Choice of Appropr iate Scale for Land Use Monitoring: A Case of the Tarim River Basin

  • 1. Xinjiang Institute of Ecology and Geography, CAS, Urumqi 830011, China;
    2. Xinjiang Management Bureau of Tarim River, Korla 841300, China;
    3. Graduate School of the Chinese Academy of Sciences, Beijing 100039, China

Received date: 2006-12-20

  Revised date: 2007-03-12

  Online published: 2007-06-25

Supported by

National Natural Science Foundation of China, No.40571030; Western Action Program of CAS (KZCX2-XB2-03); World Bank and National Key Project, No.TTTQ-126; No.TTTQ-128; Knowledge Innovation Program of CAS


After wastelands reclamation in the Tarim River Basin in recent 50 years, one third of the stream flow in the Tarim River (the longest continental river in China) has been cut off. The natural ecosystems are seriously degenerated, and the situation of land use is tempestuously changed. Therefore, it is urgent to resolve the problems that whether there exist the changing laws of scales and what kinds of scales are suitable in monitoring land use. Adaptive choice of scale is one of the important issues in ecology and geography. In different studies, the choice of methods and standards vary with purpose. This article summarized methods on how to choose appropriate scale based on land-use data of the Tarim River Basin in Xinjiang of China in the 1950s. Regarding the areas of land use types as the scales, the parameters are selected, the histograms of the areas of patches are charted, and then normalized scale variance calculated under 9 scales (1:2 000 000, 1:1 000 000, 1:500 000, 1: 250 000, 1:100 000, 1:50 000, 1:25 000, 1:10 000 and 1:5 000), furthermore, some landscape indexes of patch area counted to examine and add result of normalized scale variance as well, which include Shannon-Weaver's landscape diversity index, Simpson's diversity index and fractal dimension respectively. The scale laws of general land use and 4 main land use types including woodlands, shrub land, sandy land and saline or alkaline lands in the mainstream area of the Tarim River are lucubrated by interpreting the land use data in the 1950s. The result showed that: (1) Normalized scale variance of the Tarim River reached maximum at scale of 1:50 000 in the 1950s, that 20km×20km grid sizes, diversity of patch size at 1:50 000 richer than in other scale's, so 1:50 000 used as appropriate scale of the Tarim River. In addition to appropriate scale of sandy land at scale of 1:100 000, the optimal scale of woodland, shrub land and saline land is at 1:50 000. (2) Shannon-Weaver's diversity index, Simpson's diversity index and fractal dimension of saline land have the same results as normalized scale variance. Diversity indexes and normalized scale variance of sand land proved the appropriate scale being in the same scale domain. It is noticed that there is a significant difference in woodland and shrub land. The optimal scale of diversity indexes are at 1:10 000 rather than 1:50 000. (3) Fractal dimension of sandy land and saline land showed a marked increase and up to 1.35 at 1:10 000 and similar at other levels, however, fractal dimension of woodland and shrub land are close at all scale levels and no more than 1.2, which reveals that hierarchical structure areas of sandy land and saline land are probably changed at scale of 1:10 000, while woodlands and shruby lands's are distributed under the same hierarchical structure in the region.

Cite this article

ZHAO Jin, CHEN Xi, BAO Anming, DUAN Yuanbin . Choice of Appropr iate Scale for Land Use Monitoring: A Case of the Tarim River Basin[J]. Acta Geographica Sinica, 2007 , 62(6) : 659 -668 . DOI: 10.11821/xb200706011


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