Amit K. Srivastava scite author profile

Abstract:Remote sensing offers a low-cost method for developing spatially continuous crop production statistics across large areas and through time. Nevertheless, it has been difficult to characterize the production of individual smallholder farms, given that the land-holding size in most areas of South Asia (<2 ha) is smaller than the spatial resolution of most freely available satellite imagery, like Landsat and MODIS. In addition, existing methods to map yield require field-level data to develop and parameterize predictive algorithms that translate satellite vegetation indices to yield, yet these data are costly or difficult to obtain in many smallholder systems. To overcome these challenges, this study explores two issues. First, we employ new high spatial (2 m) and temporal (bi-weekly) resolution micro-satellite SkySat data to map sowing dates and yields of smallholder wheat fields in Bihar, India in the 2014-2015 and 2015-2016 growing seasons. Second, we compare how well we predict sowing date and yield when using ground data, like crop cuts and self-reports, versus using crop models, which require no on-the-ground data, to develop and parameterize prediction models. Overall, sow dates were predicted well (R 2 = 0.41 in 2014-2015 and R 2 = 0.62 in 2015-2016), particularly when using models that were parameterized using self-report sow dates collected close to the time of planting and when using imagery that spanned the entire growing season. We were also able to map yields fairly well (R 2 = 0.27 in 2014-2015 and R 2 = 0.33 in 2015-2016), with crop cut parameterized models resulting in the highest accuracies. While less accurate, we were able to capture the large range in sow dates and yields across farms when using models parameterized with crop model data and these estimates were able to detect known relationships between management factors (e.g., sow date, fertilizer, and irrigation) and yield. While these results are specific to our study site in India, it is likely that the methods employed and the lessons learned are applicable to smallholder systems more generally across the globe. This is of particular interest given that similar high spatio-temporal resolution micro-satellite data will become increasingly available in the coming years.

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Using satellite data to identify the causes of and potential solutions for yield gaps in India’s Wheat Belt

Jain

Singh

Srivastava

et al. 2017

Environ. Res. Lett.

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Food security will be increasingly challenged by climate change, natural resource degradation, and population growth. Wheat yields, in particular, have already stagnated in many regions and will be further affected by warming temperatures. Despite these challenges, wheat yields can be increased by improving management practices in regions with existing yield gaps. To identify the magnitude and causes of current yield gaps in India, one of the largest wheat producers globally, we produced 30 meter resolution yield maps from 2001 to 2015 across the Indo-Gangetic Plains (IGP), the nation's main wheat belt. Yield maps were derived using a new method that translates satellite vegetation indices to yield estimates using crop model simulations, bypassing the need for ground calibration data. This is one of the first attempts to apply this method to a smallholder agriculture system, where ground calibration data are rarely available. We find that yields can be increased by 11% on average and up to 32% in the eastern IGP by improving management to current best practices within a given district. Additionally, if current best practices from the highest-yielding state of Punjab are implemented in the eastern IGP, yields could increase by almost 110%. Considering the factors that most influence yields, later sow dates and warmer temperatures are most associated with low yields across the IGP. This suggests that strategies to reduce the negative effects of heat stress, like earlier sowing and planting heattolerant wheat varieties, are critical to increasing wheat yields in this globally-important agricultural region.

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Taking the climate risk out of transplanted and direct seeded rice: Insights from dynamic simulation in Eastern India

McDonald

Kumar

Poonia

et al. 2019

Field Crops Research

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Highlights Optimum rice transplanting date in EIGP to achieve high yield with low risk is up to 2 August for long duration variety and is up to 16 August for short duration variety. Late transplanting with old seedlings under farmer practice lead to low rice yields due to high drought risk but supplemental irrigation or short duration variety reduced the drought risk. Transplanting of appropriate aged seedling at onset of monsoon yields 1.8 t ha −1 as compared to farmer practice. There is high probability to meet required soil moisture conditions for DSR sowing during early June. Supplemental irrigation for DSR crop establishment and to meet crop demands during dry periods can result in 5.8 t ha −1 in May and June sowings.

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Agricultural labor, COVID-19, and potential implications for food security and air quality in the breadbasket of India

Balwinder-Singh

Shirsath

Jat

et al. 2020

Agricultural Systems

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Tradeoffs between groundwater conservation and air pollution from agricultural fires in northwest India

et al. 2019

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The impact of agricultural interventions can be doubled by using satellite data

et al. 2019

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Social inclusion increases with time for zero-tillage wheat in the Eastern Indo-Gangetic Plains

et al. 2019

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HighlightsFarmers in Bihar access zero-tillage (ZT) technology mostly via custom-hiring services.Scale bias in ZT use declined as farmer awareness increased and ZT services expanded.Land fragmentation replaced landholding size as a significant adoption determinant.Farmers with small but contiguous landholdings have gained access to quality ZT services.Private sector-based mechanization service provision can lead to socially inclusive outcomes.

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Using Sentinel-1, Sentinel-2, and Planet Imagery to Map Crop Type of Smallholder Farms

et al. 2021

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Remote sensing offers a way to map crop types across large spatio-temporal scales at low costs. However, mapping crop types is challenging in heterogeneous, smallholder farming systems, such as those in India, where field sizes are often smaller than the resolution of historically available imagery. In this study, we examined the potential of relatively new, high-resolution imagery (Sentinel-1, Sentinel-2, and PlanetScope) to identify four major crop types (maize, mustard, tobacco, and wheat) in eastern India using support vector machine (SVM). We found that a trained SVM model that included all three sensors led to the highest classification accuracy (85%), and the inclusion of Planet data was particularly helpful for classifying crop types for the smallest farms (<600 m2). This was likely because its higher spatial resolution (3 m) could better account for field-level variations in smallholder systems. We also examined the impact of image timing on the classification accuracy, and we found that early-season images did little to improve our models. Overall, we found that readily available Sentinel-1, Sentinel-2, and Planet imagery were able to map crop types at the field-scale with high accuracy in Indian smallholder systems. The findings from this study have important implications for the identification of the most effective ways to map crop types in smallholder systems.

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