Figure 7-3.—Lines of indirect levels.

Figure 7-2.—Difference in elevation in trigonometry leveling. Figure 7-3.—Lines of indirect levels. In figure 7-2, a transit is setup and leveled at A. The intersection of your line of sight with the rod (point C). rodman holds a rod on B. The instrumentman trains the Computing the DE consists of multiplying the measured telescope on C, which is an easily read value (usually a distance by the proper trigonometric function of the full foot) on the rod. With the telescope trained on C, the measured angle (sine, when slope distance (OC) is vertical angle (a) is read. Then either the horizontal measured; tangent, when horizontal distance (OD) is distance or the slope distance between the instrument measured). and rod is determined. Now one side and one angle of a The following paragraphs discuss typical situations right triangle (OCD) are known. From your knowledge that you will encounter in trigonometric leveling. You of trigonometry, you know that the other sides and angle will see in each of these situations the reamer in which can be computed. However, in trigonometric leveling, the computed DE is applied to determine the HI and you are concerned only with determining the length of required elevations. the side opposite the measured angle (side CD). The length of this side is the difference in elevation (DE). 1. DEPRESSION ANGLE BACKSIGHT (fig. As-you can see in figure between the height of 7-2, the DE is the distance 7-3, view A). The rod is on point B below the instrumerit. instrument (HI) and the The measured vertical angle (a) is a depression (minus) 7-3