Naisen Liu scite author profile

Naisen Liu

3Publications

48Citation Statements Received

203Citation Statements Given

How they've been cited

How they cite others

178

199

Affiliations

Huaiyin Normal University, Nanjing Agricultural University, Jiangsu Center for Collaborative Innovation in Geographical Information Resource Development and Application

Publications

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The effect of microbial inoculant origin on the rhizosphere bacterial community composition and plant growth-promotion

Dong

Geisen

et al. 2020

Plant Soil

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The Node Deployment of Intelligent Sensor Networks Based on the Spatial Difference of Farmland Soil

Liu

Cao

Zhu

et al. 2015

Sensors

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Considering that agricultural production is characterized by vast areas, scattered fields and long crop growth cycles, intelligent wireless sensor networks (WSNs) are suitable for monitoring crop growth information. Cost and coverage are the most key indexes for WSN applications. The differences in crop conditions are influenced by the spatial distribution of soil nutrients. If the nutrients are distributed evenly, the crop conditions are expected to be approximately uniform with little difference; on the contrary, there will be great differences in crop conditions. In accordance with the differences in the spatial distribution of soil information in farmland, fuzzy c-means clustering was applied to divide the farmland into several areas, where the soil fertility of each area is nearly uniform. Then the crop growth information in the area could be monitored with complete coverage by deploying a sensor node there, which could greatly decrease the deployed sensor nodes. Moreover, in order to accurately judge the optimal cluster number of fuzzy c-means clustering, a discriminant function for Normalized Intra-Cluster Coefficient of Variation (NICCV) was established. The sensitivity analysis indicates that NICCV is insensitive to the fuzzy weighting exponent, but it shows a strong sensitivity to the number of clusters.

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Node Deployment with k-Connectivity in Sensor Networks for Crop Information Full Coverage Monitoring

Liu

Cao

Zhu

et al. 2016

Sensors

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Wireless sensor networks (WSNs) are suitable for the continuous monitoring of crop information in large-scale farmland. The information obtained is great for regulation of crop growth and achieving high yields in precision agriculture (PA). In order to realize full coverage and k-connectivity WSN deployment for monitoring crop growth information of farmland on a large scale and to ensure the accuracy of the monitored data, a new WSN deployment method using a genetic algorithm (GA) is here proposed. The fitness function of GA was constructed based on the following WSN deployment criteria: (1) nodes must be located in the corresponding plots; (2) WSN must have k-connectivity; (3) WSN must have no communication silos; (4) the minimum distance between node and plot boundary must be greater than a specific value to prevent each node from being affected by the farmland edge effect. The deployment experiments were performed on natural farmland and on irregular farmland divided based on spatial differences of soil nutrients. Results showed that both WSNs gave full coverage, there were no communication silos, and the minimum connectivity of nodes was equal to k. The deployment was tested for different values of k and transmission distance (d) to the node. The results showed that, when d was set to 200 m, as k increased from 2 to 4 the minimum connectivity of nodes increases and is equal to k. When k was set to 2, the average connectivity of all nodes increased in a linear manner with the increase of d from 140 m to 250 m, and the minimum connectivity does not change.

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Naisen Liu

The effect of microbial inoculant origin on the rhizosphere bacterial community composition and plant growth-promotion

The Node Deployment of Intelligent Sensor Networks Based on the Spatial Difference of Farmland Soil

Node Deployment with k-Connectivity in Sensor Networks for Crop Information Full Coverage Monitoring

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