IERI Procedia 5 ( 2013 ) 75 – 80Ava

IERI Procedia 5 ( 2013 ) 75 – 80
Available online at www.sciencedirect.com
2212-6678 © 2013 The Authors. Published by Elsevier B.V.
Selection and peer review under responsibility of Information Engineering Research Institute
doi: 10.1016/j.ieri.2013.11.073
ScienceDirect
2013 International Conference on Agricultural and Natural Resources Engineering
Study on Macroscopical Dynamic Monitoring of New Increased
Construction Land in Yinchuan Plain Based on 20m Scale
Middle Resolution Remote Sensing Data
Zhihong Liua,b,*, Xingke Yanga
, Hujun Hea
, Qian Zhua
a
School of Earth Science and Resources, Chang’an University, Xi’an 710054, China b
The National Land Inspectorate Bureau of Xi'an, Xi’an 710075, China
Abstract
Analyzing the significance of macroscopical dynamic monitoring of new add construction land, considering the influence
of various factors, this paper selected Yinchuan Plain for a typical experimental zone, built knowledge base of remote
sensing images interpretation, used multi-temporal remote sensing images, carried through interactive interpretation of
change patterns of new add construction land and field validation. Interpretation results of 20m scale remote sensing
image show that the minimum spot average area of new construction land change monitored by 20m scale remote sensing
data is about 6 acres. The ability 20m scale remote sensing data identifies new increased construction land change further
strengthens, shows in the recognition of the smallest spot area reduces and the recognition accuracy increases.
© 2013 Published by Elsevier B.V.
Selection and peer review under responsibility of Information Engineering Research Institute
Keywords: Yinchuan Plain; remote sensing data; middle resolution; new increased construction land dynamic monitoring
1. Introduction
With the further development of economic construction and the transformation of macroscopic land
administration requirement, Xi’an Bureau of State Land Supervision needs to obtain the macroscopic change
* Zhihong Liu. Tel.: +86-029-82339073.
E-mail address: hshengjun@sohu.com
Available online at www.sciencedirect.com
© 2013 The Authors. Published by Elsevier B.V.
Selection and peer review under responsibility of Information Engineering Research Institute
Open access under CC BY-NC-ND license.
Open access under CC BY-NC-ND license.
76 Zhihong Liu et al. / IERI Procedia 5 ( 2013 ) 75 – 80
information of new increased construction land as quickly as possible to offer target range for supervised
points. Therefore, on the basis of using high resolution remote sensing images to supervise the situation of the
newly increased construction land in some key zones, it’s necessary to use wide covered and relatively cheap
middle resolution remote sensing images to supervise the macro situation of the new increased construction
land in the whole range. In this way, it could further complete the dynamic remote sensing supervision system
of new construction land increase in flatland zones of northwestern five provinces, meanwhile, the macro
supervision and micro supervision could compensate each other to offer just-in-time and comprehensive data
for macro decision making and land supervision administration in five provinces of the northwest[1-6].
Hence, it’s necessary to conduct an experiment about the change detection of new increased construction
land with the middle resolution remote sensing images in some flat zones. Then, based on the experiment
results, the paper analyzes and discusses the ability of middle resolution remote sensing images in supervising
and discovering the change of newly increased construction land, in order to offer experience and reference to
the further work of change detection for newly increased construction land, especially for which is changed
from plow land.
2. Experimental Zones and Data Processing
2.1. Choosing of Experimental Zone
This research chose Yinchuan Plain as the experimental zone. Yinchuan Plain has a large area, so it’s a
heavy work to use middle resolution images to supervise the whole zone. Considering the quality of existing
high resolution images, this experiment only chose some counties of Yinchuan Plain to conduct the dynamical
supervision. This experiment chose Xixia district, Jinfeng district, Xingqing district(the total area of three
districts is 9491 km2
), Helan county (1600 km2
) and Yongning city(1020 km2
). The total area is 12111 km2
.
2.2. Data Preparation
(1)Middle resolution images
The collected middle resolution images of Yinchuan Plain were produced in 2007 and 2008. P6 data spatial
resolution was 23.5m, which has four channels, CBERS satellite multispectral data spatial resolution was 20m,
which has 5 channels, this test will use the remote sensing data for 20m scale of remote sensing data
representation.
(2)High resolution images
The collected high resolution images of Yinchuan Plain were produced in 2007 and 2008. This experiment
used these images to verify and evaluate the correctness of the newly increased construction land which was
extracted from middle resolution images.
2.3. Data Pre-processing
(1)Geomatic correction
Found out identifiable points from reference images, meanwhile considering the uniform distribution of
these points.
Found out corresponding points from image for corrective, and used the remote sensing processing
software to enter the coordinate values of these points one by one.
Conducted adjustment calculation with controlling points by quadratic polynomial fitting method,
resample pixels by double linear interpolation method, and deleted those points which had exceptional RMSE
Zhihong Liu et al. / IERI Procedia 5 ( 2013 ) 75 – 80 77
values, meanwhile ensured these deleted points did not influence the geometric correction results. The number
of controlling points were controlled between the theoretical minimum number (n+1)(n+2)/2 and the
recommended maximum number (n+1)(n+2)/2 to satisfy the requirement of geometric accuracy[7-10].
(2)Image registration
As images that used to identify and extract information of newly increased construction land were obtained
from different sensors and different time of two experimental zones, they were required to match well with
each other on spatial locations in the same zone. It meant image registration technologies were needed.
The CBERS Pan images, obtained in Dec 2007, were taken as the reference image, to register the 30 m’s
middle resolution images in the experimental zone of Yinchuan Plain.
(3)Image enhancement
It was a complex process to obtain remote sensing images, and the quality of images were influenced by
atmosphere, optical system, sensor, electronic lines as well as the flight of the satellite etc., so it was necessary
to recover images’ immanent texture and geometric features through the following method: first, using the
point spread function (PSF) of the imaging formation system to express the quality reduction; second, using
the Fourier transformation on PSF to obtain the modulation transfer function (MTF) of the imaging formation
system; after that, based on the inverse process of satellite imaging process, using the Wiener filtering to
recover and compensate the MTF; finally, the sharpness of images was enhanced. Meanwhile, in order to
sharpen useful information and amplify the difference of features, which would improve images’ ability of
interpretation and analysis, the gray values of pixels were transformed to make the image features identified
and distinguished.
2.4. Extraction of New Increased Construction Land in Experimental Zones
(1)Establishment of new increased construction land interpretive marks
The establishments of new increased construction land interpretive marks were mainly on multiple spectral
images. Pattern spots of new increased construction land change of different data types were selected based on
the reference of high resolution images, at the same time described and categorized by their features:
Interpretive knowledge of the transformation from farm land to construction land
Interpretive knowledge of the transformation from unused land to construction land
(2)Extraction of new increased construction land pattern spots
Partition of grids
To avoid pattern spots of change were missed or repeated during the extracting process, the experimental
zones were partitioned into several equi-spaced grids, and each grid was a work unit. The size of the grid was
1 km×1 km for panchromatic high resolution images and 2 km×2 km for middle resolution images.
Extracting method of newly increased construction land pattern spots
Currently, the accuracy of auto classification by computer still cannot satisfy the work requirements, thus
this experiment used the human-computer interactive interpretation way to extract pattern spots of change.
Through the exchange between two periods’ multiple spectral images, the change information of the
spectrum, and interpret the pattern spots of newly increased construction land grid by grid on 20 m scale
middle resolution images were found. According to the color, size, shape, texture, structure, height, and shade
of images, the changed land was identified, the new increased construction land was drawn, and the changed
information was recorded.
In the same way, pattern spots of new increased construction land on the panchromatic images were
extracted, and the changed information was recorded for setting reference of the verification in the fieldwork.
78 Zhihong Liu et al. / IERI Procedia 5 ( 2013 ) 75 – 80
3. Extracting and Analysis Results of New Increased Construction Land in Experimental Zones
(1)Supervising results of new increased construction land by 20 m scale middle resolution multiple spectral
images
In Yinchuan Plain experimental zone, 107 pattern spots of new increased construction land were extracted
through CBERS and P6 images data. The area in all was about 20607 acres. The spot distribution of new
increased construction land was sho