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Horizontal Distance Measurement

Horizontal Distance Measurement. Tape Odometer Subtense Bar Stadia EDM. Distance Measurement. Devices and accuracy:. Older technologies “ quick look” Pacing : 1:50 Optical rangefinders: 1: 50 Odometers: 1:200 Tacheometry / stadia 1: 500 Subtense bar 1: 3000 Tapes: 1: 10,000.

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Horizontal Distance Measurement

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  1. Horizontal Distance Measurement Tape Odometer Subtense Bar Stadia EDM

  2. Distance Measurement Devices and accuracy: • Older technologies “ quick look” • Pacing : 1:50 • Optical rangefinders: 1: 50 • Odometers: 1:200 • Tacheometry / stadia 1: 500 • Subtense bar 1: 3000 • Tapes: 1: 10,000 • Modern Technology: • - Electronic Distance Measuring (EDM) devices: 2 +2 ppm

  3. Tape Measurement • Accuracy and speed considerations for civil engineers. • Sources of Errors: • Incorrect length of the tape • Temperature difference • Sag • Poor alignment • Tape not horizontal • Improper Plumbing

  4. Odometer and Subtense Bar • The idea of an odometer. • Subtense bar: a 2 m rod. • Distance H= cot(/2) m.

  5. Aiming Telescope • Subtense Bar • Distance H = cot(/2) m.

  6. L L /2 H /2 tan ( /2) = (L/2) / H H = (L/2) / tan( /2) If L = 2 m, then H = 1 / tan (/2) = cot (/2) Example: what is the horizontal distance between A and B if the angle  was 2? 

  7. Stadia • Chapter (16) • Principle of the Stadia: • Horizontal Distance = 100 rod interceptfor a horizontal line of sight and a vertical rod • Symbols: • (I) rod intercept, or stadia interval • (i) spacing between stadia hair • (f/i) = k = 100: stadia interval factor • C = (c + f) approximately 0, Stadia constant

  8. D = KI + C = 100 I, for horizontal sight

  9. H = 100 I cos2(α) V = 100 I sin(α) cos(α)

  10. Electronic Distance Measurement • Early types: • Transmit light, measure up to 25 miles • Transmit microwaves, measure up to 50 miles • Classification of EDM: • Electro-optical: laser or infra red reflected from passive prism or surfaces, the US has installed a prism on the moon. • Microwave: two positive units, GPS replaced them for most engineering applications such as hydrographic surveys

  11. Electromagnetic Spectrum

  12. Distance Computation • We only measure the phase angle shift (change) , different signals of wave length: 10 100 1000 10,000 m are sent. Each fraction provides a digit(s). • (Phase shift / 360)*wave length = non complete cycle length. • Example: how a distance 3485.123 is measured.

  13. Electronic Distance MeasurementEDM The Idea: To measure the distance between two points (A) and (B) the EDM on point (A) sends electromagnetic waves. The waves received at (B) are reflected back or resent to (A) by a device on (B). • Knowing the speed of electromagnetic waves in the air, the EDM computes the distance by measuring the time difference or the shift of the wave phase angle (will be explained in details later).

  14. Concept of the fraction

  15. 90 0 180 270 Phase Angle  Assume that  = 2 m If 1 = 80, it corresponds to a distance = (80/360) *  = 0.44 m If 2 = 135, it corresponds to a distance = (135/360) *  = 0.75 m If 3 = 240, it corresponds to a distance = (80/360) *  = 1.33 m

  16. Basic relationships • Distance = Velocity * Time = ((N *) + ) / 2 Where  is a fraction of wave length = (/360) * N is the number of full cycles, ambiguity? Since  is divided by 2, so is , we call /2 “effective wave length”

  17. Wave Modulation

  18. EDM Mounted on a theodolite

  19. A B C The angle between the rays A and C is double the angle between the two mirrors = 2 *90 = 180 Notice that the objects will look upside down, notice the box at the tail of the arrow

  20. Aiming at a prism through the telescope of a total station in a zoo!

  21. Reflectors (Prisms) Fully rotating prism Prism and sighting target Pole and bipod

  22. A reflector might include a single prism or a group of prisms • Reflectors can be a simple reflecting paper-sticker, they are called sheet-prisms, paper prism, or reflective sheeting. Very instrumental in construction sites and deformation monitoring of structures.

  23. EDM Accuracy • 3mm, and 3ppm is the most common. • Estimated error in distance = Ei2 + er2 + ec2 + (ppm X D)2 • Where: Ei and er are the centering errors of the instrument and the reflector, ec is the constant error of the EDM, and PPM is the scalar error of the EDM Example 6-5 page 156: if the estimates errors of centering the instrument and target were ± 3mm and ± 5mm respectively, the EDM had a specified error of ± (2mm +2ppm) what is the estimated error in measuring 827.329 m? Answer: ± 6.4 mm

  24. Prism constant consideration. • Total station Vs EDM. • Data collectors. • Prismless EDM: up to 100 m, can reach hard places, figure 6-14.

  25. Handheld laser measuring devices

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