2,060 resources related to Meteorological radar
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The International Conference on Image Processing (ICIP), sponsored by the IEEE SignalProcessing Society, is the premier forum for the presentation of technological advances andresearch results in the fields of theoretical, experimental, and applied image and videoprocessing. ICIP 2020, the 27th in the series that has been held annually since 1994, bringstogether leading engineers and scientists in image and video processing from around the world.
Everything to do with radar hardware, techniques, processing and systems.
2020 IEEE Radar Conference (RadarConf20)
Annual IEEE Radar Conference
The Optical Fiber Communication Conference and Exhibition (OFC) is the largest global conference and exhibition for optical communications and networking professionals. For over 40 years, OFC has drawn attendees from all corners of the globe to meet and greet, teach and learn, make connections and move business forward.OFC attracts the biggest names in the field, offers key networking and partnering opportunities, and provides insights and inspiration on the major trends and technology advances affecting the industry. From technical presentations to the latest market trends and predictions, OFC is a one-stop-shop.
The ICASSP meeting is the world's largest and most comprehensive technical conference focused on signal processing and its applications. The conference will feature world-class speakers, tutorials, exhibits, and over 50 lecture and poster sessions.
The IEEE Aerospace and Electronic Systems Magazine publishes articles concerned with the various aspects of systems for space, air, ocean, or ground environments.
Experimental and theoretical advances in antennas including design and development, and in the propagation of electromagnetic waves including scattering, diffraction and interaction with continuous media; and applications pertinent to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques.
Computer, the flagship publication of the IEEE Computer Society, publishes peer-reviewed technical content that covers all aspects of computer science, computer engineering, technology, and applications. Computer is a resource that practitioners, researchers, and managers can rely on to provide timely information about current research developments, trends, best practices, and changes in the profession.
Educational methods, technology, and programs; history of technology; impact of evolving research on education.
Publishes original and significant contributions relating to the theory, design, performance and reliability of electron devices, including optoelectronics devices, nanoscale devices, solid-state devices, integrated electronic devices, energy sources, power devices, displays, sensors, electro-mechanical devices, quantum devices and electron tubes.
IEEE Transactions on Aerospace and Electronic Systems, 1973
Radar Clutter, 06/01/2012
The Radar Systems Engineering Series consists of seventeen lectures; each lecture is offered as an individual tutorial. The goal of this series is to provide an advanced introduction to radar systems subsystem issues for first year graduate students, advanced senior undergraduates or professionals new to the field. The material will be most accessible to university graduates with a Bachelor of ...
The 23rd Digital Avionics Systems Conference (IEEE Cat. No.04CH37576), 2004
IEE Colloquium on Radar Meteorology, 1995
Radio Science, 2012
Nowadays a huge amount of data is available for the statistical characterization of rainfall worldwide, although unfortunately not always with the adequate spatial and temporal resolution required for the very high demanding telecommunication applications. On the basis of the NIMROD radar network composite rain maps, first, this paper investigates separately the impact of space or time integration on the spatial ...
2011 IEEE Dennis J. Picard Medal for Radar Technologies and Applications - James M. Headrick
Richard Klemm - IEEE Dennis J. Picard Medal for Radar Technologies and Applications, 2019 IEEE Honors Ceremony
IMS 2011 Microapps - Volume Manufacturing Trends for Automotive Radar Devices
2012 IEEE Honors - Dennis J. Picard Medal for Radar Technologies and Applications
Reconfigurable 60-GHz Radar Transmitter SoC - Wooram Lee - RFIC 2019 Showcase
IEEE Dennis J. Picard Medal for Radar Technologies and Applications - Mark E. Davis - 2018 IEEE Honors Ceremony
Honors 2020: Joseph R. Guerci Wins the IEEE Dennis J. Picard Medal for Radar Technologies and Applications
Nadav Levanon receives the IEEE Dennis J. Picard Medal for Radar Technologies and Applications - Honors Ceremony 2016
Hugh Griffiths accepts the IEEE Dennis J. Picard Medal for Radar Technologies and Applications - Honors Ceremony 2017
IMS 2012 Microapps - Virtual Flight Testing of Radar System Performance Daren McClearnon, Agilent EEsof
IMS 2012 Special Sessions: The Evolution of Some Key Active and Passive Microwave Components - N. J. Kolias
CMOS mmWave Radar SoC Architecture and Applications - Sreekiran Samala - RFIC Showcase 2018
MicroApps: Radar Design Flow with NI-AWR Integrated Framework (National Instruments)
2013 IEEE Dennis J. Picard Medal
Green Radar State of Art: theory, practice and way ahead.
2015 IEEE Honors: IEEE Dennis J. Picard Medal for Radar Technologies and Applications - Marshall Greenspan
MicroApps: Simulation of Airborne, Space-Borne and Ship-Based Radar Systems with Complex Environment (Agilent EEsof)
Young Professionals at N3XT: Bringing Together Tech Fields
A Fully Integrated 75-83GHz FMCW Synthesizer for Automotive Radar Applications with -97dBc/Hz Phase Noise at 1MHz Offset and 100GHz/mSec Maximal Chirp Rate: RFIC Industry Showcase 2017
The Radar Systems Engineering Series consists of seventeen lectures; each lecture is offered as an individual tutorial. The goal of this series is to provide an advanced introduction to radar systems subsystem issues for first year graduate students, advanced senior undergraduates or professionals new to the field. The material will be most accessible to university graduates with a Bachelor of Science degree in Electrical Engineering, Physics, Mathematics, Computer Science / Engineering, or Mechanical Engineering and who have a solid understanding of Electromagnetism and their fields, Probability, and Calculus through Differential Equations, Vector Calculus, and Linear Algebra. Each tutorial consists of a screen-captured PowerPoint lecture narrated by Dr. O'Donnell. In each tutorial Dr. O'Donnell has broken his lecture into one or more separate segments for ease of viewing. All of the material in these tutorials is subject to copyright laws. In the first segment of this lecture Dr. O'Donnell reviews the specific copyright information for these materials. Following this brief video, the first segment of this lecture will begin.You may also access copyright information by viewing the video listed below on this course page. In his tenth lecture, Dr. O'Donnell reviews radar clutter or backscatter from unwanted objects. He demonstrates how specific objects such as the ground or sea affect the performance of radar. This lecture is divided into two parts.
Nowadays a huge amount of data is available for the statistical characterization of rainfall worldwide, although unfortunately not always with the adequate spatial and temporal resolution required for the very high demanding telecommunication applications. On the basis of the NIMROD radar network composite rain maps, first, this paper investigates separately the impact of space or time integration on the spatial correlation of rainfall ρ, a key parameter for most Propagation Impairment Mitigation Techniques (PIMTs), as well as for many prediction models such as time-space rain field generators. Analytical formulations are proposed to model the average trend of ρ with the distance d between two sites as a function of the integration time T or the integration area A, which, in turn, can be used to de-integrate the spatial correlation information estimated respectively from networks of raingauges with long integration time or from radar data with coarse spatial resolution. As an example, the last part of the paper compares the spatial rain decorrelation trends estimated by a database of radar maps collected in Northern Italy with the ones de-integrated from products of meteorological re- analyses (ERA40) or Earth Observation missions (TMPA 3B42).
According to the changes and characteristics of electric field in the atmosphere when lightning occurs, this paper used mathematical model to calculate the movement of thundercloud. The atmospheric electric field data during lightning were provided by wide-area distributed sensors. According to the changes of electromagnetic field at different time points of lightning process and the weight distribution of collected data, positions of thundercloud at different time points were determined. Then, interpolation polynomial and least squares fitting were used for compensation and curve fitting. Finally, the general movement trend of thundercloud was visually presented. Result indicated that the simulated movement of thundercloud was consistent with the actual one detected by professional weather radar. Thus, the method proposed here can serve as a new method for forecasting lightning and shortening the forecast time.
A melting layer of precipitation is assumed to be composed of melting snow particles and the melting layer is related to the physical constants and the meteorological parameters. Shapes of the particles are approximated to oblate spheroids (or spheres). Bistatic radar reflectivities are computed at 1-100 GHz. Numerical results show that interference between earth stations can be caused by the melting layer at microwaves and millimeter waves. Radar bright band can be explained with the effective radar reflectivity factors and the differential reflectivity is on the expected order. Accordingly, the radar bright band can be absent in the melting layer at frequencies above 20 GHz. This agrees with radar observations at 35 and 94 GHz. It has also been found that the melting layer can result in interference between earth stations and terrestrial radio-relay stations.
This paper considers potentials of radar polarimetry to register information about the drop vibration and drop shape deformation in the reflected signal and possibility to register this impact by selection of polarization of receiving antenna. In this paper, the calculation of the relation between the average signal value and the vibrations magnitude in decibels was made to demonstrate the possibility to fix the reflected electromagnetic wave energy variation caused by wind and wind related phenomena.
This paper relates a short history of adaptive arrays, starting with Paul Howells' invention of the side-lobe canceller for radar and communications. An attempt is made in a small way to historically relate this adaptive array development with the sonar problem, the adaptive equalizer, adaptive pattern recognition, etc. Finally some technical highlights of adaptive array theory are presented.
The global precipitation measurement (GPM) mission is dedicated to improving the understanding of the global water cycle by measuring and mapping precipitation throughout the globe. The core GPM satellite will incorporate two separate precipitation radars: one operating at Ku-band (13.6 GHz) and the other at Ka band (35.6 GHz). Each radar beam will be steered such that they both point to the same location in the atmosphere. The main purpose of the dual-frequency radar system is to resolve the DSD in precipitation as well as discriminate between rain and ice. With the two beams collocated on the same precipitation volume, new algorithms are being developed to reliably estimate attenuation and rain rate. Any algorithm is based on models of precipitation. In addition, the GPM system assumes collocated beams and matched resolution volumes. Electromagnetic and microphysical models have been developed based on ground-based dual-frequency radar data at S-band to simulate Ku- and Ka-band results for comparison with the new GPM algorithms. This paper evaluates the dual-frequency inversion algorithm with synthesized S-band and known perfect data and presents results. Results show the expected performance of the new dual-precipitation radar algorithms with the potential for guiding algorithm and system improvements.
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