{KomentoDisable}

K. Adjustment Methods Comparison

1. Introduction

Except for a pure least squares approach, the numeric adjustment methods described in Chapter E Section 1 are based on a general assumption of relative angle and distance accuracy.

The Transit Rule favors angles, the Crandall Method distances. The Compass Rule, the most common for simple traverses, treats angles and distances similarly.

This Chapter compares the three adjustment methods using a numerical example.


2. Common Nomenclature

L Length of a traverse side.
T Total distance surveyed; sum of all side lengths
Lat, Dep Latitude and departure of a side
eLat, eDep Latitude and departure errors for the traverse
cLat, cDep Latitude and departure correction for a side
ALat, ADep Adjusted latitude and departure of a side

 

The corrections for each method, while computed differently, are added to the unadjusted latitudes and departures, Equations K-1 and K-2.

Equations K-1 and K-2

3. Adjustment Equations Summary

a. Compass Rule

kLat, kDep  Adjustment constants

Equations K-3 and K-4

Equations K-5 and -6

b.  Transit Rule

kLat, kDep  Adjustment constants

Equations K-7 and K-8

Equations K-9 and K-10

 

c.  Crandall Method

Computations are a bit more involved because distances are adjusted by least squares. Topic XV. Least Squares Lite covers least squares adjustments in greater detail and ways to efficiently perform the complex computations which generally requires software. The equations presented here are based on those developed by Professor Crandall in the early 1900s, way before computers or even calculators (think slide rules). They are a relatively efficient way to manually perform the adjustment on a simple traverse.

k1, k2  Adjustment constants

Equation K-11

Equation K-12

Equations K-13 and K-14

 


4. Example

a. Data

The traverse shown below will be adjusted by all three methods.

Line Azimuth Length (ft) Lat (ft) Dep (ft)
AB 30°00'00" 365.79 +316.783 +182.895
BC 325°33'52" 354.52 +292.395 -200.474
CD 219°03'25" 645.84 -501.508 -406.939
DA 104°12'35" 437.64 -107.428 +424.250
  sums: 1083.79 +0.242 -0.268

The traverse misclosure is purposely large so adjustment differences are more easily seen.

For each adjustment

b. Compass Rule

Set up the adjustment constants using Equations K-3 and K-4.

Adjust the latitude and longitude of each line using Equations K-5 and K-6. Computations for line AB are:

Fully adjusted traverse

Line ALat (ft) ADep (ft) Azimuth Length (ft)
AB +316.734 +182.949 30°00'40" 365.775
BC +292.347 -200.421 325°34'02" 354.451
CD -501.594 -406.843 219°02'44" 645.847
DA -107.487 +424.315 104°12'54" 437.717
 sums: 0.000 0.000    

c. Transit Rule

Set up the adjustment constants using Equations K-7 and K-8.

Adjust the latitude and longitude of each line using Equations K-9 and K-10. Computations for line BC are:

Fully adjusted traverse

Line ALat (ft) ADep (ft) Azimuth Length (ft)
AB +316.720 +182.935 30°00'37" 365.756
BC +292.337 -200.429 325°33'54" 354.447
CD -501.607 -406.849 219°02'43" 645.861
DA -107.450 +424.343 104°12'34" 437.736
sums: 0.000 0.000    

d. Crandall Method

 Set up the adjustment constants using Equations X-11 and -12.

 Adjust the latitude and longitude of each line using Equations X-13 and -14. Computations for line AB are:

 Fully adjusted traverse

Line ALat (ft) ADep (ft) Azimuth Length (ft)
AB +316.783 +182.895 30°00'00" 365.752
BC +292.395 -200.474 325°33'52" 354.341
CD -501.508 -406.939 219°03'25" 645.855
DA -107.488 +424.250 104°12'35" 437.842
 sums: 0.000 0.000    

e. Comparison of adjusted values

(1) Distances
Line Original Compass Transit Crandall
AB 365.79 365.756 365.756 365.752
BC 354.52 354.447 354.447 354.341
CD 645.84 645.861 645.861 645.855
DA 437.64 437.736 437.736 437.842
 (2) Interior angles
Point Original Compass Transit Crandall
A 105°47'25" 105°47'46" 105°48'03" 105°47'25"
B 115°33'52" 115°33'21" 115°33'17" 115°33'52"
C 73°29'33" 73°28'42" 73°28'49" 73°29'33"
D 65°09'10" 65°10'11" 65°09'51" 65°09'10"

 

The Crandall Method puts all the corrections into distances so angles do not change from their original values. Because the Compass and Transit Rules modify the angles, they both also change the initial azimuth from 30°00'00"; the starting azimuth is unaffected with the Crandall Method.

If the initial direction must be held, then the direction of each line in the Compass and Transit Method adjustments should be rotated by a constant. The constant is the difference between the initial and adjusted directions of the first line. Even though rotating each line the same amount changes the latitudes and departures, traverse closure is not affected.


5. Summary

Of the three methods demonstrated here, the Compass Rule is the most commonly used for simple traverse adjustments. While the Crandall Method is a quasi-least squares approach, it's up to the user to decide how to deal with random angle errors. When traverses become more complex with cross-links, a true least squares adjustment is the best. See the XV. Least Squares Lite topic.

Traverse Adjustment is an Excel workbook which performs Compass, Transit, and Crandall Method adjustments on a loop traverse. It uses Visual Basic for Applications so be sure to have macros enabled.

 

 

 

Hits: 7997