Prototyping a GNSS-Based Passive Radar for UAVs: An Instrument to Classify the Water Content Feature of Lands

Gamba, Micaela Troglia; Marucco, Gianluca; Pini, Marco; Ugazio, Sabrina; Falletti, Emanuela; Presti, Letizia Lo

doi:10.3390/s151128287

Cited by 25 publications

(13 citation statements)

References 26 publications

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“…Many designs for airborne GNSS-R sensors have been presented in the literature. For example the sensor presented by Troglia Gamba et al [48] implements a SDR based GNSS-R on an ODROID-X2 microprocessor able of receiving both the left-hand circular polarized (LHCP) and the right-hand circular polarized (RHCP) reflected signals using two front-ends streams. Esterhuizen and Akos [49] also presented a miniaturized receiver based on two GPS L1 front ends and a Nano-ITX Single Board Computer (SBC) to store raw signal samples, which were analyzed in post-processing [50].…”

Section: Introductionmentioning

confidence: 99%

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UAV-Based GNSS-R for Water Detection as a Support to Flood Monitoring Operations: A Feasibility Study

et al. 2019

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Signals from global navigation satellite systems (GNSS) can be utilized as signals of opportunity in remote sensing applications. Geophysical properties of the earth surface can be detected and monitored by processing the back-scattered GNSS signals from the ground. In the literature, several airborne GNSS-based passive radar experiments have been successfully demonstrated. With the advancements in small unmanned aerial vehicles (UAVs) and their applications for environmental monitoring, we want to investigate whether GNSS-based passive radar can provide valuable geospatial information from such platforms. Low-cost GNSS reflectometry sensors, developed using commercial of the shelf components, can be mounted onboard UAVs and flown to sense environmental parameters. This paper presents the results of a preliminary study to investigate the feasibility of utilizing data collected by UAV-based GNSS-R sensors to detect surface water for a potential application in supporting flood monitoring operations. The study was conducted in the area surrounding the Avigliana lakes in Northern Italy. The results show the possibility of detecting small water surfaces with few tens of meters resolution, and estimating the area of the lake surface with 92% accuracy. Furthermore, it is proved through simulations that the use of multi-GNSS increases this accuracy to about 99%.

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Section: Introductionmentioning

confidence: 99%

“…Estimate the performance of the GNSS-based passive radar developed by Troglia Gamba et al [48] in monitoring water surfaces on ground, when it is mounted on board a small UAV. This assessment could set-up a further source of geospatial data for the system developed in the I-REACT project [52].…”

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confidence: 99%

UAV-Based GNSS-R for Water Detection as a Support to Flood Monitoring Operations: A Feasibility Study

et al. 2019

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“…Other satellite missions have also demonstrated the capabilities of GNSS-R, which includes UK-DMC (United Kingdom -Disaster Monitoring Constellation) and SMAP (Soil Moisture Active Passive) [5,6]. Over the past quarter century, the GNSS-R theoretical framework has been greatly enhanced and its application has been extended from marine remote sensing [7][8][9][10][11][12][13] to land remote sensing [14][15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Snow Depth Estimation with GNSS-R Dual Receiver Observation

Wang

et al. 2019

Remote Sensing

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Two estimation methods using a dual GNSS (Global Navigation Satellite System) receiver system are proposed. The dual-frequency combination method combines the carrier phase observations of dual-frequency signals, whereas the single-frequency combination method combines the pseudorange and carrier phase observations of a single-frequency signal, both of which are geometry-free strictly combination and free of the effect of ionospheric delay. Theoretical models are established in the offline phase to describe the relationship between the spectral peak frequency of the combined sequence and the antenna height. A field experiment was conducted recently and the data processing results show that the root mean squared error (RMSE) of the dual-frequency combination method is 5.04 cm with GPS signals and 6.26 cm with BDS signals, which are slightly greater than the RMSE of 4.16 cm produced by the single-frequency combination method of L1 band with GPS signals. The results also demonstrate that the proposed two combination methods and the SNR method achieve similar performance. A dual receiver system enables the better use of GNSS signal carrier phase observations for snow depth estimation, achieving increased data utilization.

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“…Passive radar can be used to detect signal sources by sensing the corresponding RF signals [10]. Linear fusion has been employed previously [11] for target recognition in a passive multistatic radar system, and bistatic range measurements have been used to find the position of a target [12].…”

Section: Introductionmentioning

confidence: 99%

Passive Detection of Low-Altitude Signal Sources Using an Improved Cross-Correlation Algorithm

et al. 2018

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The passive detection of low-altitude signal sources is studied using an improved cross-correlation method in the time–frequency domain. A matching template is designed for signal cross-correlation, and a cross-correlation threshold is used to determine whether a signal source is present or not. An improved cross-correlation method is also proposed to estimate the direction of arrival and communication frequency of a signal source. Furthermore, the distance and signal-to-noise ratio are estimated using an energy detector. Outdoor data from a bridge in the Jimo District, Qingdao, and indoor data from a research laboratory are used for performance evaluation. The results obtained show that the proposed method can provide better passive detection of low-altitude signal sources compared to several well-known algorithms in the literature. In addition, this method is more suitable for long-distance detection.

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Prototyping a GNSS-Based Passive Radar for UAVs: An Instrument to Classify the Water Content Feature of Lands

Cited by 25 publications

References 26 publications

UAV-Based GNSS-R for Water Detection as a Support to Flood Monitoring Operations: A Feasibility Study

UAV-Based GNSS-R for Water Detection as a Support to Flood Monitoring Operations: A Feasibility Study

Snow Depth Estimation with GNSS-R Dual Receiver Observation

Passive Detection of Low-Altitude Signal Sources Using an Improved Cross-Correlation Algorithm

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