Basic%20Surveying

About This Presentation

Title:

Basic%20Surveying

Description:

Basic Surveying CE 263 – PowerPoint PPT presentation

Number of Views:273

Avg rating:3.0/5.0

Slides: 103

Provided by: Rug72

Category:

more less

Transcript and Presenter's Notes

Title: Basic%20Surveying

1
Basic Surveying

CE 263

2
Introduction to Surveying

Definition
Surveying is the science and art of determining
the relative positions of points above, on, or
beneath the earths surface and locating the
points in the field.

3
The work of the surveyor consists of 5 phases

Decision Making selecting method, equipment and
final point locations.
Fieldwork Data Collection making measurements
and recording data in the field.
Computing Data Processing preparing
calculations based upon the recorded data to
determine locations in a useable form.
Mapping or Data Representation plotting data to
produce a map, plat, or chart in the proper form.
Stakeout locating and establishing monuments
or stakes in the proper locations in the field.

4
2 Categories of Surveying

Plane Surveying surveying with the reference
base for fieldwork and computations are assumed
to be a flat horizontal surface.
Generally within a 12 mile radius the pull of
gravity is very nearly parallel to that at any
other point within the radius and thus horizontal
lines can be considered straight.
Geodetic Surveying surveying technique to
determine relative positions of widely spaced
points, lengths, and directions which require the
consideration of the size and shape of the earth.
(Takes the earths curvature into account.)

5
7 Types of Surveys

Photogrammetry mapping utilizing data obtained
by camera or other sensors carried in airplanes
or satellites.
Boundary Surveying establishing property
corners, boundaries, and areas of land parcels.
Control Surveying establish a network of
horizontal and vertical monuments that serve as a
reference framework for other survey projects.
Engineering Surveying providing points and
elevations for the building Civil Engineering
projects.

6
7 Types of Surveys

Topographic Surveying collecting data and
preparing maps showing the locations of natural
man-made features and elevations of points o the
ground for multiple uses.
Route Surveys topographic and other surveys for
long narrow projects associated with Civil
Engineering projects.
Highways, railroads, pipelines, and transmission
lines.
Hydrographic Surveying mapping of shorelines
and the bottom of bodies of water.
Also known as bathymetric surveying.

7
Brief History of Surveying

Surveying had its beginning in Egypt about 1400
BC
Land along the Nile River was divided for
taxation. Divisions were washed away by annual
floods.
ROPE-STRETCHERS Egyptian surveyors were created
to relocate the land divisions (measurements were
made with ropes having knots at unit distances).
Extensive use of surveying in building of
Egyptian monuments
Greeks expanded Egyptian work and developed
Geometry.
Developed one of the earliest surveying
instruments Diopter (a form of level).

8
Brief History of Surveying

Romans developed surveying into a science to
create the Roman roads, aqueducts, and land
division systems.
Surveyors held great power, had schools and a
professional organization
Developed several instruments
Groma cross instrument used to determine lines
and right angles
Libella A frame with a plumb bob used for
leveling
Chorobates 20 straight edge with oil in notch
for leveling
Middle Ages land division of Romans continued
in Europe.
Quadrans square brass frame capable of turning
angles up to 90 and has a graduated scale
developed by an Italian named Von Piso.

9
Brief History of Surveying

18th 19th Century in the New World the need
for mapping and marking land claims caused
extensive surveying, especially by the English.
1785 United Stated began extensive surveys of
public lands into one mile square sections
30 states surveyed under the U.S. Public Land
System (also called the Rectangular
System)
1807 United States Geological Survey founded to
establish an accurate control network and mapping
Famous American Surveyors George Washington,
Thomas Jefferson, George Rogers Clark, Abe
Lincoln and many more.

10
Brief History of Surveying

20th Century and Beyond As technology advanced,
population increased, and land value caused
development of licensure for surveyors in all
states.
Educational requirements for licensure began in
the early 1990s
Capable of electronic distance measurement,
positioning using global positioning systems,
construction machine control, and lidar
(scanning) mapping
Involvement in rebuilding of the infrastructure
and geographic information systems (GIS)
Shortage of licensed professionals is projected
well into the 21st century

11
Measurement of Distance

Linear measurement is the basis of all surveying
and even though angles may be read precisely, the
length of at least one line in a tract must be
measured to supplement the angles in locating
points.
Methods of measuring a
horizontal distance
Rough Measuring Pacing, Odometer readings,
Tacheometry (stadia), Taping, EDM, and GPS
Only the last three meet survey accuracy
requirements
Distance from stadia (High wire-Low wire) 100
Distance (ft)
More accurate measuring taping, EDM (1966), GPS
EDM and GPS are most common in todays surveys
In pacing, one establishes the of paces/100 by
counting the of paces over a pre-measured 300
line

12
Measurement of Distance

Taping applying the known length of a graduated
tape directly to a line a number of times.
2 Problems exist in Taping
Measuring the distance between two existing
points
Laying out a known distance with only the
starting point in place

13
Measurement of Distance

6 Steps of Taping
Lining in shortest distance between two points
is a straight line.
Applying tension rear chain is anchor and head
chain applies required tension.
Plumbing horizontal distance requires tape to
be horizontal.
Marking tape lengths each application of the
tape requires marking using chaining pins to
obtain total length.
Reading the tape the graduated tape must be
read correctly.
Recording the distance the total length must be
reported and recorded correctly.

14
Types of Chains and Tapes

Before the ability to make steel rods and bands,
sticks were cut into lengths of 16.5 (Rod) and
they were laid end to end to measure.
Gunters Chain
66 long with 100 link w/each link being 7.92
inches or 66 feet long
Developed by Edmund Gunter in 1600s in England
and made with individual wires with a loop at
each end connected
Chain had between 600-800 wearing surfaces which
with hard use would wear and cause chain to
elongate
Measurements were recorded in chains and links
7ch 94.5lk 7.945 ch 7.945 X 66/ch 524.37
1 chain 4 rods 80 chains 1 mile

15
Types of Chains and Tapes

Engineers Chain
Same construction as Gunters Chain, but each
link is 1.0 long and was used for engineering
projects
Surveyors and Engineers Tapes
Made of ¼ to 3/8 wide steel tapes in 100
200 300 lengths
Multiple types of marking and graduation
Available in chains, feet, and metric
Graduated
Throughout feet and tenths marked the entire
length
Extra foot feet marked the length of the tape
with additional foot at the 0 end graduated in
tenths and hundreds of the foot

16
Types of Chains and Tapes

Invar Tapes
Made of special nickel steel to reduce length
variations due to temperature changes
The tapes are extremely brittle and expensive
Used most of the time for standard comparison of
tapes
Cloth, Fiberglass, and PVC Tapes
Lower accuracy and stored on reels. Used for
measurement of 0.1 accuracy requirements
Accessories
Chaining Pins set of 11, used to mark the tape
lengths
Hand Level used to determine required plumbing
height
Plumb Bob used to transfer the mark from the
tape to ground
Tension Handle used to maintain correct tension
on tape

17
Taping (Field Process)

The line to be taped should be marked at both
ends
Keeps measurement on line
Rear chain person should keep the head chain
person on line
1 of line error/100 0.01 error in length
Applying Tension
Rear chainman is anchor and should hold 100 mark
over point
Tension is applied by head chain person
normally 12 to 30 pounds of pull
Tapes are standardized at 12 lbs., but greater is
utilized to compensate for sag

18
Taping (Field Process)

Plumbing
One end of tape is raised to maintain a
horizontal measuring plane. ONLY one end is
elevated
This allows measurements to be made on uneven
ground
If a high spot exists in center, break tape by
measuring to the top and then move forward to
complete the distance

19
Slope Measurements

Generally, measurements are made horizontally,
but on even, often man-made slopes the distance
can be measured directly on the slope, but the
vertical or zenith angle must be obtained.
Horizontal Distance sin Zenith Angle X Slope
Distance
Horizontal Distance cos Vertical Angle X Slope
Distance

20
Stationing

Starting point is 000 and each 100 is one
station ?700 from starting point is Station 700
If distance is 857.23 from starting point, it is
expressed as Station 857.23

21
Taping Error

Instrumental Error a tape may have different
length due to defect in manufacture or repair or
as the result of kinks
Natural Error length of tape varies from normal
due to temperature, wind and weight of tape (sag)
Personal Error tape person may be careless in
setting pins, reading the tape, or manipulating
the equipment
Instrumental and natural error can be corrected
mathematically, but personal error can only be
corrected by remeasure.
When a tape is obtained, it should either be
standardized or checked against a standard.
Tapes standardized at National Bureau of
Standards in Maryland
Standardized at 68 degrees F and 12 lbs. tension
fully supported.

22
Tape Error Correction

Measuring between two existing points
If a tape is long, the distance will be short,
thus any correction must be added
If tape is short, the distance will be long, thus
any correction must be subtracted
If you are setting or establishing a point, the
above rule is reversed.
Generally can correct for tape length,
temperature, tension, and sag, but tension and
sag are negated by increasing tension to
approximately 25 30 lbs.

23
Error in Taping

Tape Length Correction per foot Error in
100/100
If tape was assumed to be 100.00 but when
standardized was found to be 100.02 after
distance measured at 565.75
then Correction (100.02-100.00)/100.00
0.0002 error/ft
565.75 X .0002/ 0.11 correction and based
upon rule, must be added, thus true distance
565.86
If tape had been 99.98 then correction would be
subtracted and true distance would be 565.64

24
Error in Taping

Temperature Tapes in U.S. are standardized at
68?F the temperature difference above or below
that will change the length of the tape
Tapes have a relatively constant coefficient of
expansion of 0.0000065 per unit length per ?F
CT 0.0000065(Temp (?F)-68) Length
Example Assume a distance was measured when
temperature was 30F using a 100 tape was
872.54 (68 30) X 0.00000645 X 872.54
0.21 error tape is short, thus
distance is long, error must be subtracted and
thus 872.54 0.21 872.33
(note temperature difference is absolute
difference)

25
Surveying Metric Conversion

1 Survey Foot 1200 / 3937 meters
1 Meter 3937 / 1200 Survey Feet

26
Transit

Transit is the most universal of surveying
instruments primary use is for measurement or
layout of horizontal and vertical angles also
used to determine vertical and horizontal
distance by stadia, prolonging straight lines,
and low-order leveling.
3 Components of the Transit
Alidade Upper part
Horizontal limb Middle part
Leveling-head assembly Lower part

27
Transit

Alidade (upper part)
Circular cover plate w/2 level vials and is
connected to a solid conical shaft called the
inner spindle.
Contains the vernier for the horizontal circle
Also contains frames that support the telescope
called STANDARDS
Contains the vertical circle and its verniers,
the compass box, the telescope and its level vial

28
(No Transcript)
29
(No Transcript)
30
Transit

Horizontal Limb (middle part)
This is rigidly connected to a hollow conical
shaft called the outer spindle (which holds the
inner spindle)
Also has the upper clamp, which allows the
alidade to be clamped tight
Also contains the horizontal circle

31
(No Transcript)
32
Transit

Leveling-Head Assembly (lower part)
4 leveling screws
Bottom plate that screws into tripod
Shifting device that allows transit to move ¼ to
3/8
½ ball that allows transit to tilt when being
leveled
The SPIDER 4-arm piece which holds the outer
spindle
Lower clamp allows rotation of outer spindle

33
(No Transcript)
34

Telescope Similar to that of dumpy level, but
shorter
Parts objective, internal focusing lens,
focusing wheel, X-hairs, eyepiece

Scales horizontal plate or circle is usually
graduated into 30 or 20 spaces with graduations
from 0? to 360? in both directions
Circles are graduated automatically by machine
and then scanned to ensure accuracy
They are correct to with in 2 of arc

35
Verniers

Least count Lowest of reading possible
determines accuracy
Least Count (Value of smallest division on
scale)/( of divisions on vernier)

Scale Graduation Vernier Divisions Least Count
30 30 1
20 40 30
15 45 20
10 60 10
36
(No Transcript)
37
Verniers

3 Types of Verniers
Direct or single vernier reads only in one
direction must be set with graduations ahead of
zero
Double vernier can be read clockwise or
counterclockwiseonly ½ is used at a time
Folded vernier avoids a ling vernier plate
½ of the graduations are placed on each side of
the index mark
Use is not justified because it is likely to
cause errors

38
Verniers

The vernier is always read in the same direction
from zero as the numbering of the circle, i.e.
the direction of the increasing angles
Typical mistakes in reading verniers result from
Not using magnifying glass
Reading in the wrong direction from zero, or on
the wrong side of a double vernier
Failing to determine the least count correctly
Omitting 10, 15, 20, 30 when the index is
beyond those marks

39
(No Transcript)
40
Properties of the Transit

Designed to have proper balance between
Magnification and resolution of the telescope
Least count of the vernier and sensitivity of the
plate and telescope bubbles
Average length of sight of 300 assumed in design
Specifications of typical 1 gun
Magnification 18 to 28X
Field of view - 1? to 1?30
Minimum focus 5 to 7
X-hairs usually are with stadia lines above and
below
The transit is a repeating instrument because
angles are measured by repetition and the total
is added on the plate
Advantages of this
Better accuracy obtained through averaging
Disclosure of errors by comparing values of the
single and multiple readings

41
Handling the Transit

Hints on handling and setting-up the transit
Pick up transit by leveling head and standards
When carrying the transit, have telescope locked
in position perpendicular to the leveling head
with objective lens down
When setting-up, keep tripod head level and bring
plumb bob to within ¼ of point to be set over,
then loosen leveling screws enough to enable you
to move transit on plate, then move transit until
it is over the point

42
Operation of Transit
A
B
C

9 Steps
Set up over point B and level it. Loosen both
motions
Set up the plates to read 0? and tighten the
upper clamp. (Upper and lower plates are locked
together)
Bring Vernier to exactly 0? using upper tangent
screw and magnifying glass.
Sight on point A and set vertical X-hair in
center of point, by rotating transit
Tighten the lower clamp and entire transit is
locked in
Set X-hair exactly on BS point A using the lower
tangent screws. At this point the vernier is on
0?00 and the X-hairs are on BS

43
Operation of Transit
A
B
C

Loosen the upper clamp, turn instrument to right
until you are near pt. C. Tighten the upper
clamp
Set vertical X-hair exactly on pt. C using the
upper tangent screw.
Read ? on vernier
If repeating ?, loosen lower motion and again BS
on A (using only lower motion), and then loosen
upper motion to allow ? to accumulate.
If an instrument is in adjustment, leveled,
exactly centered, and operated by an experienced
observer under suitable conditions, there are
only 2 sources for error.
Pointing the telescope
Reading the plates

44
Transit Field Notes
1d? Mean ?
0?-90? (4d?)?4
90?-180? (4d? 360) ? 4
180?-270? (4d? 720) ? 4
270?-360? (4d? 1080) ? 4

Use longest side for backsite

45
TOTAL STATIONS
46
TOTAL STATION SET UP

WHEN TOTAL STATION IS MOVED OR TRANSPORTED, IT
MUST BE IN THE CASE!!!!!!!!
ESTABLISH TRIPOD OVER THE POINT.
OPEN THE CASE AND REMOVE TOTAL STATION, PLACING
IT ON THE HEAD OF THE TRIPOD AND ATTACH SECURELY
WITH CENTER SCREW.
CLOSE THE CASE.
GRASP TWO TRIPOD LEGS AND LOOK THROUGH THE
OPTICAL PLUMB, ADJUST THE LEGS SO THAT BULLSEYE
IS OVER THE POINT (KEEP THE TRIPOD HEAD AS LEVEL
AS POSSIBLE).
UTILIZING THE TRIPOD LEG ADJUSTMENTS, LEVEL THE
TOTAL STATION USING THE FISH-EYE BUBBLE.
LOOSEN THE CENTER SCREW TO ADJUST THE TOTAL
STATION EXACTLY OVER THE POINT IF NEEDED.
COMPLETE LEVELING THE TOTAL STATION USING THE
LEVEL VIAL.
CHECK TO MAKE SURE YOU ARE STILL ON THE POINT.

47
TURNING ANGLES WITH TOTAL STATION

SIGHT ON THE BACKSIGHT UTILIZING THE HORIZONTAL
ADJUSTMENT SCREW.
ZERO SET THE INSTRUMENT (THIS PROVIDES AN
INNITIAL READING OF
0 SECONDS.
LOOSEN TANGENT SCREW AND ROTATE INSTRUMENT TO
FORESIGHT.
TIGHTEN TANGENT SCREW AND BRING CROSS HAIR EXACT
ON TARGET WITH ADJUSTMENT SCREW.
READ AND RECORD ANGLE AS DISPLAYED.
TO CLOSE THE HORIZON
SIGHT ON FORESIGHT POINT FROM ABOVE AND ZERO SET
INSTRUMENT.
ROTATE TO FORMER BACKSIGHT AND ADJUST INSTRUMENT
TO EXACT.
READ AND RECORD ANGLE AS DISPLAYED.
ANGLE FROM DIRECT AND INDIRECT SHOULD EQUAL 360
DEGREES.

48
TOTAL STATION DISTANCE MEASUREMENT

POINT THE INSTRUMENT AT A PRISM (WHICH IS
VERTICAL OVER THE POINT.
PUSH THE MEASURE BUTTON AND RECORD THE DISTANCE.
YOU CAN MEASURE THE HORIZONTAL DISTANCE OR THE
SLOPE DISTANCE, IT IS IMPORTANT THAT YOU NOTE
WHICH IS BEING COLLECTED.
IF YOU ARE MEASURING THE SLOPE DISTANCE, THE
ZENITH ANGLE MUST BE RECORDED TO ALLOW THE
HORIZONTAL DISTANCE TO BE COMPUTED.
IF YOU ARE COLLECTING TOPOGRAPHIC DATA WITH
ELEVATIONS, IT IS IMPORTANT THAT THE HEIGHT OF
THE INSTRUMENT AND THE HEIGHT OF THE PRISM BE
COLLECTED AND RECORDED.
THIS CAN ALSO BE SOLVED BY SETTING THE PRISM
HEIGHT THE SAME AS THE INSTRUMENT HEIGHT.

49
TOTAL STATION RULES

NEVER POINT THE INSTRUMENT AT THE SUN, THIS CAN
DAMAGE THE COMPONENTS OF THE INSTRUMENT AS WELL
AS CAUSE IMMEDIATE BLINDNESS.
NEVER MOVE OR TRANSPORT THE TOTAL STATION UNLESS
IT IS IN THE CASE PROVIDED.
DO NOT ATTEMPT TO ROTATE THE INSTRUMENT UNLESS
THE TANGENT SCREW IS LOOSE.
AVOID GETTING THE INSTRUMENT WET, IF IT DOES GET
WET, WIPE IT DOWN AND ALLOW TO DRY IN A SAFE AREA
BEFORE STORAGE.
BATTERIES OF THE TOTAL STATION ARE NICAD AND THUS
MUST BE CHARGED REGULARLY. AT LEAST ONCE PER
MONTH, THE BATTERY SHOULD BE CYCLED.
CARE SHOULD BE TAKEN AT ALL TIMES, THESE UNITS
ARE EXPENSIVE (8,000 - 45,000)

50
Angles and Determination of Direction

Angle difference in direction of 2 lines
Another way of explaining is the amount of
rotation about a central point
3 kinds of Horizontal angles Exterior (? to
right) Interior Deflection
To turn an angle you need
A reference line
Direction of turning
Angular distance
Angular Units
Degrees, minutes, seconds (sexagesimal system)
Circle divided into 360 degrees
Each degree divided by 60 minutes
Each minute divided into 60 seconds
Radians
1 radian 1/2? of a circle 0.1592360
57?1744. 8
Grads (Centesimal System) now called Gon
1/400 of a circle or 0?5400 (100 gon 90?)

51
Angles and Determination of Direction

Angles turned in field must be accurate 3X
least count is max. error
Check 1 Close horizon when turning
If traverse closes sum of the interior angles
should equal the sum of
(N-2)X180, N Number of sides
3 angles (3-2) 180 180?
4 angles (4-2) 180 360?
8 angles (8-2) 180 1080?
25 angles (25-2) 180 4140?
If an exterior angle exists, subtract it from 360
to obtain the interior ?
Angular closure should be checked before leaving
the field

52
Angles and Determination of Direction

If angular adjustment does not divide out
equally
Do not go to decimal unless instrument reads to
decimal
Observe field notes for angles with poor closure
or where problems turning angles existed. Apply
excess to these angles evenly.
If unable to view field notes or no apparent
source, generally apply excess to angles with
shortest sides
Bearings/Azimuths
Bearing of a line is the acute horizontal angle
between a reference meridian (North and South)
and a line
Azimuth of a line is the horizontal angle
measured from the North meridian clockwise to the
line

53
Example
M
N
L
P
Q
54
Angles and Determination of Direction
4 Point Comparison 4 Point Comparison 4 Point Comparison
Bearing Azimuth
1. Numeric Value 0-90? 0-360?
2. Method of Expressing 2 letters number Number only
3. Direction Clockwise counterclockwise Clockwise
4. Position of 0 point North and South North
It is always very important to have your field
sketch properly oriented
55
Angles and Determination of Direction

Rectangular Coordinates
Totally based on computation of right triangle
North South Movement Latitude D X cos A
East West Movement Departure D X sin A
Latitude running North are , South are
Departure running East are , West are

56
Angles and Determination of Direction

Basic Procedure
Determine Latitude and Departure
Sum Lat. and Departure to calc. closure
Obtain balanced Lat. and Dept. (Compass Rule)
Determine coordinates
Once rectangular coordinates are known on point,
their exact location is known with respect to all
other points in the network

57
Example
B
47-28-00 483.52
F
99-39-30 421.97
279.33 320-42-00
392.28 188-27-30
A
E
26-16-30 452.66
C
236-27-00 886.04
D
58
Angles and Determination of Direction

Balancing Methods
Compass Rule (Bowditch) Used when accuracy of ?
and length measurement is equal
(Error Lat./Perimeter length) X Distance
Latitude Correction
(Error Dept./Perimeter length) X Distance
Departure Correction
Transit Rule Used if angles are more accurate
than distances (more accurate direction)
Correction Latitude (Side) (Lat. Side/Sum all
Lat.) X Lat. error
Correction Departure (Side) (Dept. Side/Sum all
Dept.) X Dept. error
Crandall Method Used when larger random error
exists in linear measurements that angular.
Directional adjustments from balancing are held
fixed and distances are balanced by a weighted
least squares procedure
Least Squares Based on the theory of
probability. Angular and linear adjustments are
made simultaneously. Hand methods are long and
complex ?not often done. Computer adjustment
through existing software make it feasible, which
is why it is often used today

59
Area, Inverse, Intersection

Once rectangular coordinates are established on
all points, the relationship to all other points
is known. You can
Determine area of all or any portion
Determine length and direction between any 2
points
Locate new points by intersection

60
Area, Inverse, Intersection

Area Method is area by cross multiplication
Using example from traverse lecture
NA X EB NB X EC NC X ED ND X EE NE
X EF NF X EA Sum N
EA X NB EB X NC EC X ND ED X NE EE X NF
EF X NA Sum E
Difference in Sums/2
Square feet
Square feet/43560 Acres

A 10000.0000 5000.0000
B 10326.7981 5356.3614
C 9938.7277 5298.7122
D 9448.9156 4560.3990
E 9854.7405 4760.8417
F 10070.8565 4583.9559
A 10000.0000 5000.0000
Sum N 294,119,678.8 Sum E 293,663,353.6 456,3
25.2 / 2 228,162.6 ft2 5.24 Ac?
61
Area, Inverse, Intersection

Example Determine Area of A, D, E, F, A

A 10000.0000 5000.0000
D 9448.9156 4560.3990
E 9854.7405 4760.8417
F 10070.8565 4583.9559
A 10000.0000 5000.0000
N 186,116,759.8 E 185,971,439.3 145,320.5 /
2 72,660.25 ft2 1.67 Ac ?
62
Area, Inverse, Intersection

Inverse With known coordinates of any two
points on a system, you find the distance and
direction between the two
C 9938.7277 5298.7122
D 9448.9156 4560.3990
489.8121 738.3132
To find the Inverse between 2 Points
Find difference in N E of coordinates
Plot
Use point you are going from 1st
Plot longest side 1st
Determine length using Pythagorean (a2 b2 c2)
Determine reference direction
Determine local ? using tan A a/b
Determine line direction

63
Area, Inverse, Intersection

Example Determine direction and distance D-A

D 9448.9156 4560.3990 A 10000.0000
5000.0000 551.0844 439.6010
64
Area, Inverse, Intersection

Intersection Determination of unknown point
location with directions from two points known
Determine difference in coordinates
Plot points and line projections
Set up dual formulas (as Latitude and Departure)
Solve for length
Compute coordinate as sideshot

C 9938.7277 5298.7122 D 9448.9156 4560.3990
489.8121 738.3132
65
Area, Inverse, Intersection

Example What are the coordinates of the point
of intersection of line C-F and D-A.
Azimuth D-A 38?3446.
Coordinates of D N 9448.9156, E 4560.3990

C 9938.7277 5298.7122 F 10070.8565
4583.9559 132.1288 714.7563
66
Horizontal and Vertical Curves

Horizontal curves are the basis for most Right of
Ways
Go through formulas
Angle at PC and PT are always 90?
Given any 2 elements T, L, C, R, D the remainder
can be completed
Example Horizontal curve, PC STA 20100
D 36?1500
R 1200.00
T
L
C
Seg
PI STA
PT STA

67
Horizontal and Vertical Curves

Vertical Curves Two major methods used to
calculate vertical curves Tangent offset and
Equation of Parabola
Information needed
Grade or slope on each side of curve
Elevation and station of PVI
Curve length (Horizontal distance PVC PVT)

68
Horizontal and Vertical Curves

Tangent Offset Method
Procedure
Compute the elevation of the PVC and PVT
Compute the elevation of Chord midpoint
Compute offset to curve at midpoint
Determine total number of stations covered
Determine tangent elevations at stations
Compute curve offset at stations
Combine data and determine vertical curve
elevations

69
Horizontal and Vertical Curves

Equation of Parabola Method
Equation r g2 - g1 / L
g1 initial grade
r change in grade/sta.
g2 final grade
L length of curve in stations
Procedure
Compute PVC and PVT elevations
Calculate total change in grade/station
Insert data to chart and compute final curve
elevations
To find the elevation at the high point or low
point,
find the station at which it fall and include
that
station in the elevation computations
The equation gives the distance from the PVC in
stations

70
Leveling

Leveling is the determination of the elevation of
a point or difference between points referenced
to some datum
Terms
Datum any level surface to which elevations are
referenced
Mean Sea Level (MSL) the average height of the
surface of the sea for all stages of the tide
over a 19 year period at 26 tide stations along
Pacific, Atlantic and Gulf
National Geodetic Vertical Datum nationwide
reference surface for elevations throughout the
U.S. made available by National Geodetic Survey
(NGS), based on 1929 adjustment.
Benchmark relatively permanent object bearing a
marked point whose elevation above or below an
adopted datum.

71
Leveling

Most often Mean Sea Level is used
MSL varies along the coasts
Pacific is almost 2 higher than Atlantic and
Gulf
U.S. System National Geodetic Vertical Datum of
1929
Has been used as reference for extensive network
of BMs
BMs are periodically adjusted as to elevation
Best to check with USGS or NGS for current
elevation of a BM and also best to check between
two known BMs to verify elevation difference.

72
Leveling

The level surface parallels the curvature of the
earth ?a level line is a curved line, normal (?)
at all points to plumbline
Line of sight is only normal at point of
instrument
A line with a sight distance of 1 mile using the
earths radius as 3959 mile, curvature change is
0.667 feet.
Refraction of line of sight of level is downward
by a small amount
The combined curvature refraction amounts for
short distances (normal sight dist. for levels)
are
100 0.0002
200 0.0008
300 0.0019
500 0.0052

Value is small ? for most instances can be
neglected
73
Leveling

Most common leveling instrument today is the
Automatic or Self-leveling level has an
internal compensator that automatically provides
a horizontal line of sight and maintains this
through gravity (prism hanging on pendulum)
Differential Leveling (Spirit Leveling) Most
common type today
Determine the difference in elevation using a
horizontal line of sight and readings on
graduated rod
Circuit must be closed on BM of origin or on BM
of equal accuracy
Process
Reading on point of known elevation (BS)
BS reading BM elevation HI
Reading on point of unknown elevation (FS)
HI FS elevation of new point

74
Leveling

Systematic Error in Leveling
Inclination of line of sight due to curvature of
earth and refraction generally very minimal due
to short sights
Inclination due to maladjustment of instrument
Both can be alleviated by equalizing length of BS
and FS legs
Changes in scale of rod due to temperature
Usually ignored except in very precise work
Would use same process as tape correction
Rod not held plumb
Minimized by carefully plumbing the rod or more
commonly known as Rocking the Rod and taking
the lowest reading

75
Leveling

Peg Test
Set 2 marks at 300 apart, also mark center point
in a relatively flat area
Set level at midpoint and take readings at each
end
Determine difference in readings (difference in
elevation)
Move level to one end and setup so that level is
just in front of rod on point
Read rod by looking backward through scope
(X-hair not visible), hold pencil on rod to
determine reading
Read rod at other end in normal manner
Difference in readings should equal 3
If values are not equal, there is error
Most instruments have adjustment screws
Adjust and repeat test as a check

76
Seven Basic Rules of Differential Leveling

Balance length of BS and FS (300 max)
Make sure gun is level and pendulum free
Turn through all BMs
Give complete description of BMs and TBMs
Have rod rocked
Make sure turning points are solid
Close all circuits on BM of same degree of
accuracy

77
Other Random Errors

Incorrect rod reading most common viewing foot
number above and recording it
Parallax having the X-hair not properly focused
Heat Waves limit shot lengths

78
Field Notes

STA BS HI FS ELEV
Sum BS Sum FS Difference of Elevation

79
Closure Error

Difference in measured elevation and know
elevation
Correction factor closure / turns
Error 0.09
Turns 12 Correction 0.0075 / turn
If TBMs set, break circuit into sections
Figure correction factor the same
Figure correction by taking CF X turns in
section

80
Precise Leveling

Precise Leveling Accuracy obtained by quality
of instruments and care taken in the field
High quality automatic levels are utilized
Level rods are equipped with rod level, rod shoe
(to allow better setting on BMs) scale (on rod)
is made of invar steel (not affected by temp
generally called Invar Rod)
Reading either taken by optical micrometer or a
process called 3-wire leveling is used (all 3
wire are read and averaged)
Optical micrometer line of sight deflected by
turning micrometer screw to read subdivision on
rod.
Rod division is read as normal then fractional
reading taken from micrometer screw, thus on
normal rod readings to 0.0001 are possible

81
Topographic Surveying

Topographic surveying is the process of
determining the positions, on the earths
surface, of the natural, and artificial features
of a given locality and of determining the
configuration of the terrain.
Planimetry location of features
Topography configuration of the ground
Both produce a topographic map which shows the
true distance between objects their elevations
above a given datum
Topos can be done by field methods, or by
photogrammetric methods. (Photo also requires
some field work)
Topo map is 1st step in a construction project

82
Topographic Surveying

Scale and accuracy Both depend on what used for
Method of Representing
Most common is Contour Line Imaginary line on
surface of the earth passing through points that
have equal elevation
Contour Interval Vertical distance between
lines
Topo map with contour lines shows elevation of
points on ground shapes of topographic features
(hills, etc.)
USGS Topo 10 or 20 contour intercal
Subdivision 2 or 4
Index Contour every 5th contour drawn heavier
on maps
Slopes X-sections can be obtained from contours

83
Topographic Surveying

Interpolating can find elevation of any point
or find contour line with known elevation of
point
Contour lines that close represent either a hill
or depression and can be represented as
Marks are called hatchures (used most in
depressions)

84
Characteristics of Contours

Each contour must close upon itself with within a
map or outside its borders a contour line
cannot end on a map except at the edge
Contours do not cross or meet except in caves,
cliffs vertical walls where they can meet
Contour lines crossing streams form Vs pointing
upstream
Contour lines crossing a ridge form Us pointing
down the ridge
Contour lines tend to parallel streams

85
Characteristics of Contours

Contour lines are uniformly spaced on uniform
slopes
Horizontal spacing between contour lines
indicated steepness of slope on ground
Contours are generally perpendicular to direction
of maximum slope
Contours can never branch into 2 contours of the
same elevation

86
Field Methods of Topos

Factors That Influence Method
Scale of map
Contour interval
Type of terrain
Nature of project
Equipment available
Required accuracy
Existing control
Extent of area to be mapped

87
Field Methods of Topos

Methods
Cross section railroad of highway
Trace contour drainage or impoundments
Grid small areas
Controlling point large area, plane table
Theodolite EDM - radial

88
Field Methods of Topos

Cross Section Method (Plus Offset)
Equipment used Transit, tape, and level
Establish horizontal control traverse between
control points stakes set at cross section
intervals
Run profile of traverse line
Take cross section
Locate planimetric features from traverse line

89
Field Methods of Topos

Trace Contour
Contour is by traverse
Establish elevation of each station
Contour elevation established and is then
followed by rodperson
Contour elevation is marked, then tied to
traverse line by plus-offset
Most accurate and expensive work
Elevation of reservoir water line
2 transit use

90
Field Methods of Topos

Grid Method
Establish baselines
Estimate grid of uniform size smaller grid
more accurate
Number grid
Shoot elevation at each point
Tie existing objects to grid points

91
Field Methods of Topos

Controlling Point Method (old and sketched in
field)
Determine position elevation of pre-selected
control points
Depends greatly on experience judgment of
people doing work
Required traverse of area (CPs)
Locations are made elevations obtained along
control points then intermittent topo sketched
in

92
Field Methods of Topos

Theodolite EDM (Radial)
Replaces tacheometry (stadia)
Establish control points (horizontal and
elevation)
Shoot locations and turn vertical angles
Used for large areas

93
Field Methods of Topos

Common mistakes in topo surveys
Improper selection of contour interval
Unsatisfactory equipment or field method for the
particular survey and terrain conditions
Insufficient horizontal and vertical control of
suitable precision
Omission of some topographic details

94
Mine Surveying

Points are on roof of mine
Reasons needed
Location in respect to boundaries
Location in respect to other shafts
Accurate maps (above and below ground)
Quantities
Equipment and Terms
Spad Beams that you hold plumb bob from
Bracket Mounting instrument from timber
supports
Trivet Tripod thats about 1 tall
Gyroscope Locate north
Laser vertical collimator located point at top
of vertical shaft platform
Plumb shaft Using piano wire then wiggle in at
bottom

95
Global Positioning Systems (GPS)

Developed in early 1980 s (Dept. of Defense)
Made up of 26 satellites (24 functioning 2
spares)
Each satellite is 20,000 km high (off Earths
surface)
Each satellite is in a fixed position
Minimum of 3 satellites needed, but 4-5 preferred
Need satellites at least 15 above horizon
Locate positions on Earth by distance-distance
intersection
Need 2-3 receivers (80-100K per system)
Most accurate with double occupancy (no other
checks)
Differential GPS one receiver on known point,
other receiver on unknowns

96
Global Positioning Systems (GPS)

Biggest advantage
Distance and direction in-between 2 points
without being seen
Downfalls/Limitations of GPS
Multipath bouncing off of walls of buildings
Blocked signals clouds, trees, etc.
Sunspot defraction from atmosphere
DOP (Delusion of Position) bad satellite
position
Set up error not set up exactly over point
(human error most common)

97
Global Positioning Systems (GPS)

Methods
Static observation time is at least an hour
Ideally set points in triangular fashion
Accuracy 1/10 million
RTK (Real Time Kinematic) stand for 30-60
seconds minimum
Base receivers transmission, does corrections,
sends corrections to receivers
Limitations limitation of transmitter signal

98
Geographic Information Systems (GIS)

GIS are computer programs that allow users to
store, retrieve, manipulate, analyze and display
spatial data
Spatial Data (Geographic data) any data that
represents information about the Earth
GIS components
Recent definitions of GIS suggest that is
consists of
Hardware (computer and operating system)
Software
Data
Human Operators and Institutional Infrastructure

Geographic/Spatial Non-Geographic/Aspatial/Attrib
ute
99
GIS Data Structures