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10 T T T T T T T 
[^ i —- 1st Harmonic 
FEN ---- 2nd Harmonic 
/ \ € : 
/ X 3rd Harmonic 
Wd MN | — 1st+2nd+3rd+4th 
Er Ur % q 
1; 
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=] 0 ae | 1 1 1 1 L 
5 10 15 20 25 30 35 40 
Period 
Figure 4. The curve constructed from the first four harmonics 
for single crop rotations in Loess Plateau Region 
and Yellow-Huai-Hai Rivers’ Region. 
  
m 
  
  
  
  
  
  
  
A —- 1st Harmonic 
{ A ---- 2nd Harmonic 
10 j \ 3rd Harmonic 
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Figure 5. The curve constructed from first four harmonics for 
double crop rotations in Loess Plateau Region and 
Yellow-Huai-Hai Rivers’ Region. 
4.2 Result Evaluation 
The results of the crop rotations classification were evaluated 
in two ways. First, we compared the Fourier based 
classification with. the Chinese cultivated system 
regionalization map. Second, they were compared with the 
ground based agricultural monitoring data derived from local 
stations in year 2000. 
The crop rotations map (Fig.3) described above was evaluated 
first by comparison with the Chinese cultivated system 
regionalization map, which was georeferenced to the same map 
coordinate system. The result of the crop rotations 
classification keeps comparative consistency with the reference 
map. The high accuracy derived from this comparison is partly 
due to the coarse description of the Chinese cultivated system 
regionalization map. But anyway the comparison shows that 
there are no notable mistakes in the result s of the crop 
rotations classification. 
In addition to the map comparisons, we also evaluated the 
results with the ground-based observations, which include the 
information about crop phonological calendar, and main crop 
types (winter wheat, spring wheat, spring maize, summer 
maize, rice, rapeseed, cotton, soybean, sorghum and peanut) 
237 
planted in the local area. There are 96 local stations 
observations (43 for Loess Plateau Region, 53 for Yellow- 
Huai-Hai River' Region) in year 2000 in the study areas. 
In Loess Plateau Region, double crop rotations were observed 
in 14 of 43 stations and winter wheat/summer maize (8 stations) 
and winter wheat/cotton (4 stations) were the main rotations 
types. From others local stations observations, winter wheat, 
spring wheat, spring maize and sorghum were known as the 
main crops planted in single rotations. In Yellow-Huai-Hai 
River' Region, double crop rotations were observed in 46 of 53 
stations, and four of them for double cropped winter wheat/ 
rice, others for double cropped nor rice crops. Winter 
wheat/summer maize was the main double crop rotations type 
in this region since it was observed in thirty local stations. The 
number of the local stations observations for single or double 
crop rotations showed the general agreement with the result of 
the classification. 
The accuracy of the crop rotations map evaluated with 
observations from 96 local stations was shown in Table. 2. The 
overall agreement between our crop rotations map and ground 
observations was 85 94. 
  
  
Single Double User's 
cropped cropped accuracy (94) 
Single cropped 28 6 82.4 
Double cropped 8 54 87.1 
  
  
  
  
Table 2. The accuracy of the crop rotations map evaluated with 
observations from 96 local stations. 
5. CONCLUSIONS 
In this study we detected the situation of crop rotations in 
Yellow-Huai-Hai Rivers’ Region and Loess Plateau Region, 
China using discrete Fourier analysis and unsupervised 
classification approach with AVHRR time series NDVI. The 
result of this study shows that the methodology used in this 
study is, in general, feasible for detecting the distributions of 
single cropped and double cropped rotations in China. 
Detection of triple crop rotations using discrete Fourier 
transform will be considered in the further study. 
6. REFERENCES 
Andres, L., Salas, W.A., Skole, D., 1994. Fourier analysis of 
multitemporal AVHRR data applied to a land cover 
classification. International Journal of Remote Sensing, 15(5), 
pp.1115- 1121. 
Azzali,S., Menenti, M. 2000. Mapping vegetation-soil-climate 
complexes in southern Africa using temporal Fourier analysis 
of NOAAAVHRR data. /nternational Journal of Remote 
Sensing, 21(5), pp.973-996. 
Chinese agricultural regionalization committee, 1991. Chinese 
agricultural natural resource and agricultural regionalization. 
Press of agriculture, Beijing. pp.162— 165. (In Chinese ). 
Jakubauskas, M.E., Legates, D.R., Kastens, J., 2001. Harmonic 
analysis of time-series AVHRR NDVI data. Photogrammetric 
Engineering and Remote Sensing 67 (4), pp.461-/470.