Figure 12-4.—Slope reduction using vertical angle and slope distance.

Figure 12-4.—Slope reduction using vertical angle and slope distance. the theodolite, and the h.i. of the target. These differing heights of the equipment must be considered in the computations since they result in a correction that must be applied to the observed vertical angle before the slope distance can be reduced. Figure 12-4 illustrates the situation in which the slope distance and vertical angle are obtained from separate setups of an EDM and a theodolite. In the figure, the EDM transmitter, reflector, theodolite, and target are each shown at their respective h.i. above the ground. Angle a is the observed vertical angle and A. is the correction that must be calculated to determine the corrected vertical angle, ß, of the measured line. To reduce the slope distance, s, we must first make adjustment for the differing heights of the equipment. This adjusted difference in instrument heights (A_h.i.) can be calculated as follows: &h.i. = (h.i. reflector – h.i. target) - (h.i. EDM - h.i. theodolite). With Ah.i. known, you can now solve for that is needed to determine the corrected vertical angle. You can determine as follows: Now, solve for corrected vertical angle, ß, by using the formula: NOTE: The sign of is a function of the sign of the difference in h.i., which can be positive or negative. You should exercise care in calculating ß so as to reflect the proper sign of a, Ah.i. and . Finally, you can reduce the slope distance, s, to the horizontal distance, H, by using the following equation: To understand how the above equations are used in practice, let’s consider an example. Let’s assume that the slope distance, s, from stations A to B (corrected for meteorological conditions and EDM system constants) is 2,762.55 feet. The EDM transmitter is 5.52 feet above the ground, and the reflector is 6.00 feet above the ground. The observed vertical angle is–4°30´00". The theodolite and target are 5.22 feet and 5.40 feet above the ground, respectively. Our job is to calculate the horizontal distance. To solve this problem, we proceed as follows: The above example is typical of situations in which the slope distance and the vertical angle are observed using separate setups of an EDM and a theodolite over the same station. Several models of the modern 12-4