Your search keyword '"RADAR"' showing total 26,847 results

1. Deep learning-based LPI radar signals analysis and identification using a Nyquist Folding Receiver architecture

Author

Tao Wan, Hao Ji, Bin Tang, and Kaili Jiang

Subjects

Computer science, Mechanical Engineering, Metals and Alloys, Computational Mechanics, Perceptron, Signal, law.invention, Domain (software engineering), law, Frequency domain, Ceramics and Composites, Nyquist–Shannon sampling theorem, Time domain, Radar, Algorithm, Low probability of intercept radar

Abstract

Nyquist Folding Receiver (NYFR) is a perceptron structure that realizes a low probability of intercept (LPI) signal analog to information. Aiming at the problem of LPI radar signal receiving, the time domain, frequency domain, and time-frequency domain problems of signals intercepted by NYFR structure are studied. Combined with the time-frequency analysis (TFA) method, a radar recognition scheme based on deep learning (DL) is introduced, which can reliably classify common LPI radar signals. First, the structure of NYFR and its characteristics in the time domain, frequency domain, and time and frequency domain are analyzed. Then, the received signal is then converted into a time-frequency image (TFI). Finally, four kinds of DL algorithms are used to classify LPI radar signals. Simulation results demonstrate the correctness of the NYFR structure, and the effectiveness of the proposed recognition method is verified by comparison experiments.

Published

2023

2. Robustness Improvement for Chipless RFID Reading Using Polarization Separation

Author

Florian Requena, Nicolas Barbot, Darine Kaddour, Etienne Perret, Laboratoire de Conception et d'Intégration des Systèmes (LCIS), Université Grenoble Alpes (UGA)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Université Grenoble Alpes (UGA), and European Project: 772539,SCATTERERID

Subjects

[SPI.ELEC]Engineering Sciences [physics]/Electromagnetism, [SPI]Engineering Sciences [physics], Radar, Radiation, Chipless RFID, Scatterer, Chipless RFID Radar Reading method Robustness Scatterer Sensor, Electrical and Electronic Engineering, Robustness, Condensed Matter Physics, Reading method, Sensor

Abstract

International audience; In this paper, a novel method to improve the readability of chipless tags is presented. When the EM wave falls upon the tag's surface at normal incidence or with a known incidence, the proposed approach permits to obtain a higher signal-to-noise ratio (SNR) of resonators whose orientation with respect to the normal to the plane in which the tag is positioned is unknown and thus, to increase the reading distance of the tag. It introduces a technique based on the detection of this tag orientation in relation to the antennas; a projection of the signals will allow to correct this misalignment in order to always be able to decode the tag identifier on a signal that corresponds to an ideal alignment between the tag and the antennas. With this principle, it is also possible to separate the resonance mode of the resonator that is connected to the identifier from other parasitic resonance modes that may appear due to a possible misalignment between the tag and the antenna. This principle is applied to loop resonators commonly used in chipless RFID which can present strong parasitic modes of resonance. Also, this method makes the reading orientation invariant, allowing to read the resonator whatever its orientation with respect to the normal to the plane in which the tag is positioned. Likewise, the proposed method can be also used to sense this resonator orientation. This method requires a dual-polarization antenna and a 2-ports vector network analyzer (VNA). Results are validated in simulation and with real-environment measurements for a single resonator as well as for multiple resonators, as it is classically used in the chipless RFID technology. Measurements in a harsh environment, as well as comparisons with classical techniques such as time gating, are presented. A study on the improvment of the read range is achieved to highligth the potential of the proposed technique. A reading distance of more than 80cm was thus obtained, which represents 20cm more than with the classic use of a post-processor based on time gatting. Finally, the principle of the measurement is generalized by applying it to a tag with a ground plane and considering that the antenna is not necessarily placed in normal incidence with respect to the plane of the tag.

Published

2023

3. A Novel Method for Hidden Natural Caves Characterization and Accessibility Assessment From Spaceborne VHR SAR Images

Author

Leonardo Carrer, Davide Castelletti, Riccardo Pozzobon, Francesco Sauro, and Lorenzo Bruzzone

Subjects

Rocks, Vegetation mapping, Radar, very high-resolution (VHR) synthetic aperture radar (SAR), Spaceborne radar, Earth, Synthetic aperture radar, Radar imaging, Capella space, caves, lava tubes, planetary surfaces, General Earth and Planetary Sciences, Electrical and Electronic Engineering

Published

2023

4. Research, challenges and opportunities in software define radio technologies

Author

Jacob Abraham, Kanagaraj Venusamy, Antony Judice, Joel Livin A. Obtained, Hameed Shaik, and Kannadhasan Suriyan

Subjects

Software defined network, Internet of things, Radar, Logic, Hardware and Architecture, Wireless body area network, Sonar, Electrical and Electronic Engineering, Computer Science Applications

Abstract

The network extended not just internationally but also throughout a broad variety of application areas in this age, with healthcare being one of the most well-known and vital industries. Improvements in healthcare are possible if we start using the popular internet of things (IoT) technology as a key instead of focusing on other disciplines. Wireless body area network (WBAN) is a field in which we communicate with a network of human people and medical equipment that may be used in conjunction with internet of things technology to perform any function. Additional features for software defined networks will be added in the future. In the event of a critical crisis, the suggested suggestions will be to take care of the patient's life. Because the fitted equipment keeps a lot better eye on the patient than previously advised methods. This study combines WBAN, IoT, and software defined network (SDN) to make sense in the healthcare field.

Published

2023

5. In-Cabin MIMO Radar System for Human Dysfunctional Breathing Detection

Author

Lluis JOFRE-ROCA, Jordi Romeu, María José López Montero, Cesar Palacios Arias, Universitat Politècnica de Catalunya. Doctorat en Teoria del Senyal i Comunicacions, Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, and Universitat Politècnica de Catalunya. CommSensLab-UPC - Centre Específic de Recerca en Comunicació i Detecció UPC

Subjects

MIMO radar, Radar, Enginyeria de la telecomunicació::Radiocomunicació i exploració electromagnètica::Radar [Àrees temàtiques de la UPC], FMCW radar, mm-waves, Breathing patterns, Vehicles -- Mesures de seguretat, In-cabin, Respiració -- Mesurament, Respiration -- Measurement, Electrical and Electronic Engineering, Dysfunctional breathing, Elongation map, Vehicles -- Safety measures, Instrumentation

Abstract

The integration of wireless sensors into the automotive industry is making vehicles increasingly safe and autonomous. At present, vehicles are equipped with external sensors that facilitate maneuverability and braking and internal sensors that detect presence, seat belt state, and occupant vital signs. Early detection of dysfunctional breathing patterns can reduce the risk of accidents caused by drowsiness or fatigue. In this regard, this work presents an MIMO FMCW Radar System able to distinguish dysfunctional breathing patterns from human torso motion. The torso has been divided into six regions, and the amplitude of the elongation and the frequency of motion of each region have been measured during breathing. An elongation map is then constructed in order to graphically show the dysfunctional breathing patterns. The signal processing includes a peak search algorithm to detect elongation amplitude and a bandpass frequency filter to minimize dc components, random driver motion, and vehicle vibration. A torso elongation emulator phantom has been assembled with materials of skin-like relative permittivity and dc motors for calibration and validation of basic breathing patterns. Finally, the signal of the system is compared with that of a commercial respiration belt, and then the system is tested by performing measurements on people. The MIMO radar system is able to measure, differentiate, and classify patterns associated with dysfunctional breathing such as hyperventilation syndrome and thoracic dominant breathing. This work was supported in part by the Spanish “Comision Interministerial de Ciencia y Tecnologia” (CICYT) under Project PID2019-107885GB-C31 and Project MDM2016- 0600, in part by the Catalan Research Group under Grant 2017 SGR 219, and in part by the “Secretaría Nacional de Educación Superior, Ciencia, Tecnología e Innovación” (SENESCYT) from the Ecuadorian Government

Published

2022

6. Physical and Spectral Analysis of a Semi-Infinite Grounded Slab Illuminated by Plane Waves

Author

Vito Daniele, Guido Lombardi, and Rodolfo S. Zich

Subjects

Wiener–Hopf (WH) method, electromagnetic diffraction, integral equations, nearfield interactions, dielectric waveguide, Green’s function, Antenna technologies, electromagnetic scattering, grounded slab, leaky waves, optics, radar, surface waves, Electrical and Electronic Engineering

Published

2022

7. A Novel Approach to Unambiguous Doppler Beam Sharpening for Forward-Looking MIMO Radar

Author

Sen Yuan, Pascal Aubry, Francesco Fioranelli, and Alexander G. Yarovoy

Subjects

Beam scan, Radar imaging, Radar, Signal resolution, Sensors, Doppler radar, Radar antennas, Electrical and Electronic Engineering, MIMO radar processing, Doppler effect, Forward-looking radar, Instrumentation, Doppler beam sharpening

Abstract

The ambiguity problem of targets in Doppler beam sharpening (DBS) with forward-looking radar is considered. While DBS is proposed earlier to improve the angular resolution of the radar while keeping the antenna aperture size limited, such a solution suffers from ambiguities in the case of targets positioned symmetrically with respect to the platform movement. To address this problem, an approach named unambiguous Doppler-based forward-looking multiple-input multiple-output (MIMO) radar beam sharpening scan (UDFMBSC) is proposed, based on the combination of MIMO processing and DBS. The performance of the proposed method is compared to existing approaches using simulated data with point-like and extended targets. The method is successfully verified using experimental data.

Published

2022

8. Benchmarking Classification Algorithms for Radar-Based Human Activity Recognition

Author

Francesco Fioranelli, Simin Zhu, and Ignacio Roldan

Subjects

Benchmark testing, Radar imaging, Classification algorithms, Radar, Sensors, Space and Planetary Science, Doppler radar, human activity recognition (HAR), Radar applications, radar data, Aerospace Engineering, Electrical and Electronic Engineering, Spectrogram

Abstract

Linked to the increasing availability of datasets for radar-based human activity recognition (HAR), in this Student Highlights contribution, we report on a classification project that a group of 23 graduate students performed at TU Delft. The students were asked to work in groups of 2-3 members and to use the publicly available University of Glasgow dataset to develop the best classification pipeline as possible. This involved development and justification of both choices for the preprocessing techniques on the radar data (e.g., time-frequency distributions and cleaning of the signatures), and for the classification algorithms (e.g., the type of the algorithm, the hyperparameters' selection, the training-validation-testing split). While this student activity was performed at a small scale and with educational rather than research aims, we are happy to report it to the AESS readership, as we believe that such initiatives with open datasets sharing and classification algorithm benchmarking are beneficial for the wider radar research community. Furthermore, a list of publicly available datasets for radar-based HAR that can be used for similar initiatives is also reported in this article.

Published

2022

9. Learning on Multistatic Simulation Data for Radar-Based Automotive Gesture Recognition

Author

Nicolai Kern, Julian Aguilar, Timo Grebner, Benedikt Meinecke, and Christian Waldschmidt

Subjects

Radar, Ellipsometry, Radiation, Ellipsoids, radar sensor networks, Data models, Computational modeling, Convolutional Neural Network, Data Augmentation, Condensed Matter Physics, Automotive radar, Solid modeling, DDC 620 / Engineering & allied operations, Training, ddc:620, Electrical and Electronic Engineering, Gesture recognition (Computer science), Gestenerkennung, human target simulation

Abstract

Radar-based gesture recognition can play a vital role in autonomous vehicles’ interaction with vulnerable road users (VRUs). However, in automotive scenarios the same gesture produces strongly differing radar responses owed to the wide range of variations such as position, orientation, or ego-motion. Since including all kinds of modifications in a measured dataset is laborious, gesture simulations alleviate the measurement effort and increase the robustness against edge and corner cases. Hence, this paper presents a flexible geometric human target model allowing the direct introduction of a wide range of modifications, while it facilitates the handling of shadowing effects and multiradar constellations. Using the proposed simulation model, a dataset recorded with a radar sensor network consisting of three chirp sequence (CS) radars is resimulated based on motion data simultaneously captured with a stereo video system. Completely substituting the measured by simulated data for training, a convolutional neural network (CNN) classifier still achieves 80.4% cross-validation accuracy on a challenging gesture set, compared to 89.4% for training on measured data. Moreover, using simulated data the classifier is shown to successfully generalize to new scenarios not observed in measurements., acceptedVersion

Published

2022

10. An Efficient Track-Before-Detect for Multi-PRF Radars With Range and Doppler Ambiguities

Author

Wujun Li, Wei Yi, Lingjiang Kong, Kah Chan Teh, and School of Electrical and Electronic Engineering

Subjects

Radar, Electrical and electronic engineering [Engineering], Aerospace Engineering, Electrical and Electronic Engineering, Radar Tracking

Abstract

This article considers the detection and tracking of weak targets in multiple pulse repetition frequency (multi-PRF) radars using the track-before-detect (TBD) technique. By exploring the measurement independence among different PRFs, we decompose the joint multi-PRF and multiframe optimization problem into several lower dimensional maximizations, each of which corresponds to an intra-PRF multiframe processing. An efficient two-stage TBD procedure with a parallel structure is proposed for the multi-PRF radars. Specifically, in the first stage, a constraint inequality is derived analytically and used to decouple the measurement ambiguities from the nonlinear conversion relationship between polar and Cartesian coordinates. The intra-PRF multiframe integration can then be carried out concurrently using the ambiguous measurements and the target-like measurement plot sequences with different ambiguities are extracted for different PRFs. In the second stage, a covariance combination fusion-based inter-PRF joint disambiguation and estimation algorithm is proposed to solve the ambiguities of the plot sequences and output high-Accuracy target tracks. Simulation experiments show that the proposed algorithm can provide a good detection performance and higher tracking accuracy with much lower complexity. This work was supported in part by the National Natural Science Foundation of China under Grant 61771110, Grant U19B2017, and Grant 61871103, in part by the Fundamental Research Funds of Central Universities under Grant ZYGX2020ZB029, in part by Chang Jiang Scholars Program and the 111 Project under Grant B17008, and in part by the China Scholarship Council.

Published

2022

11. Dynamic Microwave Imaging of the Cardiovascular System Using Ultra-Wideband Radar-on-Chip Devices

Author

Timo Lauteslager, Mathias Tommer, Tor S. Lande, and Timothy G. Constandinou

Subjects

Diagnostic Imaging, Radar, Biomedical Engineering, Humans, Heart, Microwaves, Microwave Imaging

Abstract

Microwave imaging has been investigated for medical applications such as stroke and breast imaging. Current systems typically rely on bench-top equipment to scan at a variety of antenna positions. For dynamic imaging of moving structures, such as the cardiovascular system, much higher imaging speeds are required than what has thus far been reported. Recent innovations in radar-on-chip technology allow for simultaneous high speed data collection at multiple antenna positions at a fraction of the cost of conventional microwave equipment, in a small and potentially portable system. The objective of the current work is to provide proof of concept of dynamic microwave imaging in the body, using radar-on-chip technology.Arrays of body-coupled antennas were used with nine simultaneously operated coherent ultra-wideband radar chips. Data were collected from the chest and thigh of a volunteer, with the objective of imaging the femoral artery and beating heart. In addition, data were collected from a phantom to validate system performance. Video data were constructed using beamforming.The location of the femoral artery could successfully be resolved, and a distinct arterial pulse wave was discernable. Cardiac activity was imaged at locations corresponding to the heart, but image quality was insufficient to identify individual anatomical structures. Static and differential imaging of the femur bone proved unsuccessful.Using radar chip technology and an imaging approach, cardiovascular activity was detected in the body, demonstrating first steps towards biomedical dynamic microwave imaging. The current portable and modular system design was found unsuitable for static in-body imaging.This first proof of concept demonstrates that radar-on-chip could enable cardiovascular imaging in a low-cost, small and portable system. Such a system could make medical imaging more accessible, particularly in ambulatory or long-term monitoring settings.

Published

2022

12. Exploring the combined use of SMAP and Sentinel-1 data for downscaling soil moisture beyond the 1 km scale

Author

Karsten Høgh Jensen, Mie Andreasen, Majken C. Looms, Simon Stisen, Rena Meyer, Søren Julsgaard Kragh, Rasmus Fensholt, and Wenmin Zhang

Subjects

CALIBRATION, DYNAMICS, Backscatter, MODELS, Land cover, Vegetation, Spatial distribution, RADAR, VALIDATION, PRODUCTS, Temporal resolution, Environmental science, General Earth and Planetary Sciences, NETWORK, Scale (map), Water content, Remote sensing, Downscaling, General Environmental Science

Abstract

Soil moisture estimates at high spatial and temporal resolution are of great value for optimizing water and agricultural management. To fill the gap between local ground observations and coarse spatial resolution remote sensing products, we use Soil Moisture Active Passive (SMAP) and Sentinel-1 data together with a unique data set of ground-based soil moisture estimates by cosmic ray neutron sensors (CRNS) and capacitance probes to test the possibility of downscaling soil moisture to the sub-kilometre resolution. For a high-latitude study area within a highly heterogeneous landscape and diverse land use in Denmark, we first show that SMAP soil moisture and Sentinel-1 backscatter time series correlate well with in situ CRNS observations. Sentinel-1 backscatter in both VV and VH polarizations shows a strong correlation with CRNS soil moisture at higher spatial resolutions (20–400 m) and exhibits distinct and meaningful signals at different land cover types. Satisfactory statistical correlations with CRNS soil moisture time series and capacitance probes are obtained using the SMAP Sentinel-1 downscaling algorithm. Accounting for different land use in the downscaling algorithm additionally improved the spatial distribution. However, the downscaling algorithm investigated here does not fully account for the vegetation dependency at sub-kilometre resolution. The study suggests that future research focussing on further modifying the downscaling algorithm could improve representative soil moisture patterns at a fine scale since backscatter signals are clearly informative. Highlights. Backscatter produces informative signals even at high resolutions. At the 100 m scale, the Sentinel-1 VV and VH polarizations are soil moisture dependent. The downscaling algorithm is improved by introducing land-cover-dependent clusters. The downscaled satellite and CRNS soil moisture agree best at the agricultural site.

Published

2022

13. Integrating CSI Sensing in Wireless Networks: Challenges to Privacy and Countermeasures

Author

Renato Lo Cigno, Francesco Gringoli, Marco Cominelli, and Lorenzo Ghiro

Subjects

Privacy, Wireless networks, Radar, Massive MIMO, Machine learning, Radar tracking, Physical layer, 6G mobile communication, Quality of service, Telecommunication network performance, Telecommunication network reliability, Radar, Physical layer, 6G mobile communication, Computer Networks and Communications, Telecommunication network performance, Telecommunication network reliability, Radar tracking, Quality of service, Privacy, Hardware and Architecture, Machine learning, Wireless networks, Massive MIMO, Software, Information Systems

Published

2022

14. From ice core to ground-penetrating radar: representativeness of SMB at three ice rises along the Princess Ragnhild Coast, East Antarctica

Author

Marie G.P. Cavitte, Hugues Goosse, Sarah Wauthy, Thore Kausch, Jean-Louis Tison, Brice Van Liefferinge, Frank Pattyn, Jan T.M. Lenaerts, Philippe Claeys, Analytical, Environmental & Geo-Chemistry, and UCL - SST/ELI/ELIC - Earth & Climate

Subjects

Antarctic glaciology, ice rise, ground-penetrating radar, Accumulation, surface mass balance, glaciology, spatial representativity, accumulation, ice core, groundpenetrating radar, radar, Earth-Surface Processes

Abstract

The future contributions of the Antarctic Ice Sheet to sea level rise will depend on the evolution of its surface mass balance (SMB), which could amplify/dampen mass losses increasingly observed at the ice sheet's edge. In situ constraints of SMB over annual-to-decadal timescales consist mostly of firn/ice cores that have a surface footprint $\sim$cm$^{2}$. SMB constraints also come from climate models, which have a higher temporal resolution but a larger surface footprint of several km$^{2}$. We use ice-penetrating radar data to obtain an intermediate spatial and temporal resolution SMB record over three ice rises along the Princess Ragnhild Coast. The co-located ice cores allow us to obtain absolute radar-derived SMB rates at a multi-annual-to-decadal temporal resolution. By comparing the ice core SMB measurements and the radar-derived SMB records, we determine that pointwise measurements of SMB are representative of a small surface area, $\sim 200-500$ m radius extending from the ice core drill site for the ice rises studied here, and that the pointwise measurements are systematically 7–15 cm w.e. a$^{-1}$ lower than the mean SMB value calculated for the whole ice rises. However, ice core records are representative of an entire ice rise's temporal variability at the temporal resolution examined.

Published

2022

15. Joint In-Band Full-Duplex Communication and Radar Processing

Author

Andre Bourdoux, Seyed Ali Hassani, Sofie Pollin, Barend van Liempd, and François Horlin

Subjects

Computer Networks and Communications, Computer science, Hand/body gesture detection, Throughput, Sciences de l'ingénieur, Communications system, law.invention, law, in-band full-duplex, opportunistic radar, Electrical and Electronic Engineering, Radar, radar-communication (RadCom), business.industry, Node (networking), self-interference cancellation, Computer Science Applications, Adaptive filter, Control and Systems Engineering, Wi-Fi sensing ,wireless sensing, Radio frequency, State (computer science), Transceiver, business, Computer hardware, Information Systems

Abstract

In-band full-duplex (IBFD) technology has the potential to not only double the communication throughput but also enable additional capabilities. The fusion of radar and communication subsystems is an excellent example of how IBFD facilitates integration of radar functionality into a communication system. Developing and analysis of a joint IBFD radar-communication (RadCom) system is at the core of this article. This system derives the range-Doppler image from the state of an adaptive filter, which already exists in a typical IBFD transceiver. Our approach is waveform-independent and reuses the radio frequency (RF) front-end while it requires little additional digital logic. The proposed system is prototyped to assess the modem-radar coexistence in a real-world IBFD communication link budget. Employing the prototyped system, we quantify the additional required logic resources and investigate whether such a RadCom approach dictates a tradeoff between the two intended functionalities. The experimental results show that the proposed solution enables a communication system to detect targets within 20 m while maintaining an IBFD link with another communication node, info:eu-repo/semantics/published

Published

2022

16. Model-Based Representation and Deinterleaving of Mixed Radar Pulse Sequences With Neural Machine Translation Network

Author

Yunjie Li, Shafei Wang, and Mengtao Zhu

Subjects

Sequence, Computer science, Aerospace Engineering, Pulse sequence, Pulse (physics), law.invention, Noise, Time of arrival, law, Minification, Electrical and Electronic Engineering, Radar, Representation (mathematics), Algorithm

Abstract

Deinterleaving mixtures of radar pulse sequences is the first and the most vital step for modern electronic reconnaissance systems to intercept and analyze the intentions of non-cooperative radars. Currently, these systems are facing great challenges due to the emerging complexity of radar modulations. This paper proposes a novel method for deinterleaving mixtures of radar pulse sequences based on the time series characteristics of each source (component pulse sequences). Firstly, the mathematical representations are established to describe the structural characteristics of each source. Then, the deinterleaving problem is formulated as a minimization of a maximum-likelihood cost function that can be solved efficiently through a supervised neural machine translation (NMT) network, i.e. to translate each received pulse in the interleaved pulse sequence to the corresponding source label. A sequence-to-sequence NMT model is proposed to capture the structural relationships among the non-adjacent pulses originated from the same source in the mixtures and assign the corresponding label to each pulse. The proposed method does not require the exact knowledge of each component pulse sequence. The experimental results based on the time of arrival sequence of mixed pulse sequences show that the proposed method outperforms the state-of-the-art deinterleaving methods and achieves satisfactory performance under highly non-ideal situations with measuring noise and lost pulse conditions. The proposed method can be directly applied to other fields involving deinterleaving problems and multi-variate input conditions.

Published

2022

17. An Image-Based Radar Detector Approaching Optimal Likelihood Ratio Detector

Author

Xianrong Wan, Jianxin Yi, Jianxuan Yang, Henry Leung, and Yunhua Rao

Subjects

Optics, law, business.industry, Computer science, Detector, Aerospace Engineering, Electrical and Electronic Engineering, Radar, business, Image based, law.invention

Published

2022

18. CMOS Automotive Radar Sensors: mm-Wave Circuit Design Challenges

Author

Egidio Ragonese, Giuseppe Papotto, Claudio Nocera, Andrea Cavarra, and Giuseppe Palmisano

Subjects

fully depleted (FD) silicon-on-insulator (SOI), Radar, CMOS mm-wave receiver, Sensors, power amplifier, transformers, Transistors, transformer-based VCO, CMOS technology, Receivers, electromagnetic (EM) simulations, Inductors, Gain, Electrical and Electronic Engineering

Published

2022

19. Use of the LunAero Open-Source Hardware Platform to Enhance the Accuracy and Precision of Traditional Nocturnal Migration Bird Counts

Author

Wesley T, Honeycutt and Eli S, Bridge

Subjects

Birds, Radar, Computers, Flight, Animal, Animals, Animal Migration, Animal Science and Zoology, Plant Science

Abstract

Quantification of nocturnal migration of birds through moon watching is a technique ripe for modernization with superior computational power. In this paper, collected by a motorized telescope mount was data analyzed using both video observations by trained observers and modernized approaches using computer vision. The more advanced data extraction used the OpenCV library of computer vision tools to identify bird silhouettes by means of image stabilization and background subtraction. The silhouettes were sanitized and analyzed in sequence to produce stacked relationships between temporally close contours, discriminating birds from noise based on the assumption that birds migrate in stable paths. The flight ceiling of the birds was determined by extracting relevant correlation coefficient data from doppler radar co-located with the LunAero instrument in Norman, OK, USA using a method with low-computational overhead. The bird paths and flight ceiling were combined with lunar ephemera to provide input for the original method used for nocturnal migration quantification as well as an enhanced version of the same method with more advanced computational tools. We found that the manual quantification of migration activity detected 16,300 birds/km•h heading northwest from 110°, whereas the automated analysis reported a density of 43,794 birds/km•h heading northwest from 106.67°. Hence, there was agreement with regard to flight direction, but the automated method overestimated migration density by approximately three times. The reasons for the discrepancy between flight path detection appeared to be due to a substantial amount of noise in the video data as well as a tendency for the computer vision analysis to split single flight paths into two or more segments. The authors discuss ongoing innovations aimed at addressing these methodological challenges.

Published

2022

20. Hydrometeorological evaluation of two nowcasting systems for Mediterranean heavy precipitation events with operational considerations

Author

Véronique Ducrocq, Béatrice Vincendon, and Alexane Lovat

Subjects

Mediterranean climate, Nowcasting, Meteorology, law, Flash flood, Environmental science, Hydrometeorology, Precipitation, Radar, Numerical weather prediction, Lead time, law.invention

Abstract

Heavy precipitation events and subsequent flash floods regularly affect the Mediterranean coastal regions. In these situations, forecasting rainfall and river discharges is crucial especially up to 6 h, which is a relevant lead time for emergency services in times of crisis. The present study investigates the hydrometeorological skills of two new nowcasting systems: a numerical weather model AROME-NWC and a nowcasting system blending numerical weather prediction and extrapolation of radar estimation called PIAF. Their performance is assessed for 10 past heavy precipitation events that occurred in southeastern France. Precipitation forecasts are evaluated at a 15- min time resolution and the availability times of forecasts, based on the operational Météo-France suites, are taken into account when performing the evaluation. Rainfall observations and forecasts were first compared using a point-to-point approach. Then the evaluation was conducted from an hydrological point of view, by comparing observed and forecast precipitation over watersheds affected by floods. In general, the results led to the same conclusions for both evaluations. On the very first lead times, up to 1 h 15 min and 1 h 30 min of forecast, the performance of PIAF was higher than AROME-NWC. For longer lead times (up to 3 h) their performances were generally equivalent. An assessment of river discharges simulated with the ISBA-TOP coupled system, which is dedicated to Mediterranean flash flood simulations and driven by AROME-NWC and PIAF rainfall forecasts, was also performed on two exceptional past flash flood events. The results obtained for these two events show that using AROME-NWC or PIAF rainfall forecasts is promising for flash flood forecasting in terms of peak intensity, timing, and first wave of discharge, with an anticipation of these phenomena that can reach several hours.

Published

2022

21. 2019 Mw 5.9 Mirpur, Pakistan Earthquake: Insights from Integrating Geodetic, Seismic, and Field Observations

Author

Adnan Barkat, Farhan Javed, Yen Joe Tan, Aamir Ali, Muhammad Tahir Javed, Nabeel Ahmad, Muhammad Awais, Muhammad Ali Shah, Talat Iqbal, Barkat, Adnan, Javed, Farhan, Joe Tan, Yen, Ali, Aamir, Javed, MUHAMMAD TAHIR, Ahmad, Nabeel, Awais, Muhammad, Ali Shah, Muhammad, and Iqbal, Talat

Subjects

HIMALAYA, Geophysics, GPS, SOURCE PARAMETERS, RESERVOIR, SURFACE DEFORMATION, RADAR

Abstract

On 24 September 2019, an Mw 5.9 earthquake struck near the Mangla reservoir in northeastern Pakistan and resulted in 39 fatalities and 746 serious injuries, making it the deadliest earthquake in the region since the 2005 Mw 7.6 Kashmir earthquake. Here, we integrate geodetic, seismic, and field observations to characterize the source properties and impact of the Mirpur earthquake as well as investigate whether it might be a reservoir-induced event. From inverting Interferometric Synthetic Aperture Radar data, we find that a fault with strike ∼310°, dip ∼6°, and rake ∼117° is the optimal source, with slip concentrated between 5 and 6 km depth. This is consistent with our relocated aftershocks depth distribution and the lack of surface rupture observed in the field. Therefore, we infer that the earthquake ruptured the Main Himalayan Thrust (MHT). The event’s shallow depth might explain the extensive damage caused despite its moderate magnitude, with a maximum shaking intensity of VIII based on our field survey. The survey also revealed extensive damages associated with earthquake-induced liquefaction. Our modeling shows that loading due to increased reservoir water level in the three months before the Mirpur earthquake led to Coulomb stress increase of ∼7–10 kPa on the rupture plane. However, this effect is ∼10 times smaller than the Coulomb stress increase due to the 2006 Mangla earthquake, and the Mirpur earthquake only occurred ∼1–2 weeks after peak water level. These suggest that pore pressure diffusion contributed to promoting the fault rupture at a time when it is close to failure due to accumulated stress from inter-seismic loading. Because the Mirpur earthquake resulted in a stress increase of >0.2 MPa on the surrounding sections of the MHT and nearby faults, future rupture of these faults is a significant hazard and proper management of reservoir operations is necessary to prevent further elevating the seismic risk.

Published

2022

22. Generation of Human Micro-Doppler Signature Based on Layer-Reduced Deep Convolutional Generative Adversarial Network

Author

Mahdi Ostovan, Sadegh Samadi, and Alireza Kazemi

Subjects

Radar, Article Subject, General Computer Science, General Mathematics, General Neuroscience, Humans, Computer Simulation, Neural Networks, Computer, General Medicine

Abstract

Human activity recognition (HAR) using radar micro-Doppler has attracted the attention of researchers in the last decade. Using radar for human activity recognition has been very practical because of its unique advantages. There are several classifiers for the recognition of these activities, all of which require a rich database to produce fine output. Due to the limitations of providing and building a large database, radar micro-Doppler databases are usually limited in number. In this paper, a new method for the generation of radar micro-Doppler of the human body based on the deep convolutional generating adversarial network (DCGAN) is proposed. To generate the database, the required input is also generated by converting the existing motion database to simulated model-based radar data. The simulation results show the success of this method, even on a small amount of data.

Published

2022

23. Population Source of Third-Generation Oriental Armyworm in Jilin, China, Determined by Entomology Radar, Trajectory Analysis, and Mitochondrial COI Sequences

Author

Wei Sun, Gao Hu, Qianfu Su, Yangzhou Wang, Wei Yang, Jiachun Zhou, and Yuebo Gao

Subjects

China, Radar, Ecology, Larva, Insect Science, fungi, Animals, Moths, Spodoptera, Ecology, Evolution, Behavior and Systematics

Abstract

The armyworm, Mythimna separata (Walker) (Lepidoptera: Noctuidae), is an important polyphagous pest with a strong migratory ability. Recently, third-generation larvae have become an increasingly serious pest threat in Jilin Province of northeast China. To investigate the population source of this species, scanning entomological radar observations and insect mitochondrial cytochrome oxidase I (COI) genes were used in this study. Five main results were found: (1) The peak period in captured second-generation moths was from mid to late July. The temperature and wind speeds were optimum for the moths to have migrated. Strong southwesterly winds occurred during the peak migration period. (2) Radar observations indicated that most of the moths’ migration took place at a height of 600 m, often in a dense layer which formed at heights of 350–800 m. (3) Analyses of adult ovarian development and larval haplotypes showed third-generation larvae were progeny of both locally produced progeny and immigrant moths. (4) Based on our back-tracking and haplotype analyses, immigration led to an outbreak originated in the same source area to the southwest. (5) Emigration of second-generation moths was confirmed by both radar observation and mtDNA analysis. Forward trajectories indicated that the moths were capable of immigrating far from their overwintering range. These results are useful for improving the forecasting systems of this insect pest species.

Published

2022

24. Nominal Body Contour Reconstruction for Millimeter-Wave Characterization of Suicide Bomber Explosives

Author

Carey M. Rappaport and Mohammad M. Tajdini

Subjects

Scanner, business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, law.invention, Ranking, law, Extremely high frequency, Metric (mathematics), Imaging technology, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, Radar, Wideband, business, Fourier series

Abstract

In order to improve the speed of passenger screening while preserving the effective capability to detect more sophisticated threats, airport security imaging systems must be able to accurately characterize concealed body-worn objects. In addition to improving the passenger experience, this system capability will enhance airport security for the traveling public. This paper presents a real-time, fully-automatic algorithm for the wideband millimeter-wave (mm-wave) radar reconstruction of the nominal human body contours, even in the presence of an affixed weak dielectric object or when a portion of the body cross-section is not captured by the imaging scanner. The algorithm extracts the main contours from a noisy collection of 3D reconstructed reflectivity and approximates the nominal human body cross-section via fitting a low order angular Fourier series. This important step is essential for precise characterization of concealed body-worn explosives. A ranking algorithm is developed as a metric for the nominal body reconstruction accuracy. We verify the developed algorithm by applying it to the actual images of the High Definition-Advanced Imaging Technology (HD-AIT) system, a laboratory prototype mm-wave scanning system developed recently by the US Department of Homeland Security (DHS). The reconstructed body contours may be used to estimate the electric permittivity of the concealed person-worn objects.

Published

2022

25. Constrained Contextual Bandit Learning for Adaptive Radar Waveform Selection

Author

Anthony F. Martone, Charles E. Thornton, and R. Michael Buehrer

Subjects

Signal Processing (eess.SP), FOS: Computer and information sciences, Computer Science - Machine Learning, Sequence, Computer science, Computer Science - Information Theory, Information Theory (cs.IT), Process (computing), Aerospace Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Machine Learning (cs.LG), law.invention, Constraint (information theory), law, FOS: Electrical engineering, electronic engineering, information engineering, Waveform, Electrical Engineering and Systems Science - Signal Processing, Electrical and Electronic Engineering, Radar, Thompson sampling, Algorithm, Selection (genetic algorithm), Communication channel

Abstract

A sequential decision process in which an adaptive radar system repeatedly interacts with a finite-state target channel is studied. The radar is capable of passively sensing the spectrum at regular intervals, which provides side information for the waveform selection process. The radar transmitter uses the sequence of spectrum observations as well as feedback from a collocated receiver to select waveforms which accurately estimate target parameters. It is shown that the waveform selection problem can be effectively addressed using a linear contextual bandit formulation in a manner that is both computationally feasible and sample efficient. Stochastic and adversarial linear contextual bandit models are introduced, allowing the radar to achieve effective performance in broad classes of physical environments. Simulations in a radar-communication coexistence scenario, as well as in an adversarial radar-jammer scenario, demonstrate that the proposed formulation provides a substantial improvement in target detection performance when Thompson Sampling and EXP3 algorithms are used to drive the waveform selection process. Further, it is shown that the harmful impacts of pulse-agile behavior on coherently processed radar data can be mitigated by adopting a time-varying constraint on the radar's waveform catalog., Comment: 16 pages, 9 figures. arXiv admin note: text overlap with arXiv:2010.15698

Published

2022

26. Mobile multimedia computing in cyber-physical surveillance services through UAV-borne Video-SAR: A taxonomy of intelligent data processing for IoMT-enabled radar sensor networks

Author

Mohammad Reza Khosravi and Sadegh Samadi

Subjects

Synthetic aperture radar, Data processing, Multidisciplinary, Multimedia, Computer science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Cyber-physical system, computer.software_genre, Supercomputer, law.invention, Remote sensing (archaeology), law, Radar imaging, ComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMS, The Internet, Radar, business, computer

Abstract

This study investigates the different aspects of multimedia computing in Video Synthetic Aperture Radar (Video-SAR) as a new mode of radar imaging for real-time remote sensing and surveillance. This research also considers new suggestions in the systematic design, research taxonomy, and future trends of radar data processing. Despite the conventional modes of SAR imaging, Video-SAR can generate video sequences to obtain online monitoring and green surveillance throughout the day and night (regardless of light sources) in all weathers. First, an introduction to Video-SAR is presented. Then, some specific properties of this imaging mode are reviewed. Particularly, this research covers one of the most important aspects of the Video-SAR systems, namely, the systematic design requirements, and also some new types of visual distortions which are different from the distortions, artifacts and noises observed in the conventional imaging radar. In addition, some topics on the general features and high-performance computing of Video-SAR towards radar communications through Unmanned Aerial Vehicle (UAV) platforms, Internet of Multimedia Things (IoMT), Video-SAR data processing issues, and real-world applications are investigated.

Published

2022

27. Realization of High-Gain Low-Sidelobe Wide-Sector Beam Using Inductive Diaphragms Loaded Slotted Ridge Waveguide Antenna Array for Air Detection Applications

Author

Tao Su, Jinshan Ding, Yu-Tong Zhao, Jianzhong Chen, Min Bao, Tian Hu, and Liang Li

Subjects

Beamforming, Physics, business.industry, law.invention, Antenna array, Beamwidth, Optics, law, Radar imaging, Equivalent circuit, Power dividers and directional couplers, Electrical and Electronic Engineering, Radar, Antenna (radio), business

Abstract

This paper presents a high-gain slotted ridge waveguide array antenna (SRWAA) with inductive diaphragms, which can realize a wide-sector beam with a low sidelobe simultaneously. The proposed antenna can cover a wide detection range and avoid interference from other directions. The expected excitation distribution for the antenna array is extracted through a beamforming method. To reduce the influence of the dispersion phenomenon on signal quality, inductive diaphragms are inserted into the sidewall of the ridge waveguide, which is fully analyzed from the point of the equivalent circuit. A cut-off-mode power divider is utilized, which can control the power ratio flexibly. A SRWAA working at 24.125 GHz, including a six-way feeding network, and a 6×24 slot array with the size of 330 mm × 66.8 mm is designed and fabricated. The measured sidelobe level (SLL) and half-power beamwidth (HPBW) in the elevation plane are -19.6 dB and 54.41°, with the counterparts in the azimuth plane -29.8 dB and 3.15°, respectively. The measured peak gain is 22.3 dBi at 24.125 GHz. The measured results are in good agreement with the simulated ones. This work has the potential to be applied in air detection, anti-unmanned aerial vehicles (UAVs), meteorological radar, and imaging radar.

Published

2022

28. Enhanced interfacial polarization of biomass-derived porous carbon with a low radar cross-section

Author

Jialing Wang, Ming Zhou, Zhengchan Xie, Xingyu Hao, Shaolong Tang, Jingwen Wang, Zhongqiu Zou, and Guangbin Ji

Subjects

Biomaterials, Radar, Colloid and Surface Chemistry, Biomass, Microwaves, Porosity, Carbon, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Ultra-thin microwave absorbers have been urgently demanded for electromagnetic applications in recent years. Herein, porous carbon with a "flower cluster" microstructure was synthesized from biomass waste (mango seeds) by a facile activation and carbonization method. The novel structure reduced the density and also improved the impedance matching, dipole polarization, and provided many carbon matrix-air interfaces for interfacial polarization, resulting in superior microwave absorption performance. At an ultra-thin thickness of 1.5 mm, extraordinary microwave absorption was achieved, with a reflection loss (RL) of -42 dB. The effective absorption bandwidth reached 4.2 GHz. The RL can be further improved to -68.4 dB by adjusting the amount of activator to manipulate the structure of porous carbon. In addition, from the simulated radar scattering results, the maximum reduction in the radar cross-section (RCS) reached 30.4 dBm

Published

2022

29. Robust Copula-Based Detection of Shallow-Buried Landmines With Forward-Looking Radar

Author

Abdelhak M. Zoubir, Fauzia Ahmad, and Afief Dias Pambudi

Subjects

law, Computer science, Forward looking, Copula (linguistics), Aerospace Engineering, Data mining, Electrical and Electronic Engineering, Radar, computer.software_genre, computer, law.invention

Published

2022

30. Range-Dependent Ambiguous Clutter Suppression for Airborne SSF-STAP Radar

Author

Xie W. Chong, Yongliang Wang, and Wei Chen

Subjects

Computer science, Covariance matrix, Acoustics, Conformal antenna, Aerospace Engineering, Slant range, Signal, law.invention, Bistatic radar, law, Waveform, Clutter, Electrical and Electronic Engineering, Radar

Abstract

Range-dependent clutter suppression is a challenging problem in non-sidelooking (NSL), bistatic, and conformal antenna array airborne radar, especially in the presence of range ambiguity. Superimposed stepped frequency (SSF) radar employs a small frequency increment across the stepped signals in each pulse, which induces a dimension related to slant range. In this paper, an airborne radar framework is established with SSF signal as the transmit waveform. Thus, a two-stage adaptive clutter suppression method is proposed which utilizes the degrees of freedom in range, space and time domains provided by airborne SSF radar. In the first stage, the secondary range dependence compensation (SRDC) approach is adopted to distinguish the clutter of each range region in the carrier frequency domain. Then, a target-free covariance matrix is estimated by the compensated data, and the covariance matrix is used for the range-ambiguous clutter separation in the carrier frequency domain. Thus, the space-time snapshot of each range region can be extracted. In the second stage, a clutter segmentation processing method is devised for residual clutter suppression.

Published

2022

31. Adaptive Mutual Coupling Compensation Method for Airborne STAP Radar With End-Fire Array

Author

Yuanyi Xiong and Wenchong Xie

Subjects

Physics, Coupling, law, Acoustics, Aerospace Engineering, Electrical and Electronic Engineering, Radar, law.invention, Compensation (engineering)

Published

2022

32. IBIS-FM radar as a tool for monitoring hill slopes during excavations in hydropower projects: A case study from Bhutan Himalayas

Author

Karma Tshewang, Naveen Chander Bansal, Jigme Wangchuk, Jamyang Chophel, and K.R. Praveen

Subjects

Ibis, biology, business.industry, Foundation (engineering), Abutment, Excavation, Landslide, biology.organism_classification, law.invention, Mining engineering, law, Gravity dam, Radar, business, Hydropower, Geology

Abstract

Excavation is common in the construction of hydropower projects. Monitoring for both stable and unstable slopes is a pressing requirement during progressive excavations with or without cut-slope support measures. The present study is about an excavation carried out in a proposed concrete gravity dam site on the right bank slope of the Punatsangchhu River in western Bhutan. During the excavation, the right bank abutment witnessed multiple events of slope failures of various magnitudes. One major landslide occurred on 23 July 2013 in the toe of the right abutment, where foliation/multiple sheared/fractured zones/seams in quartz-feldspathic biotite gneiss dip towards the valley. During further excavations/piling works, a subsequent landslide on the downstream, within the body of the July 2013 landslide, occurred on 12 August 2016. As a result, a real-time monitoring of the slope became necessary to facilitate further excavations for achieving the dam foundation. Thus, the advanced slope monitoring instrument like Image By Interferometric Survey – Frequency Modulated (IBIS-FM) radar was deployed for monitoring the right bank slope during the excavation for the construction of ∼129 m high dam. The displacement of the hill slope is assessed based on this system by monitoring point locations as well as areas by assigning different threshold values for providing timely alerts. This real-time monitoring was effective in identifying the reactivation of August 2016 landslide that occurred on 22 January 2019. Thus, this study showcases the efficiency of IBIS-FM radar in monitoring slope instability with sub-millimeter accuracy on a near real-time basis.

Published

2022

33. Floating-Platform High-Frequency Hybrid Sky-Surface Wave Radar: Simulations and Experiments

Author

Miao Li, Xiongbin Wu, Lan Zhang, Guobin Yang, Qing Zhou, and Xianchang Yue

Subjects

Acoustics, Spectral density, law.invention, symbols.namesake, Surface wave, law, Vertical direction, Wave radar, symbols, Clutter, Electrical and Electronic Engineering, Ionosphere, Radar, Doppler effect, Geology

Abstract

A theoretical sea echo modeling of the floating-platform high-frequency hybrid sky-surface wave radar (HSSWR) is presented. The ionosphere is considered to be a no-tilt reflecting plane moving in the vertical direction. Subsequently, the first-order sea clutter cross section with consideration of the platform sway and yaw motion is derived. Simulations are conducted to explore the influences of the ionospheric movement and the platform oscillation motion on the sea clutter power spectrum. Simulation results indicate that the platform sway motion may induce additional peaks that distribute symmetrically concerning the Bragg peaks, while the platform yaw motion and the ionospheric movement may broaden even split the sea clutter. Experiments are conducted with the newly-developed HSSWR system, of which the receiving arrays are simultaneously deployed on a floating platform and the shoreside. Experimental measurements concerning the frequency shift, Doppler width, and the arrival angle of the E-layer/F-layer ionosphere reflected direct wave are compared and analyzed. The study demonstrates the feasibility of the proposed modeling and provides valuable guidelines for the sea clutter characteristics analysis and the data quality assessments of the floating-platform HSSWR.

Published

2022

34. Increasing and widespread vulnerability of intact tropical rainforests to repeated droughts

Author

Shengli Tao, Jérôme Chave, Pierre-Louis Frison, Thuy Le Toan, Philippe Ciais, Jingyun Fang, Jean-Pierre Wigneron, Maurizio Santoro, Hui Yang, Xiaojun Li, Nicolas Labrière, Sassan Saatchi, Evolution et Diversité Biologique (EDB), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS), Laboratoire sciences et technologies de l'information géographique (LaSTIG), Ecole des Ingénieurs de la Ville de Paris (EIVP)-École nationale des sciences géographiques (ENSG), Institut National de l'Information Géographique et Forestière [IGN] (IGN)-Université Gustave Eiffel-Institut National de l'Information Géographique et Forestière [IGN] (IGN)-Université Gustave Eiffel, Centre d'études spatiales de la biosphère (CESBIO), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Interactions Sol Plante Atmosphère (UMR ISPA), Ecole Nationale Supérieure des Sciences Agronomiques de Bordeaux-Aquitaine (Bordeaux Sciences Agro)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), and Université de Bordeaux (UB)

Subjects

remote sensing, Tropical Climate, Multidisciplinary, Rainforest, [SDV.SA.SF]Life Sciences [q-bio]/Agricultural sciences/Silviculture, forestry, Climate Change, rainforests, drought, [SDV.EE.BIO]Life Sciences [q-bio]/Ecology, environment/Bioclimatology, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, radar, Droughts, Trees

Abstract

International audience; Intact tropical rainforests have been exposed to severe droughts in recent decades, which may threaten their integrity, their ability to sequester carbon, and their capacity to provide shelter for biodiversity. However, their response to droughts remains uncertain due to limited high-quality, long-term observations covering extensive areas. Here, we examined how the upper canopy of intact tropical rainforests has responded to drought events globally and during the past 3 decades. By developing a long pantropical time series (1992 to 2018) of monthly radar satellite observations, we show that repeated droughts caused a sustained decline in radar signal in 93%, 84%, and 88% of intact tropical rainforests in the Americas, Africa, and Asia, respectively. Sudden decreases in radar signal were detected around the 1997–1998, 2005, 2010, and 2015 droughts in tropical Americas; 1999–2000, 2004–2005, 2010–2011, and 2015 droughts in tropical Africa; and 1997–1998, 2006, and 2015 droughts in tropical Asia. Rainforests showed similar low resistance (the ability to maintain predrought condition when drought occurs) to severe droughts across continents, but American rainforests consistently showed the lowest resilience (the ability to return to predrought condition after the drought event). Moreover, while the resistance of intact tropical rainforests to drought is decreasing, albeit weakly in tropical Africa and Asia, forest resilience has not increased significantly. Our results therefore suggest the capacity of intact rainforests to withstand future droughts is limited. This has negative implications for climate change mitigation through forest-based climate solutions and the associated pledges made by countries under the Paris Agreement.

Published

2023

35. DATA AUGMENTATION FOR SYNTHETIC APERTURE RADAR USING ALPHA BLENDING AND DEEP LAYER TRAINING

Author

Denton, Alexander W., Agrawal, Brij N., Garren, David A., Kim, Jae Jun, and Space Systems Academic Group (SP)

Subjects

SAMPLE, convolutional neural network, wide area search, low-resolution, chip, area search, patch, AConvNet, synthetic dataset, FOV, object proposal, target proposal, MSTAR, background, target detection, tip-and-cue, feature detection, object detection, synthetic aperture radar (SAR), artificial intelligence, ML, RADAR, machine learning, swath, alpha blending, AI, field of view, CNN, discovery, data augmentation

Abstract

Human-based object detection in synthetic aperture RADAR (SAR) imagery is complex and technical, laboriously slow but time critical—the perfect application for machine learning (ML). Training an ML network for object detection requires very large image datasets with imbedded objects that are accurately and precisely labeled. Unfortunately, no such SAR datasets exist. Therefore, this paper proposes a method to synthesize wide field of view (FOV) SAR images by combining two existing datasets: SAMPLE, which is composed of both real and synthetic single-object chips, and MSTAR Clutter, which is composed of real wide-FOV SAR images. Synthetic objects are extracted from SAMPLE using threshold-based segmentation before being alpha-blended onto patches from MSTAR Clutter. To validate the novel synthesis method, individual object chips are created and classified using a simple convolutional neural network (CNN); testing is performed against the measured SAMPLE subset. A novel technique is also developed to investigate training activity in deep layers. The proposed data augmentation technique produces a 17% increase in the accuracy of measured SAR image classification. This improvement shows that any residual artifacts from segmentation and blending do not negatively affect ML, which is promising for future use in wide-area SAR synthesis. Outstanding Thesis Major, United States Air Force Approved for public release. Distribution is unlimited.

Published

2023

36. COUNTERING SMALL UNMANNED AIRCRAFT SYSTEMS WITH ADVANCED DATA ANALYSIS AND MACHINE LEARNING

Author

Miske, Robert, Yoshida, Ruriko, Schuchard, Ross J., and Operations Research (OR)

Subjects

C-UAS, UAV, data analysis, detection, drone, unsupervised learning, small unmanned aircraft system, supervised learning, air defense, feature engineering, machine learning, classification, unmanned aerial vehicle, model robustness, sUAS, UAS, counter unmanned aircraft system, counter-drone, C-sUAS, strategy, radar, discrimination

Abstract

In January 2021, the DOD released its first Counter-Small Unmanned Aircraft Systems Strategy to address the growing risk to military personnel, facilities, and assets posed by the rapid technological advancement and proliferation of sUAS. Existing counter-drone capabilities—heavily reliant on electronic warfare to disrupt the communication link between user and device—no longer address an evolving threat that includes autonomous drones, COTS technology, and an increasing number of drones in the airspace that can overwhelm a C-sUAS operator. To counter the increasingly complex small drone threat, the Army-led Joint Counter-sUAS Office is pursuing materiel and non-materiel solutions for its new system-of-systems approach. One vexing C-sUAS challenge involves radar detection systems discriminating some sUAS from other flying objects, like birds, due to their comparable size, slow movement, and low altitude. Inaccurate or inefficient sUAS classification using radar data can be a force protection threat due to the limited number of electro-optical sensors and human operators for classification at-scale. This thesis uses bird and drone radar track data from two different training environments to explore hidden structure in the data, develop independent unsupervised and supervised learning models using the two datasets, and experiment with data sampling and feature engineering to improve upon model robustness to different environments and dynamic environmental conditions. Lieutenant Colonel, United States Army Approved for public release. Distribution is unlimited.

Published

2023

37. Feasibility of downscaling satellite-based precipitation estimates using soil moisture derived from land surface temperature

Author

Alexander Strehz, Joost Brombacher, Jelle Degen, and Thomas Einfalt

Subjects

Atmospheric Science, land surface temperature, Namoi radar, soil moisture, IMERG, Environmental Science (miscellaneous), Namoi, precipitation measurement, radar

Abstract

For many areas, satellite-based precipitation products or reanalysis model data represent the only available precipitation information. Unfortunately, the resolution of these datasets is generally too coarse for many applications. A very promising downscaling approach is to use soil moisture due to its clear physical connection to precipitation. We investigate the feasibility of using soil moisture derived from land surface temperature in this context. These data are more widely available in the required resolution compared to other soil moisture data. Rain gauge-adjusted radar data from Namoi serves as a spatial reference dataset for two objectives: to identify the most suitable globally available precipitation dataset and to explore the precipitation information contained in the soil moisture data. The results show that these soil moisture data cannot be used to downscale satellite-based precipitation data to a high resolution because of cloud cover interference. Therefore, the Integrated Multi-satellitE Retrievals for GPM (IMERG) late data represents the best precipitation dataset for many areas in Australia that require timely precipitation information, according to this study.

Published

2023

38. Semantic Segmentation of Radar Detections using Convolutions on Point Clouds

Author

A. Kummert, M. Braun, A. Cennamo, K. Kollek, and M. Schoeler

Subjects

FOS: Computer and information sciences, History, Computer Science - Machine Learning, Computer science, business.industry, Computer Vision and Pattern Recognition (cs.CV), Point cloud, Computer Science - Computer Vision and Pattern Recognition, Computer Science Applications, Education, law.invention, Machine Learning (cs.LG), law, Computer vision, Segmentation, Artificial intelligence, Radar, business

Abstract

For autonomous driving, radar sensors provide superior reliability regardless of weather conditions as well as a significantly high detection range. State-of-the-art algorithms for environment perception based on radar scans build up on deep neural network architectures that can be costly in terms of memory and computation. By processing radar scans as point clouds, however, an increase in efficiency can be achieved in this respect. While Convolutional Neural Networks show superior performance on pattern recognition of regular data formats like images, the concept of convolutions is not yet fully established in the domain of radar detections represented as point clouds. The main challenge in convolving point clouds lies in their irregular and unordered data format and the associated permutation variance. Therefore, we apply a deep-learning based method introduced by PointCNN that weights and permutes grouped radar detections allowing the resulting permutation invariant cluster to be convolved. In addition, we further adapt this algorithm to radar-specific properties through distance-dependent clustering and pre-processing of input point clouds. Finally, we show that our network outperforms state-of-the-art approaches that are based on PointNet++ on the task of semantic segmentation of radar point clouds., Comment: 5th International Conference on Artificial Intelligence, Automation and Control Technologies (AIACT 2021), 26-28 March 2021, Shanghai, China

Published

2023

39. Modeling Envisat RA-2 waveforms in the coastal zone: Case study of calm water contamination

Author

Graham D. Quartly, Christine Gommenginger, Stefano Vignudelli, Jesús Gómez-Enri, Peter Challenor, Jérôme Benveniste, and Paolo Cipollini

Subjects

Storm surge, FOS: Physical sciences, Storm, Sea-surface height, Geotechnical Engineering and Engineering Geology, law.invention, Marine pollution, Physics - Atmospheric and Oceanic Physics, law, Climatology, Atmospheric and Oceanic Physics (physics.ao-ph), Tide gauge, Altimeter, Electrical and Electronic Engineering, Radar, Digital elevation model, Geology

Abstract

Radar altimeters have so far had limited use in the coastal zone, the area with most societal impact. This is due to both lack of, or insufficient accuracy in the necessary corrections, and more complicated altimeter signals. This letter examines waveform data from the Envisat RA-2 as it passes regularly over Pianosa (a 10-km2 island in the northwestern Mediterranean). Forty-six repeat passes were analyzed, with most showing a reduction in signal upon passing over the island, with weak early returns corresponding to the reflections from land. Intriguingly, one third of cases showed an anomalously bright hyperbolic feature. This feature may be due to extremely calm waters in the Golfo della Botte (northern side of the island), but the cause of its intermittency is not clear. The modeling of waveforms in such a complex land/sea environment demonstrates the potential for sea surface height retrievals much closer to the coast than is achieved by routine processing. The long-term development of altimetric records in the coastal zone will not only improve the calibration of altimetric data with coastal tide gauges but also greatly enhance the study of storm surges and other coastal phenomena.

Published

2023

40. Joint Radar-Communication Systems: Modulation Schemes and System Design

Author

Mario Pauli, Benjamin Nuss, Mohamad Basim Alabd, Axel Diewald, Lucas Giroto de Oliveira, and Thomas Zwick

Subjects

Signal processing, Radiation, Computer science, Condensed Matter Physics, Communications system, Multiplexing, law.invention, System model, Modulation, law, Chirp, Electronic engineering, Systems design, Electrical and Electronic Engineering, Radar

Abstract

The joint radar-communication (RadCom) concept has been continuously gaining interest due to the possibility of integrating radar sensing and communication functionalities in the same radio frequency hardware platform. Besides a number of challenges in terms of hardware design and signal processing, the choice of suitable modulation schemes plays a significant role in driving the performance of RadCom systems. In this sense, this article presents an overview of state-of-the-art modulation schemes for RadCom systems, namely, chirp sequence, phase-modulated continuous wave, orthogonal frequency-division multiplexing, and orthogonal chirp-division multiplexing. For each of them, a detailed system model is outlined, and parameters for quantifying both radar and communication performances are presented. Finally, a comparative analysis of the aforementioned RadCom modulation schemes is carried out to illustrate the presented discussion.

Published

2022

41. Time and phase synchronization using clutter observations in airborne distributed coherent aperture radars

Author

Jianxin Wu, Chen Jinming, Tong Wang, and Liu Xiaoyu

Subjects

Sequential estimation, Aperture, Computer science, Mechanical Engineering, Aerospace Engineering, Phase synchronization, law.invention, Azimuth, law, Synchronization (computer science), Clutter, Radar, Algorithm, Coherence (physics)

Abstract

Airborne Distributed Coherent Aperture Radar (ADCAR) is one of the most promising next-generation radars to significantly improve target detection and discrimination abilities. However, time and phase synchronization among unit radars should be done before an ADCAR is intended to cohere on a potential target. To address this problem, a time and phase synchronization technique using clutter observations is proposed in this paper. Clutter returns from different azimuths and elevations on the surface of the earth are employed to calibrate system uncertainties. Two stages are mainly considered: a scene registration among range-Doppler units from different transmit/receive pairs is performed to enhance the clutter coherence in the first stage, followed by a joint estimation of those synchronization errors in the second stage. To relieve the computational burden, a novel Separable and Sequential Estimation (SSE) method is provided to separate the unknowns at the sacrifice of a range-Doppler unit. Moreover, performance analyses including the clutter coherence ability, estimation lower bound, and signal coherence loss are also performed. Finally, simulation results indicate that ADCAR time and phase synchronization is realized by using our methods.

Published

2022

42. Virtual Synthetic Aperture Radar Target Based on a Miniaturized Monostatic Digital Delay Transponder

Author

Stelzig, Michael, Benedikter, Andreas, Horn, Ralf, Jäger, Marc, Keller, Martin, Scheiber, Rolf, Krieger, Gerhard, and Vossiek, Martin

Subjects

Pulsecompression, transponder, radarcrosssection (RCS), synthetic aperture radar (SAR), Electrical and Electronic Engineering, Condensed Matter Physics, radar

Published

2022

43. Radar emitter multi-label recognition based on residual network

Author

Hao Xinhong, Liu Shao-kun, Yu Hong-hai, Yan Xiaopeng, and Li Ping

Subjects

0209 industrial biotechnology, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Computational Mechanics, 02 engineering and technology, Residual, 01 natural sciences, Signal, Convolutional neural network, 010305 fluids & plasmas, law.invention, 020901 industrial engineering & automation, Aliasing, law, 0103 physical sciences, Radar, Common emitter, business.industry, Mechanical Engineering, Metals and Alloys, Short-time Fourier transform, Pattern recognition, Modulation, Ceramics and Composites, Artificial intelligence, business

Abstract

In low signal-to-noise ratio (SNR) environments, the traditional radar emitter recognition (RER) method struggles to recognize multiple radar emitter signals in parallel. This paper proposes a multi-label classification and recognition method for multiple radar-emitter modulation types based on a residual network. This method can quickly perform parallel classification and recognition of multi-modulation radar time-domain aliasing signals under low SNRs. First, we perform time-frequency analysis on the received signal to extract the normalized time-frequency image through the short-time Fourier transform (STFT). The time-frequency distribution image is then denoised using a deep normalized convolutional neural network (DNCNN). Secondly, the multi-label classification and recognition model for multi-modulation radar emitter time-domain aliasing signals is established, and learning the characteristics of radar signal time-frequency distribution image dataset to achieve the purpose of training model. Finally, time-frequency image is recognized and classified through the model, thus completing the automatic classification and recognition of the time-domain aliasing signal. Simulation results show that the proposed method can classify and recognize radar emitter signals of different modulation types in parallel under low SNRs.

Published

2022

44. Деякі експериментальні результати оцінювання доплерівських портретів радіолокаційних цілей

Subjects

Signal processing, Computer science, business.industry, Coordinate system, Signal, law.invention, Antenna array, Radial velocity, Acceleration, symbols.namesake, law, symbols, Computer vision, Artificial intelligence, Radar, business, Doppler effect

Abstract

Recently, the long coherent accumulation of radar signals becomes relevant in the analysis of Doppler portraits of targets. This interest is related to the desire of researchers to obtain more information about radar purposes. Detailed spectral analysis provides additional information on the parameters of the target and its maneuvers. Some studies published in special articles are being discussed. They analyzed the methods of high resolution for the spectrums of refl ected signals. It is possible to obtain detailed Doppler portraits. The development of the elemental base of the construction of radar devices contributes to the improvement of the processing processes of refl ected signals. The possibilities of highlighting useful signals of small objects against the background of refl ections from the sea surface are considered. The article provides the results of processing signals recorded by radars made by the technology of digital antenna array. The experimental results of the Doppler portraits used a long-term coherent accumulation of signals in the L and X bands. Doppler portraits of ISS signals, Boeing-type passenger aircraft, MiG-29 fi ghter, helicopter are analyzed. The possibility of compensating for changes in the signal phase, which occurs during the radial acceleration of the ISS is shown. This allowed to increase the of signal-to-noise ratio to 6 dВ. Experimental results allow you to observe the maneuver of the target, to measure the acceleration of individual elements of the structure and their evolution. It is proposed to use the method of assessing Doppler portraits in the «radial speed - radial acceleration» coordinate system. The method is useful to use in radar surveillance systems of space objects, in the development of methods for recognizing classes of radar targets and in determining the number of objects in the target group. The development of this method of analysis of signals in prospective RADAR with the digital antenna array will help to solve problems of optimal signal processing, identify the number of targets in the group and maneuver the target, recognize classes of targets by the number of brilliant points and cross-Size targets.

Published

2022

45. GNSS signal-based snow water equivalent determination for different snowpack conditions along a steep elevation gradient

Author

A. Capelli, F. Koch, P. Henkel, M. Lamm, F. Appel, C. Marty, and J. Schweizer

Subjects

QE1-996.5, Reference data (financial markets), Elevation, Geology, Snowpack, Snow, law.invention, Environmental sciences, Current (stream), GNSS applications, law, Liquid water content, Environmental science, GE1-350, Radar, Remote sensing, Earth-Surface Processes, Water Science and Technology

Abstract

Snow water equivalent (SWE) can be measured using low-cost Global Navigation Satellite System (GNSS) sensors with one antenna placed below the snowpack and another one serving as a reference above the snow. The underlying GNSS signal-based algorithm for SWE determination for dry- and wet-snow conditions processes the carrier phases and signal strengths and additionally derives liquid water content (LWC) and snow depth (HS). So far, the algorithm was tested intensively for high-alpine conditions with distinct seasonal accumulation and ablation phases. In general, snow occurrence, snow amount, snow density and LWC can vary considerably with climatic conditions and elevation. Regarding alpine regions, lower elevations mean generally earlier and faster melting, more rain-on-snow events, and shallower snowpack. Therefore, we assessed the applicability of the GNSS-based SWE measurement at four stations along a steep elevation gradient (820, 1185, 1510 and 2540 m a.s.l.) in the eastern Swiss Alps during two winter seasons (2018–2020). Reference data of SWE, LWC and HS were collected manually and with additional automated sensors at all locations. The GNSS-derived SWE estimates agreed very well with manual reference measurements along the elevation gradient, and the accuracy (RMSE = 34 mm, RMSRE = 11 %) was similar under wet- and dry-snow conditions, although significant differences in snow density and meteorological conditions existed between the locations. The GNSS-derived SWE was more accurate than measured with other automated SWE sensors. However, with the current version of the GNSS algorithm, the determination of daily changes of SWE was found to be less suitable compared to manual measurements or pluviometer recordings and needs further refinement. The values of the GNSS-derived LWC were robust and within the precision of the manual and radar measurements. The additionally derived HS correlated well with the validation data. We conclude that SWE can reliably be determined using low-cost GNSS sensors under a broad range of climatic conditions, and LWC and HS are valuable add-ons.

Published

2022

46. Slow-Time FDA-MIMO Technique With Application to STAP Radar

Author

Yuhong Zhang, Jinye Peng, Cai Wen, Jianxin Wu, Yan Huang, and Guimei Zheng

Subjects

Slow time, Computer science, law, MIMO, Electronic engineering, Aerospace Engineering, Electrical and Electronic Engineering, Radar, law.invention

Published

2022

47. Analysis and Design for Pilot Power Allocation and Placement in OFDM Based Integrated Radar and Communication in Automobile Systems

Author

Ming-Chun Lee, Yu-Chien Lin, Hao-Wei Hsu, Meng-Xun Gu, and Ta-Sung Lee

Subjects

Computer Networks and Communications, law, Orthogonal frequency-division multiplexing, Computer science, Automotive Engineering, Electronic engineering, Aerospace Engineering, Electrical and Electronic Engineering, Radar, Pilot power, law.invention

Published

2022

48. Estimation of ground subsidence of New Delhi, India using PS-InSAR technique and Multi-sensor Radar data

Author

Biswajeet Pradhan, Dheeraj Kumar, Daniele Perissin, and Kapil Malik

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 0201 Astronomical and Space Sciences, 0901 Aerospace Engineering, 0913 Mechanical Engineering, Aerospace Engineering, Astronomy and Astrophysics, Subsidence, Geodesy, Urban area, law.invention, Multi sensor, Geophysics, Space and Planetary Science, law, Interferometric synthetic aperture radar, Aerospace & Aeronautics, General Earth and Planetary Sciences, Environmental science, New delhi, Radar, Groundwater, Ground subsidence

Abstract

Globally the land subsidence is a significant problem of the rapidly growing urban area. The factor responsible for the land subsidence caused by over-exploitation of the underground fluid such as water, petroleum, and gas respectively. In present study we present the result of detail investigation of active ground subsidance in New Delhi, National Capital Region (NCR). This area indicates a high rate of urban growth during the past decades. To analyze the land subsidence, we used multiple SAR sensor data and exploited the PS-InSAR technique. The data used for this study are Cosmo-skymed acquired between 08/06/2011 to 15/11/2017, Sentinel-1A-B (18-12-2014 to 27-11-2018), and ALOS PALSAR acquired between 19/01/2007 and 20/01/2011. These radar sensors operate in X, C, and L-band, which covers over ten years, from 2007 to 2018. The PSI results of Cosmo-skymed reveals that the Delhi NCR region has undergone an average deformation ± 15 mm/y, a maximum surface deformation observed from ALOS-PALSAR is 10 to 18 mm/y and the ground displacement observed from the SENTINAL-1A data is −2 to 16 mm/y. Groundwater level data also collected for the same period and a ground water level depletion compared with the subsidence. Monitoring land subsidence with ground-based conventional technology is time-consuming and can be carried out in a limited area due to the financial implication. PS-InSAR is an established method to detect the surface movement using the SAR sensor's time-series data. The result shows that a twenty centimeter of land subsidence is visible in some areas, validated with the collected ground evidence. The affected area is also showing resemblance to the groundwater depleting condition in those areas. This study also establish that multiple sensor data can be used to monitor the long term land subsidence.

Published

2022

49. Range Ambiguous Clutter Suppression Approach With Elevation Time Diverse Array

Author

Xiongpeng He, Jiang Zhu, Shenqi Zhu, Jingwei Xu, and Guisheng Liao

Subjects

Computer science, Aerospace Engineering, Moving target indication, law.invention, Azimuth, symbols.namesake, law, symbols, Clutter, Waveform, Electrical and Electronic Engineering, Radar, Doppler effect, Algorithm, Energy (signal processing), Decoding methods

Abstract

When range ambiguity and range dependence coexist in forward-looking ground moving target indication (GMTI) radar, the traditional space-time adaptive processing (STAP) approaches may fail to work. To cope with this issue, a range-ambiguous clutter suppression approach based on elevation time diverse array (TDA) radar system and azimuth phase coding (APC) technique is presented in this paper. Due to the advantages of frequency scanning, the elevation TDA radar is able to cover all directions by transmitting a single time-shifted waveform. Therefore, a frequency bandpass filter is devised for each single range-bin to achieve the mainlobe echo extraction procedure. In the sequel, the azimuth phase decoding and Doppler filtering are performed to deal with the residual sidelobe ambiguous energy. With two-dimensional filtering, one can extract the unambiguous signals for each range region independently. Then, the traditional clutter compensation and STAP methods are employed to suppress the ground clutter. Finally, the effectiveness of the proposed framework in resolving range ambiguity are verified by the numerical simulation experiments.

Published

2022

50. Neural Network-Based Control of an Adaptive Radar

Author

Joel T. Johnson, Peter John-Baptiste, and Graeme Smith

Subjects

Artificial neural network, Computer science, law, Control (management), Real-time computing, Aerospace Engineering, Electrical and Electronic Engineering, Radar, law.invention

Published

2022