Static Positioning under Tree Canopy Using Low-Cost GNSS Receivers and Adapted RTKLIB Software

Tomaštík, Julián; Everett, Tim

doi:10.3390/s23063136

Cited by 10 publications

(3 citation statements)

References 57 publications

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“…The datasets were used as a basis for two studies [5 , 6] focused on applicability of GNSS data from low-cost and smartphone GNSS receivers.…”

Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

Raw GNSS data collected using smartphones and low-cost receiver under optimal and sub-optimal conditions

Tomaštík,

Varga,

Everett

2024

Data in Brief

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“…The datasets were used as a basis for two studies [5 , 6] focused on applicability of GNSS data from low-cost and smartphone GNSS receivers.…”

Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

Raw GNSS data collected using smartphones and low-cost receiver under optimal and sub-optimal conditions

Tomaštík,

Varga,

Everett

2024

Data in Brief

Self Cite

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“…Localization is of key importance in forestry and other unstructured environments, as the signal transmittance can be obstructed massively-usually one can expect positional accuracy within approximately 5 m of a true position in open sky settings, 7 m in young forest conditions, and 10 m under closed canopies [25]; recent results show better accuracy-this is theoretical up to 1.5 m [26]; however, it is highly dependent on the density of the forest and often there is no signal at all. Therefore, GNSS is rarely used alone but linked to technologies like LiDAR (explained later) to obtain the best location in such unstructured environments [27].…”

Section: Locator Devicesmentioning

confidence: 99%

Sensors for Digital Transformation in Smart Forestry

Ehrlich-Sommer,

Hoenigsberger,

Gollob

et al. 2024

Sensors

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Smart forestry, an innovative approach leveraging artificial intelligence (AI), aims to enhance forest management while minimizing the environmental impact. The efficacy of AI in this domain is contingent upon the availability of extensive, high-quality data, underscoring the pivotal role of sensor-based data acquisition in the digital transformation of forestry. However, the complexity and challenging conditions of forest environments often impede data collection efforts. Achieving the full potential of smart forestry necessitates a comprehensive integration of sensor technologies throughout the process chain, ensuring the production of standardized, high-quality data essential for AI applications. This paper highlights the symbiotic relationship between human expertise and the digital transformation in forestry, particularly under challenging conditions. We emphasize the human-in-the-loop approach, which allows experts to directly influence data generation, enhancing adaptability and effectiveness in diverse scenarios. A critical aspect of this integration is the deployment of autonomous robotic systems in forests, functioning both as data collectors and processing hubs. These systems are instrumental in facilitating sensor integration and generating substantial volumes of quality data. We present our universal sensor platform, detailing our experiences and the critical importance of the initial phase in digital transformation—the generation of comprehensive, high-quality data. The selection of appropriate sensors is a key factor in this process, and our findings underscore its significance in advancing smart forestry.

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“…This integration leverages the strengths of each system, improves positioning accuracy, and enhances the availability of satellite signals, especially in environments where signal blockages are common, including dense vegetation and other physical structures [42]. In terms of signal processing, the latest developments in multi-constellation receivers focus on advanced algorithms that optimize the utilization of signals from multiple constellations [43]. By combining signals from multiple constellations, the receivers can mitigate the effects of signal blockages, multipath interference, and ionospheric disturbances [44].…”

Section: Global Navigation Satellite Systemsmentioning

confidence: 99%

Global Navigation Satellite Systems as State-of-the-Art Solutions in Precision Agriculture: A Review of Studies Indexed in the Web of Science

2023

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Global Navigation Satellite Systems (GNSS) in precision agriculture (PA) represent a cornerstone for field mapping, machinery guidance, and variable rate technology. However, recent improvements in GNSS components (GPS, GLONASS, Galileo, and BeiDou) and novel remote sensing and computer processing-based solutions in PA have not been comprehensively analyzed in scientific reviews. Therefore, this study aims to explore novelties in GNSS components with an interest in PA based on the analysis of scientific papers indexed in the Web of Science Core Collection (WoSCC). The novel solutions in PA using GNSS were determined and ranked based on the citation topic micro criteria in the WoSCC. The most represented citation topics micro based on remote sensing were “NDVI”, “LiDAR”, “Harvesting robot”, and “Unmanned aerial vehicles” while the computer processing-based novelties included “Geostatistics”, “Precise point positioning”, “Simultaneous localization and mapping”, “Internet of things”, and “Deep learning”. Precise point positioning, simultaneous localization and mapping, and geostatistics were the topics that most directly relied on GNSS in 93.6%, 60.0%, and 44.7% of the studies indexed in the WoSCC, respectively. Meanwhile, harvesting robot research has grown rapidly in the past few years and includes several state-of-the-art sensors, which can be expected to improve further in the near future.

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Static Positioning under Tree Canopy Using Low-Cost GNSS Receivers and Adapted RTKLIB Software

Cited by 10 publications

References 57 publications

Raw GNSS data collected using smartphones and low-cost receiver under optimal and sub-optimal conditions

Raw GNSS data collected using smartphones and low-cost receiver under optimal and sub-optimal conditions

Sensors for Digital Transformation in Smart Forestry

Global Navigation Satellite Systems as State-of-the-Art Solutions in Precision Agriculture: A Review of Studies Indexed in the Web of Science

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