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Geospatial Data Accuracy: Metrics and Assessment

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Geospatial Data Accuracy: Metrics and Assessment Qassim A. Abdullah, Ph.D. Fugro EarthData, Inc. PDAD Special Session 39 : Sensor Calibration and Data Product Accuracy – PowerPoint PPT presentation

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Title: Geospatial Data Accuracy: Metrics and Assessment

1
Geospatial Data Accuracy Metrics and Assessment
Qassim A. Abdullah, Ph.D. Fugro EarthData, Inc.
PDAD Special Session 39 Sensor Calibration and
Data Product Accuracy ASPRS 2012 Annual
Convention March 22, 2012 Sacramento, CA
2
Sensors Technologies Today

1) Silicon Electronics made it possible to build
Large Format Aerial Mapping Camera
Medium Format Aerial Mapping Camera
Small Format Multi-purpose Camera
Special Application Mapping Sensors
Panoramic and Oblique Camera
Thermal Sensors
Multi-Spectral/Hyper-spectral Sensors
Space-based imaging Sensors
2) LiDAR
3) IFSAR

Image courtesy, Microsoft
3
Todays Geospatial Data Acquisition Very Complex
World
Panoramic
Push Broom
Oblique
Framing
LiDAR
4
Complex mapping processes

Complex technologies result in complex processes
How Complex are todays technologies?
A laser system generate millions of pulses per
second flown at speed of 200 300 knots
A space-based imaging Radar provide DEM of Earth
Terrain with vertical accuracy of 1 meter or
better
How about a full waveform digitization laser that
record object surface every 2 nano second?
Human skills and knowledge may sometimes be
lacking the proper understanding of such complex
technologies
Proper training is essential to solve such
complex puzzle
Not understanding the complex technologies leads
to errors in the acquired data

5
Types of Errors In Geospatial Data

FACT Errors can be minimized but can never be
eliminated
Gross errors or blunders
They can be of any size or nature, and tend to
occur through carelessness.
Random Errors
are the small differences between repeated
measurements of the same
quantity
often of the order of the finest division in the
measuring scale or
device
It can be caused by operator skill level
Random errors have very definite statistical
behavior and so can be dealt with by statistical
methods
It can be minimized but not eliminated
Systematic Errors
are those which we can be modeled mathematically
and therefore corrected
Examples GPS problems, camera calibration, earth
curvature, atmospheric effects, inaccurate lever
arm determination, etc.

6
Bias versus Random Errors
Random error
Systematic error
Date
7
Actions Required to Minimize the Occurrence of
Errors

Project planning stage
Follow manufacturers recommendation on operating
the sensor
Stay within the limits of the operation
parameters of the auxiliary systems such as GPS
and IMU
Data Processing stage
Sensor orientation determination
Do not compromise aerial triangulation or the
boresight processes
Plan extra check points within the project area
Make sure you have the correct calibration for
the system
Datum Confirmation
Make sure that you are using the right vertical
and horizontal datum
Avoid using older datums as they may not be that
accurate (i.e. NAD27, NAD83/86, WGS84(transit),
etc.)

8
Bias in Map Coordinates
Example of bias caused by confusing NAD83(86) and
HARN in Indiana SPC
9
Biased observations
Mean (Bias) -0.47 -0.01
StDEV 0.22 0.26
RMSE 0.52 ft 0.25 ft
An RMSE of 0.52 ft will cause a rejection to
ortho delivery mapped at 150 scale Allowed
RMSE according to ASPRS standard 0.50
Results after Bias removal
Mean (Bias) 0.00 0.00
StDEV 0.22 0.26
RMSE 0.21 0.25
10
What every user want beside pretty pictures?
Thermal Imagery GSD 50 cm Altitude 2,300 ft
11
User is interested in

Accurate Data
Discriminator
Check points fit
High definition/ high resolution
Clean Data
Discriminator
Matching mosaic lines (Both imagery and LiDAR)
Noise free Data (for LiDAR)
Decent radiometric quality (if optical imagery)
Manageable Data
Discriminator
Common file format
Optimized data size (i.e. lossless compression)

12
How Accuracy Standard should look like? The LiDAR
case

a) Classification According to LiDAR Point
Accuracy
1. Engineering class-I grade LiDAR data accuracy,
for products with
Horizontal accuracy of RMSEX RMSEY 20 cm or
better
Vertical accuracy of RMSEv 5 cm or better
2. Engineering class-II grade LiDAR data
accuracy, for products with
Horizontal accuracy of RMSEX RMSEY 30 cm or
better
Vertical accuracy of RMSEv 10 cm or better
3. Planning class-I grade LiDAR data accuracy,
for products with
Horizontal accuracy of RMSEX RMSEY 0.60 m or
better
Vertical accuracy of RMSEv 20 cm or better
4. Planning class-II grade LiDAR data accuracy,
for products with
Horizontal accuracy of RMSEX RMSEY 0.75 m or
better
Vertical accuracy of RMSEv 30 cm or better
5. General purpose grade LiDAR data accuracy, for
products with
Horizontal accuracy of RMSEX RMSEY 1.2 m or
better
Vertical accuracy of RMSEv 0.50 m or better
6. User defined Accuracy, for products that do
not fit into any of the previous five categories.

13
How Accuracy Standard should look like? The LiDAR
case

b) Classification According to LiDAR Surface
Definitions (quality)
1. Engineering class-I grade LiDAR data quality,
for a LiDAR surface with
a) Nominal post spacing of 0.30 m or less
2. Engineering class-II grade LiDAR data quality,
for a LiDAR surface with
a) Nominal post spacing of 0.70 m or less
b) To have optional break lines
3. Planning class-I grade LiDAR data quality, for
a LiDAR surface with
a) Nominal post spacing of 1.0 m or less
b) To have optional break lines
4. Planning class-II grade LiDAR data quality,
for a LiDAR surface with
a) Nominal post spacing of 1.5 m or less
b) To have optional break lines
5. General purpose grade LiDAR data quality, for
a LiDAR surface with
a) Nominal post spacing of 2.0 m or less
b) To have optional break lines
6. User defined quality, for products that do not
fit into any of the previous five

14
How Accuracy Standard should look like? The
Imagery case

Class I quality
To serve applications that requires very fine
details or high resolution. The standard can
specify the ground resolution for this class of
maps to be one of the following subclasses
IA GSD 2.5cm (1.0in.)
IB GSD 5.0cm (2.0in.)
IC GSD 7.5cm (3.0in.)
Class II quality
To serve applications that requires good details
or high resolution. The standard can specify the
ground resolution for this class of maps to be
one of the following subclasses
IIA GSD 10cm (4in)
IIB GSD 12.5cm (5.0in.)
IIC GSD 15cm (6in.).
Class III quality
To serve applications that requires acceptable
details or medium resolution. The standard can
specify the ground resolution for this class of
maps to be one of the following subclasses
IIIA GSD 20cm (8in.)
IIIB GSD 25cm (10.0in.)
IIIC GSD 30cm (12in.)

15
How Accuracy Standard should look like? The
Imagery case

While geometrical quality classes for
imagery-based map could look like this regardless
of the resolution of the products
Class-I Accuracy
To serve applications that require a high
horizontal and vertical accuracy as specified in
the following subclasses
IA RMSEx RMSEy RMSEv 3.8 cm (1.5in.)
IB RMSEx RMSEy RMSEv 7.6cm (3in.)
IC RMSEx RMSEy RMSEv 11.4cm (4.5in.)
Class-II Accuracy
To serve applications that require a medium range
of horizontal and vertical accuracy as specified
in the following subclasses
IIA RMSEx RMSEy RMSEv 15 cm (6in.)
IIB RMSEx RMSEy RMSEv 19cm (7.5in.)
IIC RMSEx RMSEy RMSEv 22.8cm (9in.)
Class-III Accuracy
To serve applications that require a horizontal
and vertical accuracy range as specified in the
following subclasses
IIIA RMSEx RMSEy RMSEv 23 cm (9in.)
IIIB RMSEx RMSEy RMSEv 38cm (15in.)
IIIC RMSEx RMSEy RMSEv 46cm (18in.)
Class-IV Accuracy
To serve all other products with resolution not
included in the three quality classes. Such
products should meet horizontal and vertical
accuracy according to the following formula