Comparison of Pixel- and Object-Based Approaches in Phenology-Based Rubber Plantation Mapping in Fragmented Landscapes

Zhai, De‐Li; Jie, Dong; Cadisch, Georg; Wang, Mingcheng; Kou, Weili; Xu, Jianchu; Xiao, Xiangming

doi:10.20944/preprints201608.0069.v1

Cited by 3 publications

(3 citation statements)

References 48 publications

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“…More importantly, compared with the ratioing method of individual band (e.g., near-infrared (NIR)), the (re)normalization of bands or VIs considerably reduces errors caused by surface anisotropy, saturation, and topographical variations (Gutman, 1991;Huete et al, 1997). Phenology-based approaches have also shown promise for reducing the demand for data to monitor rubber plantations (Li et al, 2015;Xiao et al, 2019a;Zhai et al, 2018). In the RNVI approach, only two target images of the defoliating phase and the other when new leaves emerge were needed to satisfy the data requirement.…”

Section: Introductionmentioning

confidence: 99%

Latest 30-m map of mature rubber plantations in Mainland Southeast Asia and Yunnan province of China: Spatial patterns and geographical characteristics

Xiao

Zhu

et al. 2021

Progress in Physical Geography: Earth and Environment

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Knowledge of the location, area and extent of rubber plantations is a prerequisite for assessing their ecological and environmental impacts. Mainland Southeast Asia (MSEA) and Yunnan province (MSEA&YN) in China are globally important rubber-planting regions. Rubber cultivation in areas at moderate and low altitudes (<1000 m) within these regions has expanded rapidly in recent years. However, datasets of maps generated at a fine spatial resolution are still unavailable for MSEA&YN. Because of this, three relevant and important questions remain unanswered: what are the northernmost boundary for rubber production in these regions, what is the highest altitude at which rubber is produced, and how are the plantations distributed in (cross-) border regions? An approach of the phenology- and Landsat-based re-normalized vegetation index (RNVI), originally developed for Xishuangbanna in southern China, is used in this study to verify the feasibility of mapping mature rubber plantations in MSEA&YN using the Landsat 8 Operational Land Imager data products acquired from January to April, 2013 to 2018. Characteristics of the vertical and horizontal distributions of mature rubber plantations in MSEA&YN, as well as national differences especially in the (cross-) borders, were examined using the generated map. The results showed that the RNVI method, although tailored to the northern edge of the tropics, is useful for detecting mature rubber plantations in MSEA&YN. The latest map of mature rubber plantations indicated that they occupied a total area of 7.69 × 106 ha, accounting for 3.32% of the study area. Spatial analyses showed three typical features of the distribution: new plantations at higher (over 1000 m) and lower (below 200 m) elevations, more cultivation in the borderlands (over a half within 60 km buffers), and their northward movement (as far as 25°N). The results of this study have important implications for phenological methods verification in the tropics, and provide valuable information on mature rubber plantations in MSEA&YN.

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Section: Introductionmentioning

confidence: 99%

Latest 30-m map of mature rubber plantations in Mainland Southeast Asia and Yunnan province of China: Spatial patterns and geographical characteristics

Xiao

Zhu

et al. 2021

Progress in Physical Geography: Earth and Environment

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“…It has been determined that an essential factor for accurate mapping of rubber plantations in SE Asian ecosystems is the availability of data at two crucial phenological periods: defoliation (leaf off) and new leaf emergence (leaf on), which distinguishes deciduous rubber trees from other vegetation. Many approaches consist of using optical satellite data [6,[17][18][19][20][21] to detect rubber plantations. However, due to the persistent cloud cover in tropical regions, it is difficult to acquire sufficient high resolution satellite imagery which in turn compromises spatial resolution, as coarser satellites such as MODIS are frequently used.…”

Section: Introductionmentioning

confidence: 99%

Mapping Plantations in Myanmar by Fusing Landsat-8, Sentinel-2 and Sentinel-1 Data along with Systematic Error Quantification

Poortinga¹,

Tenneson²,

Shapiro

et al. 2019

Remote Sensing

118

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Forests in Southeast Asia are experiencing some of the highest rates of deforestation and degradation in the world, with natural forest species being replaced by cropland and plantation monoculture. In this work, we have developed an innovative method to accurately map rubber and palm oil plantations using fusion of Landsat-8, Sentinel 1 and 2. We applied cloud and shadow masking, bidirectional reflectance distribution function (BRDF), atmospheric and topographic corrections to the optical imagery and a speckle filter and harmonics for Synthetic Aperture Radar (SAR) data. In this workflow, we created yearly composites for all sensors and combined the data into a single composite. A series of covariates were calculated from optical bands and sampled using reference data of the land cover classes including surface water, forest, urban and built-up, cropland, rubber, palm oil and mangrove. This training dataset was used to create biophysical probability layers (primitives) for each class. These primitives were then used to create land cover and probability maps in a decision tree logic and Monte-Carlo simulations. Validation showed good overall accuracy (84%) for the years 2017 and 2018. Filtering for validation points with high error estimates improved the accuracy up to 91%. We demonstrated and concluded that error quantification is an essential step in land cover classification and land cover change detection. Our overall analysis supports and presents a path for improving present assessments for sustainable supply chain analyses and associated recommendations.

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“…Land use/land cover data for was classified by 32 Landsat images which were downloaded from Earth Explorer (http://earthexplorer.usgs.gov/). The nearest-neighbor-object-based phenology approach was applied for the classification (Zhai et al, 2018). Google Earth data were used for training and validation.…”

Section: Use Classification and Stand Age Of Rubber Plantationmentioning

confidence: 99%

Rubber Plantation Retiring with Simulation of Market-Priced Ecosystem Services in Xishuangbanna, China

Liu¹,

Zhang²,

Yan³

et al. 2020

Preprint

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Background: Until 50 years ago, Xishuangbanna was a heavy forest-covered region with high biodiversity. Attributed to the rubber boom that took place in the region during the last decades, natural forest area decreased quickly and was replaced by monoculture rubber plantations (Hevea brasiliensis). To slow down the deforestation rate and encourage rubber plantation retiring, a market and government-combined compensatory payment system was developed with consideration of market-priced ecosystem services. Results: In the baseline scenario, the annual retiring rate reduced from 9,353±17.8 ha to 4,669±18.5 ha in the projection period, and the final total retiring area in 2050 was 202.477±0.063 thousand ha. The compensatory payment increased along with the growth of rubber plantations. In the projected period (2021-2050), the total NPV (net present value) of compensatory payment was $3,364.820±1.669 million. The total carbon sequestration benefit resulting from replacement of artificial rainforests was 11.718±0.005 million tC. In sensitivity analyses, more uncertainties of compensatory payment were expected with a higher variation of rubber price. The rise of carbon price, discount rate and traditional medicine price, and the decrease of rubber price and final retiring rate could reduce the total NPV of payment. Conclusions: The market and government-combined payment system has high possibility to effectively encourage rubber retiring and reduce government payment. By the projection of the market and government-combined payment system, most of the small patches of rubber plantation were disappeared in 2050. The annual retiring area decreased gradually along the projection period. The projected compensatory payment and the area-specific payment increased, while the increment of compensatory payment decreased. The carbon sequestration benefit by rubber plantation retiring was negative in the first decade. All the tested factors (i.e., rubber price, rubber price variation, carbon price, final retiring rate, discount rate, and traditional medicine price) could affect the compensatory payment. Currently, the payment system may not so attractive; however, the situation could change when more market-priced ecosystem services are involved in the system.

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Comparison of Pixel- and Object-Based Approaches in Phenology-Based Rubber Plantation Mapping in Fragmented Landscapes

Cited by 3 publications

References 48 publications

Latest 30-m map of mature rubber plantations in Mainland Southeast Asia and Yunnan province of China: Spatial patterns and geographical characteristics

Latest 30-m map of mature rubber plantations in Mainland Southeast Asia and Yunnan province of China: Spatial patterns and geographical characteristics

Mapping Plantations in Myanmar by Fusing Landsat-8, Sentinel-2 and Sentinel-1 Data along with Systematic Error Quantification

Rubber Plantation Retiring with Simulation of Market-Priced Ecosystem Services in Xishuangbanna, China

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