Module 7/8

Question 1

LASER

Answer 1

is the acronym for Light Amplification by Simulated Emission of Radiation. Laser light is made of waves with the same wavelength, moving in
the same direction and in phase. These properties
of laser light are referred
as monochroma-city, collima-on
and coherence.

Question 2

3D laser scanners employ

Answer 2

Nd:YAG-­‐Neodymium-­‐doped

YttriumAluminum Garnet, Nd:Y3Al5O12.

Question 3

LIDAR

Answer 3

Light Detection and Ranging

Question 4

TLS

Answer 4

Terrestrial Laser Scanning

Question 5

ALS

Answer 5

Airborne Laser Scanning

Question 6

Terrestrial Laser

Answer 6

Reigl z420i (1000m range)
Nd:YAG 1064 nm lasers
• Laser rangefinder error = 4 mm at 1000m
• Laser backscatter off ground. Mirror and rotational stepper motors direct laser beam
• Distance = (c x Tflight)/2

Bare Ground Error Budget:
• Laser rangefinder error = 0.4 cm at 1000m
• GPS error ~1-4 cm+
• Registration Error = 2-5 cm
• Estimated RMSE
• 2.6-6.5 cm vertical

Question 7

TLS (LIDAR) for Civil Engineer Geotechnical

Answer 7

• Topographic design
• Landslides, Liquefaction,Lat.
Spread
• Accretion & Erosion
• Settlement measurement
• River Scour
• Excavation displacements
• Quay & sea walls
• Geomorphic change
detection

Question 8

TLS (LIDAR) for Civil Engineer Structural

Answer 8

• Structural displacements\ deflections \rotations
• Failure patterns
• Design vs. built differences
• Concrete deformations
• Modeling interior space/utilities.

Question 9

Typical Terrestrial LIDAR Setup

Answer 9

RTK-DGPS Base
Photogrammetric Camera
RTK-DGPS Rover
Benchmark
Laser

Question 10

3D Terrestrial Laser Scanner

Answer 10

1. Range finder electronics
2. Laser beam
3. Polygon mirror
4. Body
5. TCP/IP Ethernet interface
6. Laptop computer
7. Camera
8. USB interface
9. Software

A diagram for the RIEGL Z-SeriesTerrestrial 3D laser scanners.

Question 11

Solar Spectrum:

Answer 11

Non-­‐MonochromaAc
Non-­‐Collimated
Non-­‐Coherent

Question 12

Laser Light

Answer 12

Monochromatic (single wavelength)
Collimated (in the same direction)
Coherent (in phase)

Question 13

The electromagnetic spectrum

Answer 13

V=ƒ λ
The propagating velocity of electromagnetic waves (V), commonly known as the speed of light, is 299,792,458 m/sec in a vacuum. The relationship of V, λ, and f is the same for all wave types.

Question 14

The wavelength of peak power is predicted for a given target temperature by

Answer 14

Wien’s law:
λmax = 2,898,000 nm-­‐K/T
Human body 310°K (98.6°F, 37°C)
λmax ~ 9700 nm-­‐K/T

Question 15

The energy of a single photon an electromagnetic wave

carries is a function of frequency be calculated as:

Answer 15

E=hf = h V/λ
where h is Plank’s constant, 4.135 x 10-15 electron volts-sec or 6.626069 x 10-34 J-sec.
Electronic waves have wave length (λ), and frequency (f) and carry energy (E).

Question 16

Electromagnetic Radiation from Our LIDAR laser.

Answer 16

Our scanner has a Nd:YAG laser has a wavelength of 1064 nm. Calculate the frequency of the laser wave and the energy that the wave
carries (1 photon) in a vacuum.
ƒ =V/λ=299792458/1064•10^­‐9 m/cycle = 2.8•10^14 cycles/sec
E=hƒ=hV/λ
=6.626069•10-­‐34J-­‐s 2.8 •10^14 cycles/sec=1.867•10^­‐19J

=Energy that the wave carries (of one photon in a vacuum at 1064 nm and 2.8 10^14cycles/sec.

Question 17

Our Riegl z420i

Answer 17

is a low power 1064 nm

(infrared) Nd:YAG laser and eye safe.

Question 18

Reflector Registration

Answer 18

Registered from best
fit to common
reflectors.
500m

Question 19

Topnext RTN-DGPS Control for Positioning

Answer 19

Digital Photo Overlay
LIDAR 80° scanning window
GPS Controller
w/ Cellular Modem
CORS Network Differential

Question 20

TLS Processing Proc

Answer 20

A: Scan
B: Registration
C: Surface Modeling
TIN
Quantify +/or
Change
Detection

Question 21

Registration

Answer 21

Registering (Merging)
multiple scans eliminates
shadow zones
Picture--(2 false-colored scans in
white and red)

Question 22

Sometimes Tripods Do Not Work: Overcoming Obstacles and Shadows

Answer 22

Elevated (20 m) Terrestrial LIDAR

1) Downward view of terrain/vegetation
2) Improved grazing angle
3) Flat terrain max range = H / tan 3°-5°

Question 23

Registration by the Translation matrix

SOCS>PROCS>GLOCS

Answer 23

SOCS – Scanners
Own Coordinate System
PROCS –Project Coordinate System
GLOCS-­‐Global (Georeferenced) Coordinate System

Question 24

Scanner’s Own Coordinate System (SOCS)

Answer 24

the coordinate of the scanner’s raw data.

Question 25

Project Coordinate System (PRCS)

Answer 25

The coordinate system
defined by the user. We fix one of the scans as ‘Registered’, and adjust
all other scans to it’s coordinate system (SOCS–>PRCS).

Question 26

Global Coordinate System (GLCS)

Answer 26

is the Georeferenced coordinate system into which the entire project
is embedded (e.g. UTM, State Plane northings, eastings, elevation; (PRCS-->GLCS)

Question 27

2D Coordinate Transformation using Direction Cosines

Answer 27

• x’A=xΑcosα+yAsinα+c

* y’A=-­xΑsinα+yAcosα+d

Question 28

3D Coordinate Transforma1on – Euler Angles

Answer 28

The transformation matrix we seek is the product of the three sequential transformations (in the correct order) or T(2,1)=T(2,F’‘,F’)T(F’,1)

Question 29

Direction Cosines-­‐3D Coordinate Transformation

Answer 29

3D coordinate transformation is similar to 2D with an added dimension, the objective
is to find the coordinates of Point A in the X’Y’Z’ system if the coordinates of that
point in the XYZ system are known. Again from analytical geometry:
• x’ = x cos(x’, x) + y cos(x’, y) + z cos(x’, z) + c
• y’ = x cos(y’, x) + y cos(y’, y) + z cos(y’, z) + d
• z’ = x cos(z’, x) + y cos(z’, y) + z cos(z’, z) + e

This transformation has nine independent parameters

Question 30

Point cloud vs. Reflector Registration

Answer 30

RMSE=Root Mean Square Error= sqrt((z1,i-z2,i)^2/n)

For a large sample population of n, RSME^2=M^2+o(omega)^2
For large unbiased population, RMSE=o(omega)

Question 31

Comparison between Terrestrial and Airborne LIDAR

Answer 31

-­‐ Laser Rangefinder:
Optech ALTM 3100
-­‐ 1064nm w/integrated
IMU&GPS.
-­‐ Pre-­‐Trench Flight 1: Fixed wing at 900m (Airborne1,El Segundo, California)
-­‐ Post Trench Flight 2:
Helicopter at 210m
(Terrapoint, The Woodlands, Texas)

• Laser rangefinder error
= 2-­‐3 cm
• GPS error=5-­‐10cm
• IMU error=~9cm@900m

Vendors quoted RMSE
– 18cm vertical (95%CI)
– 0.3-­‐0.45m horizontal (1σ)

Question 32

Airborne systems

Answer 32

Airborne systems collect
overlapping swaths of data
Waveform based lidar is typical in airborne systems

Question 33

Residual, Mean of the residuals, sample dispersion

Answer 33

Ri=Residual=(zi-zknown,i)
M=mean of residual=sample bias= sum of Ri/n
o(omega)=sample dispersion=sqrt(sumof(Ri-M)^2/(n-1))

Question 34

Blind Comparison of Airborne and Terrestrial

LIDAR

Answer 34

• Terrestrial LIDAR had almost no bias with pre- and post-trench
Airborne LIDAR had negative bias in both pre- and post-trench
μ = -23.6 - -8.7 cm, and σ = 5.6 - 20.0 cm
(errors exceeded both vendors specifications)
• Terrestrial data had 1/4-1/10 mean error and 1/1.4-1/5 dispersion of airborne
data.
• Multi-epoch elevation change terrestrial residuals were 1/3 of airborne residuals.

Question 35

Index of Refraction

Answer 35

• The ratio between the propagation rates in a
vacuum and in atmosphere is the index of
refraction which can be expressed as follows:
• n=c/V
• where c is the speed of light in a vacuum and n
is the index of refraction. The value of n is
around 1.0003.

Question 36

Refraction

Answer 36

The LASER wavelength of an electromagnetic wave decreases as the propagation velocity drops. Since the wave energy does not change and the frequency remains fixed. This effects the estimation of range distance.

Question 37

Index of refraction

Answer 37

λo/λ = (c/ƒ)/(v/ƒ)=c/v=n

n=index of refraction
ƒ=frequency
c=speed of light in a vacuum
v=speed of light in air
λo = wavelength in a vacuum
λ=wavelength in air

Question 38

Temperature

Answer 38

1. The effect of temperature on the index of refraction is the most profound.
   For example, for a temperature change of 5 Cº from 10Cº to 15Cº, the corresponding change in
   the index is more than 5ppm.

Question 39

Minor effects on refraction: Atmospheric Pressure Humidity

Answer 39

The humidity has the least effect on the index of refraction.
For a 10 percent increase in humidity from 30 to 40 percent,
the change in the index is about 0.087 ppm when λ=0.915 μm

Question 40

Actual V, λ, and Error

Answer 40

n=c/V
λ =V/ƒ
t=Distance/V
DistanceError=Vt-­Distance(vacuum)

•Significant problem if the target distance is large.
•Understand how the
distance is being calculated.
•Be mindful of temperature.