Conferences related to Shipborne Radar

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IGARSS 2020 - 2020 IEEE International Geoscience and Remote Sensing Symposium

All fields of satellite, airborne and ground remote sensing.


2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting

The joint meeting is intended to provide an international forum for the exchange of information on state of the art research in the area of antennas and propagation, electromagnetic engineering and radio science


2019 IEEE 19th Topical Meeting on Silicon Monolithic Integrated Circuits in RF Systems (SiRF)

This is a set of five conferences with a focus on wireless components, applications and systems that affect both now and our future lifestyle. The main niche of these conferences is to bring together technologists, circuit designers, system designers and entrepreneurs at a single event. It was and is the place where these worlds meet, where new processes and systems can be benchmarked against the needs of circuit designers at the bleeding edge of RF systems. This is also an area where today's design compromises can trigger tomorrow's advanced technologies, where dreams can become a reality.


2019 International Radar Conference (RADAR)

RADAR2019 is in the frame of the international relations set up between the IET, the IEEE, the CIE, the IEAust and the SEE. The conference will focus on new research and developments in the fields: Radar Systems (ground based, airborne, spaceborne), Radar Environment and Phenomenology, Electromagnetic Modeling Radar Component Technologies, Remote Sensing from Airborne or Spaceborne Systems, SAR & ISAR Imagery Waveform design, beamforming and signal processing Emerging, Radar Applications, Smart Visualization and Information processing, System Modeling, Simulation and Validation, Radar Management Techniques Automatic Classification. The conference will take place at Toulon Neptune Palais. Located on the French Riviera, Toulon is an important centre for naval construction and aeronautical equipment,hosting the major naval centre on France's Mediterranean coast, also home of the French Navy aircraft carrier Charles De Gaulle.

  • 2003 IEEE International Radar Conference

  • 2008 International Conference on Radar (Radar 2008)

    All aspects of radar systems for civil, security and defence applications. Themes include: Radar in the marine environment, Radar systems, Multistatic and netted radars, Radar subsystems, Radar techniques, processing and displays, Modelling and simulation of radar environments, Electronic attack, Electronic protection, Test and Evaluation

  • 2009 International Radar Conference Radar "Surveillance for a Safer World" (RADAR 2009)

    The conference will focus on new research and developments in the field of radar techniques for both military and civil applications. Topics to be covered at Radar 2009 include: Radar Environment and Phenomenology Radar Systems Remote Sensing from Airborne or Spaceborne Systems Waveform Design, Beamforming and Signal Processing Emerging Radar Applications Emerging Technologies Advanced Sub-Systems Technologies Computer Modeling, Simulation and V

  • 2011 IEEE CIE International Conference on Radar (Radar)

    This series of successfully organized international conference on radar shows the very fruitful cooperation between IEEE AESS, IET/UK, SEE/France, EA/Australia CIE/China, and the academy societies of other countries , such as Germany, Russia, Japan, Korea and Poland. Radar 2011 is a forum of radar engineers and scientists from all over the world. The conference topics of Radar 2011 will cover all aspects of radar system for civil and defense applications.

  • 2012 International Radar Conference (Radar)

    Radar Environment/Phenomenology, Radar Systems, Remote Sensing from Airborne/Spaceborne Systems, Waveform Design, Beamforming/Signal Processing, Emerging Applications, Advanced Sub-Systems, Computer Modelling, Simulation/Validation.

  • 2013 International Conference on Radar

    Radar 2013 cover all aspects of radar systems for civil, security and defence application. Waveform design, beamforming, signal processing, Emerging applications and technologies, sub-systems technologies, Radar environment.

  • 2014 International Radar Conference (Radar)

    Radar 2014 cover all aspects of radar systems for civil, security and defence application. Waveform design, beamforming, signal processing, Emerging applications and technologies, sub-systems technologies, Radar environment.

  • 2016 CIE International Conference on Radar (RADAR)

    The 2016 CIE International Conference on Radar (Radar 2016) will be held in October 10-13 in Guangzhou, China. Radar 2016 is one of the international radar conference series which is held separately in USA, China, UK, Australia and France. It is the 7th International Radar Conference held in China. The conference topics of Radar 2016 will cover all aspects of radar system for civil or defense application.The professional theme of Radar 2016 is “Innovative thinking into the future”. It is our pleasure and honor to invite you to attend Radar 2016 conference. All accepted papers will be published in the conference proceedings We hope to meet you in Guangzhou, China.

  • 2017 International Radar Conference (Radar)

    radar environment and phenomenology, radar systems, remote sensing from airborne or spaceborne systems, waveform design, beamforming and signal processing, emerging technologies, advanced sub-systems technologies, computer modelling, simulation and validation, radar management techniques

  • 2018 International Conference on Radar (RADAR)

    All aspects of radar systems for civil and defence applications.


2018 IEEE Radar Conference (RadarConf18)

This conference will be a continuation of the annual IEEE radar series (formerly the IEEE National Radar conference). These conferences cover the many disciplines that span the applications of modern radar systems, including systems-level through subsystem and component technologies, antennas, and signal processing (deterministic and adaptive). The scope includes systems architectures of monostatic, bistatic and multistatic, and ground-based, airborne, shipborne, and spaceborne realizations.

  • 1996 IEEE Radar Conference

  • 1997 IEEE Radar Conference

  • 1998 IEEE Radar Conference

  • 1999 IEEE Radar Conference

  • 2000 IEEE International Radar Conference

  • 2001 IEEE Radar Conference

  • 2002 IEEE Radar Conference

  • 2003 IEEE Radar Conference

  • 2004 IEEE Radar Conference

  • 2005 IEEE International Radar Conference

  • 2006 IEEE Radar Conference

  • 2007 IEEE Radar Conference

  • 2008 IEEE Radar Conference

    The 2008 IEEE Radar Conference will focus on the key aspects of radar theory and applications as listed below. Exploration of new avenues and methodologies of radar signal processing will also be encouraged. Tutorials will be held in a number of fields of radar technology. The Conference will cover all aspects of radar systems for civil, security and defense applications.

  • 2009 IEEE Radar Conference

    The conference's scope is civil and military radar, including science, technology, and systems. The theme for RADAR '09 is "Radar: From Science to Systems," emphasizing scientific or observational requirements and phenomenology that lead to the systems that we in the radar community develop.

  • 2010 IEEE International Radar Conference

    RADAR Systems, RADAR technology

  • 2011 IEEE Radar Conference (RadarCon)

    RadarCon11 will feature topics in radar systems, technology, applications, phenomenology,modeling, & signal processing. The conference theme, In the Eye of the Storm, highlights the strong regional interest in radar for severe weather analysis and tracking. Broader implications of the theme reflect global interests such as radar's role in assessing climate change, supporting myriad defense applications, as well as issues with spectrum allocation and management.

  • 2012 IEEE Radar Conference (RadarCon)

    The 2012 IEEE Radar Conference will host 400 to 600 attendees interested in innovations and developments in radar technology. The radar related topics will include presentations describing developments in radar systems and their implementations, phenomenology, target and clutter modeling, component advances, signal processing and data processing utilizing advanced algorithms. The conference will also include exhibits by vendors of radar systems, radar components, instrumentation, related software and publ

  • 2013 IEEE Radar Conference (RadarCon)

    The conference theme is The Arctic The New Frontier as it presents a vast and challenging environment for which radar systems operating in a multi-sensor environment are currently being developed for deployment on space, air, ship and ground platforms and for both remote sensing of the environment and for the monitoring of human activity. It is one of the major challenges and applications being pursued in the field of radar development in Canada.

  • 2014 IEEE Radar Conference (RadarCon)

    The 2014 IEEE Radar Conference will showcase innovations and developments in radar technology. Topics will include presentations describing developments in radar systems and their implementations, phenomenology, target and clutter modeling, signal processing, component advances, etc.

  • 2015 IEEE Radar Conference (RadarCon)

    The scope of the IEEE 2015 International Radar Conference includes all aspects of civil and military radar. Topics range from fundamental theory to cutting-edge applications, from signal processing, modeling, simulation to hardware implementation and experimental results.

  • 2016 IEEE Radar Conference (RadarCon)

    A continuing series of annual RADAR Conferences IEEE-AESS

  • 2017 IEEE Radar Conference (RadarCon)

    This conference will be a continuation of the annual IEEE radar series (formerly the IEEE National Radar conference). These conferences cover the many disciplines that span the applications of modern radar systems. This includes systems-level through subsystem and component technologies, antennas, and signal processing (deterministic and adaptive). The scope includes systems architectures of monostatic, bistatic and multistatic, and ground-based, airborne, and spaceborn realizations.



Periodicals related to Shipborne Radar

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Aerospace and Electronic Systems Magazine, IEEE

The IEEE Aerospace and Electronic Systems Magazine publishes articles concerned with the various aspects of systems for space, air, ocean, or ground environments.


Antennas and Propagation, IEEE Transactions on

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.


Geoscience and Remote Sensing Letters, IEEE

It is expected that GRS Letters will apply to a wide range of remote sensing activities looking to publish shorter, high-impact papers. Topics covered will remain within the IEEE Geoscience and Remote Sensing Societys field of interest: the theory, concepts, and techniques of science and engineering as they apply to the sensing of the earth, oceans, atmosphere, and space; and ...


Geoscience and Remote Sensing, IEEE Transactions on

Theory, concepts, and techniques of science and engineering as applied to sensing the earth, oceans, atmosphere, and space; and the processing, interpretation, and dissemination of this information.


Oceanic Engineering, IEEE Journal of

Bayes procedures; buried-object detection; dielectric measurements; Doppler measurements; geomagnetism; sea floor; sea ice; sea measurements; sea surface electromagnetic scattering; seismology; sonar; acoustic tomography; underwater acoustics; and underwater radio communication.



Most published Xplore authors for Shipborne Radar

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Xplore Articles related to Shipborne Radar

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Shipborne radar echo signal denoising based on improved threshold and shrinkage function

2010 2nd International Conference on Signal Processing Systems, 2010

In order to denoise shipborne radar (9 GHz pulse radar) echo signal in distortion-free, smooth, and less loss, A improved threshold and shrinkage function are proposed in this paper based on the Multi-analysis wavelet threshold denoising. The denoising effects of different shrinkage function for shipborne radar echo signal were compared. The results of experiment show that better SNR and similarity ...


Shipborne Radar Servo Control based on Neural Sliding Mode Variable Structure

2018 IEEE 3rd Advanced Information Technology, Electronic and Automation Control Conference (IAEAC), 2018

In this paper, in view of the complexity of shipborne radar servo system, the position loop is controlled by sliding mode variable structure. In order to overcome the oscillation in sliding mode variable structure control, neural network and sliding mode variable structure are combined. And the control performance is analyzed and simulated. Compared with the traditional PID control, neural network ...


New threshold and shrinkage function for shipborne radar echo signal denoising based on wavelet transforms

2010 2nd International Conference on Signal Processing Systems, 2010

In order to denoise shipborne radar (9 GHz pulse radar) echo signal in distortion-free, smooth, and less loss, a new threshold and shrinkage function are proposed in this paper based on the Multi-analysis wavelet threshold denosing. The denoising effects of different shrinkage function for shipborne radar echo signal were compared. The results of experiment show that better SNR and similarity ...


The shipborne radar antenna pattern at over-horizon object observation

4th International Conference on Antenna Theory and Techniques (Cat. No.03EX699), 2003

The paper considers the possibilities for shipborne radar (/spl lambda/ = 4.5 cm) to detect over-the-horizon objects in higher refraction conditions. It is shown that, due to antenna pattern adaptation to high refraction coefficient gradients in the troposphere lower layers, the radar receiver output signal- to-noise ratio can increase by 20-23 dB.


Non-uniform beam filling correction for spaceborne rain radar measurement: a simulation study using shipborne radar data over tropical Pacific

IGARSS'97. 1997 IEEE International Geoscience and Remote Sensing Symposium Proceedings. Remote Sensing - A Scientific Vision for Sustainable Development, 1997

A method to correct spaceborne rain radar measurement for non-uniform beam filling (NUBF) is studied using a shipborne radar data set over the tropical Pacific. Statistical analyses are made on spatial variabilities of rain rate. The result is reflected in estimating the variability in a radar IFOV which is then used to obtain a NUBF correction factor. Results indicate the ...



Educational Resources on Shipborne Radar

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IEEE.tv Videos

2014 Dennis J. Picard Medal for Radar Technologies and Applications
Richard Klemm - IEEE Dennis J. Picard Medal for Radar Technologies and Applications, 2019 IEEE Honors Ceremony
2011 IEEE Dennis J. Picard Medal for Radar Technologies and Applications - James M. Headrick
2012 IEEE Honors - Dennis J. Picard Medal for Radar Technologies and Applications
IMS 2011 Microapps - Volume Manufacturing Trends for Automotive Radar Devices
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
Sang Gyun Kim - RFIC Industry Showcase - IMS 2020
2013 IEEE Dennis J. Picard Medal
Green Radar State of Art: theory, practice and way ahead.
MicroApps: Radar Design Flow with NI-AWR Integrated Framework (National Instruments)
2015 IEEE Honors: IEEE Dennis J. Picard Medal for Radar Technologies and Applications - Marshall Greenspan
Tatsunori Usugi - RFIC Industry Showcase - IMS 2020
MicroApps: Simulation of Airborne, Space-Borne and Ship-Based Radar Systems with Complex Environment (Agilent EEsof)

IEEE-USA E-Books

  • Shipborne radar echo signal denoising based on improved threshold and shrinkage function

    In order to denoise shipborne radar (9 GHz pulse radar) echo signal in distortion-free, smooth, and less loss, A improved threshold and shrinkage function are proposed in this paper based on the Multi-analysis wavelet threshold denoising. The denoising effects of different shrinkage function for shipborne radar echo signal were compared. The results of experiment show that better SNR and similarity and smoothness and less loss can be reached by using the proposed function to shipborne radar echo signal.

  • Shipborne Radar Servo Control based on Neural Sliding Mode Variable Structure

    In this paper, in view of the complexity of shipborne radar servo system, the position loop is controlled by sliding mode variable structure. In order to overcome the oscillation in sliding mode variable structure control, neural network and sliding mode variable structure are combined. And the control performance is analyzed and simulated. Compared with the traditional PID control, neural network adaptive sliding mode controller has better stability and anti-jamming capability.

  • New threshold and shrinkage function for shipborne radar echo signal denoising based on wavelet transforms

    In order to denoise shipborne radar (9 GHz pulse radar) echo signal in distortion-free, smooth, and less loss, a new threshold and shrinkage function are proposed in this paper based on the Multi-analysis wavelet threshold denosing. The denoising effects of different shrinkage function for shipborne radar echo signal were compared. The results of experiment show that better SNR and similarity and smoothness and less loss can be reached by using the proposed function to shipborne radar echo signal.

  • The shipborne radar antenna pattern at over-horizon object observation

    The paper considers the possibilities for shipborne radar (/spl lambda/ = 4.5 cm) to detect over-the-horizon objects in higher refraction conditions. It is shown that, due to antenna pattern adaptation to high refraction coefficient gradients in the troposphere lower layers, the radar receiver output signal- to-noise ratio can increase by 20-23 dB.

  • Non-uniform beam filling correction for spaceborne rain radar measurement: a simulation study using shipborne radar data over tropical Pacific

    A method to correct spaceborne rain radar measurement for non-uniform beam filling (NUBF) is studied using a shipborne radar data set over the tropical Pacific. Statistical analyses are made on spatial variabilities of rain rate. The result is reflected in estimating the variability in a radar IFOV which is then used to obtain a NUBF correction factor. Results indicate the usefulness of this method for reducing bias error in rain rate estimation.

  • From a high-resolution LFM-CW shipborne radar to an airport surface detection equipment

    This paper presents a modification of a linear frequency modulation-continuous waveform shipborne surveillance radar (Perez et al. (2002)) with two antennas to transform it into airport surface detection equipment with a single antenna. The most important additional subsystem for this new equipment is a reflected power canceller to overcome the problem of insufficient isolation between the transmitter and receiver due to imperfect matching between the transmitter and the antenna. This system is currently being developed by the Spanish company Indra Sistemas SA in co-operation with the Technical University of Madrid.

  • False alarm generation for simulation of shipborne radar tracking

    This paper presents a model for generating radar false alarms for panoramic radar in maritime environments in a realistic manner. False alarms as caused by system noise and sea-clutter are considered.

  • Design and Realization of Real-Time Detection System for Shipborne Radar's Rate Gyros

    As signal monitoring method of ship borne radar's rate gyros is too single to fulfill the users, the real-time detection system is designed and realized. This system can help users to judge the gyros' working order more intuitively and quickly through real-time data acquisition and graphic processing. At the same time, real-time index test and correlation detection between the correlated signals are proposed innovatively to improve the detection efficiency. So this detection system has realized the functions of real-time signal detection and fault alarm for two pairs of rate gyros, and it helps to improve the efficiency of checking and maintaining gyros' reliability. The design of this detection system can contribute to automation design of ship borne radar's servo system.

  • Array Manifold Calibration in Shipborne Radar

    Array manifold error is the key factor which influences the performance of DOA algorithm. In ship borne radar, after distance and velocity resolution, the corresponding spatial azimuth of first-order sea echo can be computed. The first-order sea echo on the fixed frequency can be considered as scale source. After array covariance matrix's eigen value decomposition, the vector corresponding to the biggest eigen value can be considered as the actual manifold vector so as to apply DOA algorithm effectively. In ship born radar, through source calibration, the performance of DOA algorithm is enhanced and the inadequacy of compensation from different influencing factors such as the discrepancy of amplitude and phase, and the coupling between array elements are also avoided.

  • Detection of surface targets in sea clutter by shipborne radar

    Doppler techniques do not aid detection by shipborne radar of small (drifting) surface targets in sea clutter, and such targets have no velocity spectrum distinguishable from that of the clutter. However, clutter decorrelation by rapid antenna scan, followed by camera or direct-view storage-tube integration, can give impressive gains in target/clutter visibility. With relative-motion displays, own ship's motion severely limits possible integration time by shifting the effective spot area of integration as the target is approached; this is neatly avoided by using a `true-motion′ display. Further gains may be possible (at least for hovercraft radar) by using an antenna with a vertical difference pattern in which the null is laid on the sea surface as a fence.



Standards related to Shipborne Radar

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No standards are currently tagged "Shipborne Radar"