⁄d$ = −s$1+tan^{2}⁄tan^{2}$, or. .

da T S 5"/dz " § (S2+d2)

Therefore d, the distance error, is given by the equation d=−(s2+d2)/s. But at distances of 5 chains or more s2 will be very small compared with d2 and may be neglected, so that d =-51.112/5. Since may be considered as constant for all distances where the staff can be distinctly read, the distance error increases as the square of the distance. With small theodolites, where special care has not been given to the graduating and reading of the vertical circle, will probably amount to about 20″, At a quarter of a mile excellent work can be done. In carrying on a traverse line by this method with stations 10 or 12 chains apart, the theodolite being set up at points about midway between the stations, the probable distance error in a mile is about 3 ft., and the probable level error about 4 in. In 25 miles these probable errors would correspond to about 18 ft. and 20 in. respectively. This system of tacheometry is well adapted for distant readings, and from the great simplicity of the observations there is little likelihood of errors in the field. But the reduction work is rather heavier than is the case with some of the tachometers described below. Since the accuracy of the method depends entirely upon the accuracy with which the vertical angles are measured, it is advisable that the vertical circle should be as large as possible, very finely and accurately divided, and fitted with good verniers and microscopes.

In Eckhold's omnimeter the vertical circle of the theodolite is dispensed with, and a saving of reduction work is effected by reading, not the vertical angles themselves, but the tangents of the angles.

In the Ziegler-Hager tachograph the tangents are read not horizontally but vertically, and the arrangement is as follows:— In fig. 2 O is the axis of rotation of the telescope; mn is the axial line of a steel bolt, which carries on its top a knife-edge, on which the telescope rests by means of an agate plate. The bolt is carried by a slide in which it can be raised or lowered by a micrometer screw fitted with a graduated head. The slide plays between the vertical cheeks of a standard rigidly attached to the frame of the instrument, and it can be raised or lowered by a rack and pinion. The telescope, which rests on the knife-edge, follows the movement of the bolt. The slide carries on one side a vernier by which to read the divisions on a scale fixed to one of the vertical legs of the standard, and the zero point o of the scale is the point where the horizontal plane through O cuts the scale when the plane-table or upper plate of the theodolite is truly level. The scale is graduated in divisions, each of which is the T2, ¢@th part of the distance Oo, or h. The head of the micrometer screw which raises or lowers the steel bolt in the slide is graduated with a zero mark and with marks corresponding to a vertical movement of the knife-edge of h, h, &c. The instrument is used as follows:-Let AB be the surface of the ground, and BC a staff held vertically at B, and let CB be produced to meet the horizontal line through O in M. Let the head of the micrometer screw be turned till the zero division is exactly under the pointer. Let p be the zero division on the staff, and let the slide and bolt be raised by the rack and pinion movement till the axis of the telescope is directed towards p. Let v be the point where the line Op cuts mn, and let the tangent reading ov be taken on the scale. Then let the telescope be lowered by the micrometer screw in the slide till the division on the head of the screw marked I is exactly under the pointer; the knife-edge of the bolt has then been lowered through a distance 'vt equal to h/100. Let q be the point on the staff where the line Ot cuts it, and let the reading at q be taken. Then since the triangles between O and mn and O and CM are similar to each other, and vtt is th of Oo, therefore pq will be th of OM, or OM =100 × pq. This gives the horizontal distance of the staff from O, and the vertical distance pM of p above O is OM tan MOp=OM × ov/Oo, and since ov has been read in

. 2.

parts of which Oo contains 100, the distance pM is readily obtained. If the difference of elevation of B and A be required, the height pM must be reduced by 12B and increased by OA, both known quantities. By this arrangement the reduction work of the observations is rendered extremely simple, and can readily be performed ingfie held. The instrument is well adapted for use with the plane-table.

Tacheometers in which the horizontal distance of the staff from the telescope is deduced from the readings of the staff indicated by two fixed wires in the diaphragm of the telescope will S dl now be considered. In fig. 3 BC is a diaphragm fixed in a tube having fine horizontal wires at B and C. Let the end E of the tube be closed by a disk which has a minute hole at E, to which the eye can be applied. If P and D be the oints on a vertical staff at which the lines EB and EC are observed to cut the staff, so that the intercept PD is known, then from similar triangles ED = (EC/BC)PD, and since EC and BC are constant, ED varies as PD. If, for instance, PD has a certain observed value when the staff is held at a certain distance ED, and has exactly half that value when the staff is held at another distance ED′, then the distance