Automated schemes are needed to classify multispectral remotely sensed data. Human intelligence is often required to correctly interpret images from satellites and aircraft. Humans suceed because they use various types of cues about a scene to accurately define the contents of the image. Consequently, it follows that computer techniques that integrate and use different types of information would perform better than single source approaches. This research illustrated that multispectral signatures and topographical information could be used in concert. Significantly, this dual source tactic classified a remotely sensed image better than the multispectral classification alone. These classifications were accomplished by fusing spectral signatures with topographical information using neural network technology. A neural network was trained to classify Landsat mulitspectral signatures. A file of georeferenced ground truth classifications were used as the training criterion. The network was trained to classify urban, agriculture, range, and forest with an accuracy of 65.7 percent. Another neural network was programmed and trained to fuse these multispectral signature results with a file of georeferenced altitude data. This topological file contained 10 levels of elevations. When this nonspectral elevation information was fused with the spectral signatures, the classifications were improved to 73.7 and 75.7 percent

Harston, Craig

Schumacher, Chris

English

NASA Technical Reports Server

N97-23368
Improved Image Classification with Neural Networks z//_. _/'
by Fusing Multispectral Signatures with Topological Data I ///J j.-
Craig Harston and Chris Schumacher
Computer Application Systems, Inc.
P.O. Box 251
Signal Mountain, TN. 37377
(615) 886-1419
(Fax) 886-7377
r
ABSTRACT
Automated schemes are needed to
classify multi-spectral remotely
sensed data. Human intelligence is
often required to correctly interpret
images from satellites and aircraft.
Humans succeed because they use
various types of cues about a scene
to accurately define the contents of
the image. Consequently, it follows
that computer techniques that
integrate and use different types of
information would perform better than
single source approaches.
This research illustrated that
multispectral signatures and
topographical information could be
used in concert. Significantly, this
dual source tactic classified a
remotely sensed image better than the
multispectral classification alone.
These classifications were
accomplished by fusing spectral
signatures with topographical
information using neural network
technology.
A neural network was trained to
classify Landsat multi-spectral
images of the Black Hills. Bands 4,
5, 6 and 7 were used to generate four
classifications based on the spectral
signatures. A file of georeferenced
ground truth classifications were
used as the training criterion. The
network was trained to classify
urban, agriculture, range and forest
with 65.7% correct. Another neural
network was programmed and trained to
fuse these multispectral signature
results with a file of georeferenced
altitude data. This topological file
contained i0 levels of elevations.
When this non-spectral elevation
information was fused with the
spectral signatures the
classifications were improved to
73.7% and 75.7%.
INTRODUCTION
Automated schemes are needed to
classify multi-spectral remotely
sensed data. For example, the
upcoming Earth Observing System (EOS)
will generate massive quantities of
data that must be managed quickly
(Dorfman, 1991; Short, 1991). Access
to the resulting data and information
should be quick and user friendly.
Campbell and Cromp (1990) call for a
user friendly system that is based on
user domain-specific knowledge and
goals. This concept requires that the
data system be based on object-
oriented storage and retrieval
procedures that incorporate
information about the image (Dorfman,
1991). Fekete has recommended a
sphere quadtree technique for
subdividing and relating spherical
IThis work was supported by the' National Aeronautics and
Administration (NASA) Contra_t #NAS13-435 w_.th the Stennis Space Center.
_'_ 151
Space
https://ntrs.nasa.gov/search.jsp?R=19920014125 2020-03-17T12:26:39+00:00Z
data into a data base. This technique
relies on the identification of image
contents such as coast lines.
If these recommendedata base-
information systems are to be based
on content and knowledge about the
data, then real time classification
algorithms will be required. Data
storage techniques, such as the
sphere quadtree (Fekekte) or object
oriented information, are based on
the contents of the image/data. Data
storage will depend on access codes,
indexes, or keys specific to the
content of data. These codes and
indexes would be determined as the
data arrives and prior to storage
into the data base. An accurate and
automated classification technique
would be the basis for determining
these indexes that will be used for
cataloging and filing data. Due to
the large quantity of data coming
from the EOS, this classification-
indexing and storage process should
occur in real time or near real time
to avoid building a backlog. Not only
will it be necessary to transmit and
store EOSdata efficiently, but also
EOS data should be categorized
somehow during the transmit or
storage process.
While EOSdata managementwill
be important, rapid or near real time
multispectral remotely sensed data
classification is important in its
own right. There are potential
satellite image applications that
depend on rapid access to
classification results. Imagesshould
be classified without the delay
associated with most processing
techniques. The results would be
transmitted to the user in a timely
fashion. This rapid classification
and delivery would support the
feasibility of manynewapplications.
For example, fishermen could respond
quickly to recent current shifts.
Short term illegal wild cat mining or
deforestation could be identified and
arrested. Natural disasters such as
oil spills could be monitored as they
progress.
Real time classification
techniques do not exist; however,
neural network technology promises to
allow us to automatically classify
imagesin real time. The technique is
simple yet can be deployed with
parallel neural processing integrated
circuits. These processors are
relatively cheap and available for
multispectral analysis (Harston,
Zhant & Stewart, 1991; Kagel, 1991).
Theneural network approach has
classified various remotely sensed
multispectral images (Campbell, Hill
& Cromp, 1989; Benediktsson, Swain &
Ersoy, 1990; Cromp, 1991; Harston &
Schumacher, 1991; Kulkarni, 1990;
Eberlein & Yates, 1991; Decatur,
1989). Decatur's work was with the
synthetic aperture radar (SAR) HH,
HV, and VV componentsof the return
at the L band (1.225 GHz) and the
others were with visual and infrared
bands. Someof their results can be
seen in Table III. While the results
compare well with statistical
classification techniques, better
performance is desirable. It was
hypothesized that fusion of spectral
signatures with additional
information might improve
performance.
Human intelligence is often
required to correctly interpret
images from satellites and aircraft.
Humans succeed because they use
various types of cues about a scene
to accurately define the contents of
the image. Consequently, it follows
that computer techniques that
integrate and use different types of
information would perform better than
single source approaches. Work to
date in our laboratory supports this
supposition (Harston, 1991 a, b & c).
This research illustrated that
multispectral signatures and
152
topographical information could be
used in concert. Significantly, this
dual source tactic classified a
remotely sensed image better than the
multispectral information alone.
These classifications were
accomplished by fusing spectral
signatures with topographical
information using neural network
technology.
METHOD
The data came from a Landsat
Multispectral Scanner (MSS) image of
the Black Hills. Thematic mapper (TM)
spectral bands 4, 5, 6 and 7 were
represented as intensity values from
0 to 255 in 512 by 512 byte image
files. Additionally, files of
elevation and ground truth data were
available. The ground truth showed
that broad contiguous areas were
assigned to single classifications.
There were 22 potential
classifications, which covered urban,
farm, range, forest, and water as
major groupings. The four classes of
data used in this study were urban,
farm, range, and forest. These and
the other data files were
georeferenced.
The type of neural network used
was the three layer feedforward
networks with one layer as the
hidden layer. The delta rule was used
to train the output layer and
backpropagation was used to train the
hidden layer. All work was done on
MS-DOS 386/486 VGA microcomputers and
the code was written in C.
One neural network was trained
to classify Landsat multi-spectral
images of the Black Hills. Bands 4,
5, 6, and 7 were used to generate
four classifications based on the
spectral signatures. These classes
included or collapsed several of the
classifications found in the ground
truth into urban, farm, range, and
forest categories. The file of
condensed georeferenced ground truth
classifications was used as the
training criterion. This network was
called the spectral signature
network.
Another neural network was
trained with the four bands of TM
data and a topography file of
altitude or elevation data. This
topological file contained i0 levels
of elevations. These images/files
were georeferenced to each other, and
the ground truth file was used for
training. This network was referred
to as the fusion network.
Training for both networks
consisted of hand picked samples from
the larger image. The experiment was
conducted twice, resulting in two
spectral signature networks and two
fusion networks. The second set of
networks was tested with additional
samples taken from the same image.
These samples were taken from
intersection points of a grid taken
at 50 pixel (horizontal) and 25 pixel
(vertical) locations on the upper
part of the image. There were 25 test
points taken from urban, farm, range,
and forest areas that resulted in
only one range and one urban testing
sample. This kind of grid sampling
and random sampling may be roughly
representative of the types of data
in the image but does not obtain
equal numbers of cases for each
category.
RESULTS
Both spectral signature
networks learned 65.7% of the
training sets (60,021 training trials
for the second network). The first
fusion network learned 73.7% of the
training set, and the second fusion
network learned 75.8% at 63,035
training trails. Further training
resulted in decreased levels of
performance.
The second set of networks,
both spectral and fusion, were tested
with other data taken from the
multispectral image. The spectral
signature network generalized to
these novel data points at 52%, and
the fusion network correctly
classified 60%of these test cases.
These results (see Table i for
results) were carefully reviewed with
the image in view. Sixteen percent of
the errors appeared to be correctly
classified. That is, the ground truth
did not appear to be correct from the
visual examination of the image.
Additionally, 4% of the errors were
not clear from the visual image, and
the ground truth classification could
be debated. The results improved 16%
for both the signature and fusion
network test results when the scores
were corrected for the obvious (not
the 4% border line) ground truth
errors.
Regardless of the corrections,
it is clear that the fusion of
altitude information with spectral
signatures improved the learning.
This improvement was 8% in the first
set of networks and 10% in the second
set of networks. Even the testing
results improved by 8% with the
second set of networks.
A detailed analysis of the
errors indicated that the greatest
number of errors came from
misclassified farm data. Keep in mind
that there were more test samples
from farm areas than from other
areas. The performance in each class
can be seen in Table If. There was
only one range test sample and that
one was misclassified. This resulted
in a 100% error rate for the range
class.
The fusion with elevation data
improved the farm scores from 60% to
80%. Unfortunately the forest
performance was decreased from 87.5%
to 75%. The test sample size was
small at 25 cases so interpretation
of the results may be limited. The
misclassified range sample was one of
the debatable or border line cases.
These results are also found in Table
If.
CONCLUSIONS
The use of altitude data with
the spectral signatures improved the
performance. This fusion of image and
topographic data was simple to do
with the neural networks. The
elevation data improved the farm land
classification but degraded the
forest classification to a lesser
extent. However, the results were
positive overall and suggest that
classification performance could be
further improved if other types of
data were included in the neural
classification process.
The initial impression that the
learning and test results were low
should be interpreted in relationship
to the results from similar
classifications. For example, as seen
in Table III, other types of
statistical classification are also
low (Benediktsson, Swain & Ersoy,
1990; Duda & Hart, 1973). In general,
the neural techniques performed
better, except with the multisource
technique that used information in
addition to the spectral data
(Senediktsson, Swain & Ersoy, 1990).
This multisource statistical
technique included Landsat MSS,
elevation, slope, and aspect data.
This additional data improved the
classification technique to 61%.
Clearly, this result argues for the
fusion with, or inclusion of,
additional cues, regardless of the
classification technique used.
Classification of raw spectral
data without any clean up is also
poor as seen in Table I with 55%
(Campbell, Hill & Cromp, 1989) and
52% or 60% in this study. Neural
154
studies often correct or select the
data in some way. Campbell, Hill, &
Cromp (1989) used only non-boundary
pixels for training. Homogeneous
fields were developed for training
and testing by Benediktsson, Swain,
& Ersoy, 1990. In the present case,
the classification was corrected by
visual inspection of the test cases.
Some of these selection or correction
procedures resulted in respectable
test scored at 70% (Campbell, Hill &
Cromp, 1990) and 76% in this study.
Given the improved
classifications by fusing non
spectral data with the spectral
signature, possibly other
supplementary information can be used
by the neural network system to
improve performance. A shadow file
might be used to improve the
classification of forests on both
sides of the mountain. In another
study, pixel patterns based on
brightness and texture were
classified within each MSS TM band
(Harston, 1991d) . These
classifications were fused with an
add it iona I neu ra I network t hat
resulted in improved performance.
Possibly, the texture, signature,
altitude, and other data can be fused
with neural technology to obtain even
higher test performance.
The potential for classifying
incoming Earth Observing System (EOS)
data in real time is genuine. See
papers authored by Short, Campbell,
Fekete, Dorfman, and Cromp at the
GSFC for a description of the
importance of this problem. As
indicated in our multi-spectral work
to date, meaningful results are
possible; however, higher levels of
performance may be possible. It seems
reasonable that more can be done with
multi-spectral data when additional
non-spectral information is
integrated with the spectral results.
Further work with seasonal, urban,
hazy, and cloudy images is needed.
Ultimately, a system that could
classify regardless of variations or
conditions could categorize incoming
data in real time. Such
categorizations would be useful for
the Intelligent Data Management (IDM)
project as a basis for defining,
cataloging, and referencing images
for a data base.
Acknowledgements: The data was
supplied by the Goddard Space Flight
Center. Thanks goes to Nick Short and
Semir Chettri at GSFC for their
assistance.
REFERENCES
Benediktsson, J.A., Swain, P.H. &
Ersoy, O.K., (1990). Neural
Network approaches versus
statistical methods in
classification of multisource
remote sensing data, IEEE
Transactions on Geoscience and
Remote Sensinq, 28,4, 540-551.
Campbell, W.J. & Cromp, R.F., (1990).
Evolution of an intelligent
information fusion system,
Photoqrammetric Enqineerinq and
Remote Sensinq, 56(6), 867-
870.
Campbell, W.J., Hill, S.E. & Cromp,
R.F., (1989). Automatic
labeling and characterization
of objects using artificial
neural networks, Telematics and
Informatics, 6,3/4, 259-271.
Cromp, R.F., (1991). Automated
extraction of metadata from
remotely sensed satellite
imagery, 1991ACSM/ASPRS/AUTO-
CARTO i0 Proceedinq.
Decatur, S.E., (1989). Application of
neural networks to terrain
classification, IJCNN, 1-283-
288.
Dorfman, E., (1991). Architecture of
a large object-oriented
database for remotely sensed
data, ACSM/ASPRS/Auto Carto I0
Conference, March, Baltimore.
Duda, R.O., & Hart, P.E., (1973).
Pattern Classification and
Scene Analysis, John Wiley &
155
Sons, NewYork.
Eberlein, S. & Yates, G., (1991).
Neural network-based systemfor
autonomous data analysis and
control, Proqress in Neural
Networks, (Ed. Omid Omidvar)
Vol. I, 25-55.
Fekete, G., Rendering and Managing
spherical data with sphere
quadtrees, available from
NASA/GSFC, Greenbelt, MD 20771.
Harston, C.T., (1991a). A Neural
Network systems Approach to
Image Processing, IEEE Int'l
Conf. on Sys., Man t and
Cybernetics, Oct. 13-16, 1539-
1544.
Harston, C.T., (1991b). Pattern
Identification with a
Computerized Neural Network,
IEEE Southeastcon '91,
Williamsburg, April 7-10, 935-
939.
Harston, C.T., (1991c). Spacial
classification and multi-
spectral fusion with neural
networks, Proceedinqs: ANNA'91
Analysis of Neural Network
Applications Conference, May
29-31, George Mason University,
76-82.
Harston, C.T. (1991d). The
integration of spacial and
Multi-spectral data with neural
networks, Intelliqent
Enqineerinq Systems Throuqh
Artificial Neural Networks,
(Eds. C.H. Dagli, S.R.T. Kumara
& Y.C. Shin), ASME Press, New
York, 435-440.
Harston, C.T. & Schumacher, C.,
(1991). Feature extraction and
fusion with spectral signatures
by neural networks, ( in
preparation ) .
Harston, C.T., Zhant, G. & Stewart,
D.W., (1991). Neural Network
Hardware, part of Phase I SBIR
final Report to NASA at the
SCC.
Kagel, J.H., (1991) . Hardware
implementation of a neural
network performing
multispectral image fusion.
SPIE's International Symposium
on Optical Engineering and
Photonics in Aerospace Sensing,
Technical Conference 1469,
April 1-5, Orlando.
Kulkarni, A.D. , (1991) . Neural
Networks for Pattern
Recognition, Proqress in Neural
Networks, (Ed. Omid Omidvar),
V.I, 197-219.
Short, N. (1991). A Real-time expert
system and neural network for
the classification of remotely
sensed data, 1991
ACSM/ASPRS/Auto-Carto i0
Proceeding, March, Baltimore,
MD.
TABLE I
NEURAL NETWORK TEA ! N I NO
AND TESTING RESULTS
EXPERXMENT Z •
TRZALS TRAZN TEST CORRECT
SPECTRAL NN 6S. 7R
FUSZON NN 73. 7X
mXPERXMENT ZZ •
SPECTRAL NN 60, e2 I 65. 7X 52R 68X
FUSXON NN 65 o e3S 7S. 8R 6SR 76R
TABLE II
CORRECTED PERFORMANCE FOR EACH CLASS
SPECTRAL SXGNATURE NEURAL NETWORK
C_RECTED NEURAL NETWORK CLASSXPZCATZON
GR_ND
T_TH UmAN FARM RA_E F_[ ST
URBAN IGOR -
FARM 26. 8R 6eR 6. 7R 6. 7R
RANGE - leer OR
FOREST - - I 2. SX 87. 5R
ELEVATION FUSION NEURAL NETWORK
C_RECTED NEURAL NETWORK CLASSIFXCATZON
GR_
TRUTH URBAN F_M RA_E F_EST
URBAN leer - - -
FARM 2eX 8eR = =
RANGE - leer ex -
FOREST - I 2. SR I 2. SX 75R
157
TABLE I I !
UULTISPECTRAL IMAGE
CLASS IF ! CAT I ON PERFORMANCES
NEURAL NETWORKS
CAMPBELL, HZLL
& CROMP, 1989
WASHINGTON, DC
W/ GROUND TRUTH
TRAZNZNG TESTZNO
ANYPim 48Z 557.
"oR- 66_ 70_GOUNDRY
PIXELS
BENEDZKTSSON,
SWAZN & ERSOY,
1990
COLORADO MOUNTAINS
CROMP , 1991
BLACK HILLS LANDSAY MSS
HOMOGENEOUS
,.LOS 95Z
HARSTON , 199 I
liURFREESBORO LANDSAT MSS
HULTISPECTRAL FUSION SYSTEM
HARSTON &
$CHUMACHER,
1991
TillS I IV,OE S
HARSTON &
SCHUMACHER,
1991
BLACK HILLS LANDSAT MSS
IILC Wl NH
I SAMPLE
/CLASS SET
BRIGHTNESS
BRIGHTNESS
& TEXTURE
SPECTRAL
SIGNATURE
W/ ROAD
DETECTOR
NN SYSTEH
SPECTRAL
SIGNATURE
SPECTRAL
SIGNATURE
W/ALTITUDE
100Z
100Z
85Z
75Z
95Z
Wl GROUND
TiM,ITH
65.7Z
75.8Z
m EDt MINIMUM EUCLIDEAN DISTANCE
MLs MAXIMUM LIKELIHOOD IIETHOD
lidos MINIMUM HAHALANOBIS DISTANCE
HULT|SOURCE: STATISTICAL NULTISOURCE ANALYSIS
52.5Z
60Z
6IZ
43Z
63Z
STATZST ZCAL
CLASSZ_ZCATZON
ED ilL lid HULTI-
SOURCE
47Z 49Z 50Z 61Z
CORRECTED
FOR VISUAL
INTERPRETATION
68Z
76Z
1S8


Improved image classification with neural networks by fusing multispectral signatures with topological data

Abstract

Similar works

Full text

Available Versions

NASA Technical Reports Server