1,721,589 research outputs found
FIGURE 3 in Distribution status of the Western Burrowing Frog, Sphaerotheca pashchima in India
No full textFIGURE 3. Map showing the distribution range of Sphaerotheca pashchima in the Indian subcontinent.Published as part of Deepak, P., Dinesh, K.P., Prasad, Vishal Kumar, Das, Abhijit & Ashadevi, J.S., 2020, Distribution status of the Western Burrowing Frog, Sphaerotheca pashchima in India, pp. 146-150 in Zootaxa 4894 (1) on page 149, DOI: 10.11646/zootaxa.4894.1.10, http://zenodo.org/record/431544
sj-pdf-1-jao-10.1177_03913988241232315 – Supplemental material for Step by step enhancement of aesthetics for distal phalangeal prosthetic replacement using neoteric stamp technique: A case report
No full textSupplemental material, sj-pdf-1-jao-10.1177_03913988241232315 for Step by step enhancement of aesthetics for distal phalangeal prosthetic replacement using neoteric stamp technique: A case report by Komal Kaur Saroya, Vishal Kumar, Surbhi Sharma and Sonam Kalsi in The International Journal of Artificial Organs</p
A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour
No full textDufresnes, Christophe, Ambu, Johanna, Prasad, Vishal Kumar, Borzée, Amaël, Litvinchuk, Spartak N (2022): A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour. Biological Journal of the Linnean Society 135 (1): 40-51, DOI: 10.1093/biolinnean/blab143, URL: https://academic.oup.com/biolinnean/article/135/1/40/644634
Figure 2 in A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour
No full textFigure 2. Phylogeography of Zhangixalus, part I. For clarity, distributions are mapped separately for three sets of lineages. Stars indicate the known type localities of currently recognized species. Undescribed lineages are labelled as 'cf.', except for Zhangixalus schlegelii, for which the labels provided by Matsui et al. (2019) are used.Published as part of Dufresnes, Christophe, Ambu, Johanna, Prasad, Vishal Kumar, Borzée, Amaël & Litvinchuk, Spartak N, 2022, A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour, pp. 40-51 in Biological Journal of the Linnean Society 135 (1) on page 45, DOI: 10.1093/biolinnean/blab143, http://zenodo.org/record/781796
Institute of Economic Growth
No full textPresentation given by Vishal kumar on Institute of Economic Growt
Node selection for cooperative decoding in wireless mesh networks
Full text linkWe study the problem of gathering data and aggregation in decentralized, heterogeneous sensor networks for reliable communication. In many application scenarios, we have sensors with small energy budget and size in the network. Wildlife monitoring is one of many examples within the Internet of Things research community. To improve communication reliability and energy-efficiency of the network in such applications, macro-diversity has been employed on the data samples received by multiple sensor nodes in the network. Thus resulting in the reduction of transmission failures and further avoiding costly retransmissions. In recent times, macro-diversity techniques have been proposed which uses a distributed sensor network as an antenna array at the receiver end. These techniques primarily need the sensor nodes to forward the data samples to the sink node, to apply different diversity combining techniques. The process of forwarding the data samples from all the ground node at all times in the network incurs a huge cost. We present two algorithms, a cluster and a tree-based one, that help to reduce the data transfers in the network by pushing the aggregation process near to the point of transmission within the network. Sensor nodes within the network act as an aggregator and apply diversity combining technique on the received samples from multiple receivers rather than a centralized sink node. In an extensive set of simulations, we show that our algorithms substantially outperform naïve centralized solution and also depending upon the topology, cluster-based and tree-based algorithms outperform each other in terms of time delay and energy footprint.vorgelegt von Vishal Kumar Singh ; angefertigt in der Fachgruppe Distributed Embedded Systems (CCS Labs), Heinz Nixdorf Institut Universität Paderborn ; Gutachter: Prof. Dr.-Ing. habil. Falko Dressler, Prof. Dr. Christian ScheidelerTag der Abgabe: 14.01.2019Universität Paderborn, Masterarbeit, 201
FIGURE 8B in Identification of anuran species diversity of the Panna Tiger Reserve, Central India, using an integrated approach
No full textFIGURE 8B. Maximum Likelihood tree based on the 16S mitochondrial DNA dataset (nodes having>50% bootstrap values are shown) of genera B. Sphaerotheca (Red colour indicates sequences generated in this study).Published as part of Prasad, Vishal Kumar, Gautam, Kumudani Bala, Gupta, Sandeep Kumar, Murthy, R. Sreenivasa, Ramesh, K., Shinde, Ajinkya Duttatray & Das, Abhijit, 2020, Identification of anuran species diversity of the Panna Tiger Reserve, Central India, using an integrated approach, pp. 450-476 in Zootaxa 4851 (3) on page 466, DOI: 10.11646/zootaxa.4851.3.2, http://zenodo.org/record/448723
FIGURE 1 in Discovery and description of a new species of burrowing frog Sphaerotheca Günther, 1859 (Anura: Dicroglossidae) from the suburban landscapes of Bengaluru, India
No full textFIGURE 1. Map showing type localities and sequence representations for the recognized eight species of Sphaerotheca Günther and an unnamed lineage from south Asia.Published as part of <i>Deepak, P., Dinesh, K.P., Nag, K.S. Chetan, Ohler, Annemarie, Shanker, Kartik, Souza, Princia D, Prasad, Vishal Kumar & Ashadevi, J.S., 2024, Discovery and description of a new species of burrowing frog Sphaerotheca Günther, 1859 (Anura: Dicroglossidae) from the suburban landscapes of Bengaluru, India, pp. 381-410 in Zootaxa 5405 (3)</i> on page 386, DOI: 10.11646/zootaxa.5405.3.3, <a href="http://zenodo.org/record/10603512">http://zenodo.org/record/10603512</a>
Figure 3 in A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour
No full textFigure 3. Phylogeography of Zhangixalus, part II. For clarity, distributions are mapped separately for two sets of lineages. Stars indicate the known type localities of currently recognized species. Undescribed lineages are labelled as 'cf.', except for Zhangixalus arboreus, for which the labels provided by Matsui et al. (2019) are used. No accurate geographical information exists for the lineage Zhangixalus cf. dorsoviridis 2 (given as 'China'; see Supporting Information, Appendix S1).Published as part of Dufresnes, Christophe, Ambu, Johanna, Prasad, Vishal Kumar, Borzée, Amaël & Litvinchuk, Spartak N, 2022, A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour, pp. 40-51 in Biological Journal of the Linnean Society 135 (1) on page 46, DOI: 10.1093/biolinnean/blab143, http://zenodo.org/record/781796
Figure 4 in A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour
No full textFigure 4. Diversity of the nesting strategies inventoried in the genus Zhangixalus, classified in the following three categories: arboreal (suspended in trees and leaves above the water surface); scansorial (attached to the ground, grasses or abiotic substrates flanking the water); or fossorial (buried in the mud or ground cover). Ancestral state reconstructions are shown. *The fossorial Zhangixalus schlegelii was exceptionally reported to build arboreal nests.Published as part of Dufresnes, Christophe, Ambu, Johanna, Prasad, Vishal Kumar, Borzée, Amaël & Litvinchuk, Spartak N, 2022, A phylogeographical framework for Zhangixalus gliding frogs, with insight on their plasticity of nesting behaviour, pp. 40-51 in Biological Journal of the Linnean Society 135 (1) on page 47, DOI: 10.1093/biolinnean/blab143, http://zenodo.org/record/781796
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