Conferences related to Operational Oceanography

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Oceans 2020 MTS/IEEE GULF COAST

To promote awareness, understanding, advancement and application of ocean engineering and marine technology. This includes all aspects of science, engineering, and technology that address research, development, and operations pertaining to all bodies of water. This includes the creation of new capabilities and technologies from concept design through prototypes, testing, and operational systems to sense, explore, understand, develop, use, and responsibly manage natural resources.

  • OCEANS 2018 MTS/IEEE Charleston

    Ocean, coastal, and atmospheric science and technology advances and applications

  • OCEANS 2017 - Anchorage

    Papers on ocean technology, exhibits from ocean equipment and service suppliers, student posters and student poster competition, tutorials on ocean technology, workshops and town meetings on policy and governmental process.

  • OCEANS 2016

    The Marine Technology Scociety and the Oceanic Engineering Society of the IEEE cosponor a joint annual conference and exposition on ocean science, engineering, and policy. The OCEANS conference covers four days. One day for tutorials and three for approx. 500 technical papers and 150 -200 exhibits.

  • OCEANS 2015

    The Marine Technology Scociety and the Oceanic Engineering Society of the IEEE cosponor a joint annual conference and exposition on ocean science, engineering, and policy. The OCEANS conference covers four days. One day for tutorials and three for approx. 450 technical papers and 150-200 exhibits.

  • OCEANS 2014

    The OCEANS conference covers four days. One day for tutorials and three for approx. 450 technical papers and 150-200 exhibits.

  • OCEANS 2013

    Three days of 8-10 tracks of technical sessions (400-450 papers) and concurent exhibition (150-250 exhibitors)

  • OCEANS 2012

    Ocean related technology. Tutorials and three days of technical sessions and exhibits. 8-12 parallel technical tracks.

  • OCEANS 2011

    The Marine Technology Society and the Oceanic Engineering Scociety of the IEEE cosponsor a joint annual conference and exposition on ocean science engineering, and policy.

  • OCEANS 2010

    The Marine Technology Society and the Oceanic Engineering Scociety of the IEEE cosponsor a joint annual conference and exposition on ocean science engineering, and policy.

  • OCEANS 2009

  • OCEANS 2008

    The Marine Technology Society (MTS) and the Oceanic Engineering Society (OES) of the Institute of Electrical and Electronic Engineers (IEEE) cosponsor a joint conference and exposition on ocean science, engineering, education, and policy. Held annually in the fall, it has become a focal point for the ocean and marine community to meet, learn, and exhibit products and services. The conference includes technical sessions, workshops, student poster sessions, job fairs, tutorials and a large exhibit.

  • OCEANS 2007

  • OCEANS 2006

  • OCEANS 2005

  • OCEANS 2004

  • OCEANS 2003

  • OCEANS 2002

  • OCEANS 2001

  • OCEANS 2000

  • OCEANS '99

  • OCEANS '98

  • OCEANS '97

  • OCEANS '96


2019 IEEE International Geoscience and Remote Sensing Symposium (IGARSS)

International Geosicence and Remote Sensing Symposium (IGARSS) is the annual conference sponsored by the IEEE Geoscience and Remote Sensing Society (IEEE GRSS), which is also the flagship event of the society. The topics of IGARSS cover a wide variety of the research on the theory, techniques, and applications of remote sensing in geoscience, which includes: the fundamentals of the interactions electromagnetic waves with environment and target to be observed; the techniques and implementation of remote sensing for imaging and sounding; the analysis, processing and information technology of remote sensing data; the applications of remote sensing in different aspects of earth science; the missions and projects of earth observation satellites and airborne and ground based campaigns. The theme of IGARSS 2019 is “Enviroment and Disasters”, and some emphases will be given on related special topics.


2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

robotics, intelligent systems, automation, mechatronics, micro/nano technologies, AI,


OCEANS 2019 - Marseille

Research, Development, and Operations pertaining to the Oceans

  • OCEANS 2020 - SINGAPORE

    An OCEANS conference is a major forum for scientists, engineers, and end-users throughout the world to present and discuss the latest research results, ideas, developments, and applications in all areas of oceanic science and engineering. Each conference has a specific theme chosen by the conference technical program committee. All papers presented at the conference are subsequently archived in the IEEE Xplore online database. The OCEANS conference comprises a scientific program with oral and poster presentations, and a state of the art exhibition in the field of ocean engineering and marine technology. In addition, each conference can have tutorials, workshops, panel discussions, technical tours, awards ceremonies, receptions, and other professional and social activities.

  • 2018 OCEANS - MTS/IEEE Kobe Techno-Ocean (OTO)

    The conference scope is to provide a thematic umbrella for researchers working in OCEAN engineering and related fields across the world to discuss the problems and potential long term solutions that concernnot only the oceans in Asian pacific region, but the world ocean in general.

  • OCEANS 2017 - Aberdeen

    Papers on ocean technology, exhibits from ocean equipment and service suppliers, student posters and student poster competition, tutorials on ocean technology, workshops and town hall meetings on policy and governmental process.

  • OCEANS 2016 - Shanghai

    Papers on ocean technology, exhibits from ocean equipment and service suppliers, student posters and student poster competition, tutorial on ocean technology, workshops and town hall meetings on policy and governmental process.

  • OCEANS 2015 - Genova

    The Marine Technology Society and the Oceanic Engineering Society of IEEE cosponsor a joint annual conference and exposition on ocean science, engineering and policy. The OCEANS conference covers four days. One day for tutorials and three for approx. 450 technical papers and 50-200 exhibits.

  • OCEANS 2014 - TAIPEI

    The OCEANS conference covers all aspects of ocean engineering from physics aspects through development and operation of undersea vehicles and equipment.

  • OCEANS 2013 - NORWAY

    Ocean related technologies. Program includes tutorials, three days of technical papers and a concurrent exhibition. Student poster competition.

  • OCEANS 2012 - YEOSU

    The OCEANS conferences covers four days with tutorials, exhibits and three days of parallel tracks that address all aspects of oceanic engineering.

  • OCEANS 2011 - SPAIN

    All Oceans related technologies.

  • OCEANS 2010 IEEE - Sydney

  • OCEANS 2009 - EUROPE

  • OCEANS 2008 - MTS/IEEE Kobe Techno-Ocean

  • OCEANS 2007 - EUROPE

    The theme 'Marine Challenges: Coastline to Deep Sea' focuses on the significant challenges, from the shallowest waters around our coasts to the deepest subsea trenches, that face marine, subsea and oceanic engineers in their drive to understand the complexities of the world's oceans.

  • OCEANS 2006 - ASIA PACIFIC

  • OCEANS 2005 - EUROPE


2018 41st International Convention on Information and Communication Technology, Electronicsand Microelectronics (MIPRO)

Computer in Technical Systems, Intelligent Systems, Distributed Computing and VisualizationSystems, Communication Systems, Information Systems Security, Digital Economy, Computersin Education, Microelectronics, Electronic Technology, Education


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Periodicals related to Operational Oceanography

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Computing in Science & Engineering

Physics, medicine, astronomy—these and other hard sciences share a common need for efficient algorithms, system software, and computer architecture to address large computational problems. And yet, useful advances in computational techniques that could benefit many researchers are rarely shared. To meet that need, Computing in Science & Engineering (CiSE) presents scientific and computational contributions in a clear and accessible format. ...


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.


Mechatronics, IEEE/ASME Transactions on

Synergetic integration of mechanical engineering with electronic and intelligent computer control in the design and manufacture of industrial products and processes. (4) (IEEE Guide for Authors) A primary purpose is to have an aarchival publication which will encompass both theory and practice. Papers will be published which disclose significant new knowledge needed to implement intelligent mechatronics systems, from analysis and ...


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.


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Most published Xplore authors for Operational Oceanography

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Xplore Articles related to Operational Oceanography

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CORIOLIS, a French project for in situ operational oceanography

Europe Oceans 2005, 2005

The seven French agencies concerned by ocean research are developing together a strong capability in operational oceanography based on a triad including satellite altimetry (JASON), numerical modelling with assimilation (MERCATOR), and in-situ data (CORIOLIS).


Improving software engineering processes to support operational oceanography

OCEANS '02 MTS/IEEE, 2002

This paper presents a plan to improve software engineering processes based on the Carnegie Mellon University Software Engineering Institute Capability Maturity Model. The perspective is from an organization that performs information processing of oceanographic data. The objective of the plan is to create software quality that is repeatable. Special emphasis is given to key process areas that must be addressed ...


Production management and control for operational oceanography

MTS/IEEE Oceans 2001. An Ocean Odyssey. Conference Proceedings (IEEE Cat. No.01CH37295), 2001

The mission of the Naval Oceanographic Office (NAVOCEANO) is to conduct multidisciplinary military ocean surveys, collect and analyze oceanographic data, and generate operationally significant products and services that address Navy and Department of Defense oceanographic needs, as well as those of academia and civil agencies. NAVOCEANO provides near-real-time and long- term oceanographic product support in the form of text, graphics, ...


Real-time operational oceanography at the Naval Oceanographic Office

Oceans 2003. Celebrating the Past ... Teaming Toward the Future (IEEE Cat. No.03CH37492), 2003

Summary form only given. Scientists of the Naval Oceanographic Office (NAVOCEANO) provide specialized operationally-significant products and services for military "warfighters." These products are also provided for civilian, national and international customers under some circumstances and with some constraints. Our scientists acquire global ocean and littoral data from sources such as: shipboard surveys by NAVOCEANO and others, from routine data collected ...


Operational oceanography for the North West European Shelf seas: NOOS 2002–2006

2006 IEEE US/EU Baltic International Symposium, 2006

Arising from the EuroGOOS North-West Shelf task team, the North-West Shelf Operational Oceanographic System NOOS was established in September 2002, with national agencies signing a memorandum of understanding. Membership of NOOS has now grown to 14 agencies, with responsibilities ranging from monitoring to forecast modelling, and there are four associate research institutes. Members of NOOS routinely provide a range of ...


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Educational Resources on Operational Oceanography

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IEEE-USA E-Books

  • CORIOLIS, a French project for in situ operational oceanography

    The seven French agencies concerned by ocean research are developing together a strong capability in operational oceanography based on a triad including satellite altimetry (JASON), numerical modelling with assimilation (MERCATOR), and in-situ data (CORIOLIS).

  • Improving software engineering processes to support operational oceanography

    This paper presents a plan to improve software engineering processes based on the Carnegie Mellon University Software Engineering Institute Capability Maturity Model. The perspective is from an organization that performs information processing of oceanographic data. The objective of the plan is to create software quality that is repeatable. Special emphasis is given to key process areas that must be addressed and how these areas relate to the production processes of operational oceanography products. Oceanographic organizations that pursue improvements to software engineering processes may realize significant increases in the quality of their software and, as a result, the information and products that their software produces.

  • Production management and control for operational oceanography

    The mission of the Naval Oceanographic Office (NAVOCEANO) is to conduct multidisciplinary military ocean surveys, collect and analyze oceanographic data, and generate operationally significant products and services that address Navy and Department of Defense oceanographic needs, as well as those of academia and civil agencies. NAVOCEANO provides near-real-time and long- term oceanographic product support in the form of text, graphics, remotely sensed products, and databases. NAVOCEANO constitutes a production environment for analyzing oceanographic features from in situ data, imagery, and databases and for producing tailored and standard products for a myriad of operational customers. Production can consist of automated processing, database creation, or scientific analysis of various data sets. To track the requirements and requests for products from receipt to dissemination, the production process has been captured in a workflow software package called Forward Looking Office Workflow (FLOW). This paper describes a system to meet production management requirements for operational products at NAVOCEANO. It will describe the current use of the FLOW software and an initiative to integrate FLOW into the hydrographic production process. A link will be made between the FLOW software and a commercial off-the-shelf performance management software, Panorama Business Views (PBViews), to give an office-wide perspective on production management and performance.

  • Real-time operational oceanography at the Naval Oceanographic Office

    Summary form only given. Scientists of the Naval Oceanographic Office (NAVOCEANO) provide specialized operationally-significant products and services for military "warfighters." These products are also provided for civilian, national and international customers under some circumstances and with some constraints. Our scientists acquire global ocean and littoral data from sources such as: shipboard surveys by NAVOCEANO and others, from routine data collected by both operational Navy and commercial ships, from remotely- sensed data available from a variety of airborne and satellite sensors, and from drifting and fixed-location buoys. The analyses of these data range from the creation of historical climatologies and real-time maps of specific measured parameters to the assimilation of real-time data into ocean prediction systems for temperature, salinity, tides, waves, and currents. NAVOCEANO products are primarily requested from and delivered to the customer through the Warfighting Support Center (WSC). The WSC provides analyses of the oceanographic environment using multiple data sources. Dynamic and morphologic features of coastal areas are extracted from satellite imagery within the WSC, which then blends bathymetric, hydrologic, climatologic and predictive information from other departments and organizations into operational products tailored to specific mission requirements. These products are frequently geo- spatially enabled for automated information system use and delivered via web technology.

  • Operational oceanography for the North West European Shelf seas: NOOS 2002–2006

    Arising from the EuroGOOS North-West Shelf task team, the North-West Shelf Operational Oceanographic System NOOS was established in September 2002, with national agencies signing a memorandum of understanding. Membership of NOOS has now grown to 14 agencies, with responsibilities ranging from monitoring to forecast modelling, and there are four associate research institutes. Members of NOOS routinely provide a range of services to their national governments, and some are also demonstrating this through participation in GMES service element projects funded by the European Space Agency. NOOS works through networking to establish collaborative, incremental developments to the day-to- day business of the member agencies. Thus NOOS activities are truly sustainable. Where available, individual member agencies gain project funding from national or European Commission Framework Program research projects. NOOS activities include data exchange for sea level observations and storm surge forecasts, cooperation on development of 3D forecast modelling, contribution to the ICES-EuroGOOS North Sea pilot project for an ecosystem-based approach to fisheries management, exchange of calculated model transports, and bi- lateral developments to provide robust and resilient backup for storm surge forecast modelling. Data exchange within NOOS is being actively developed and this will contribute to the SEPRISE project demonstration during 2006.

  • Examples of practical mechanisms for improving the coordination of operational oceanography at a national and international level

    Achieving the goals for the Global Ocean Observing System (GOOS) and the wider Global Earth Observation System of Systems (GEOSS) requires the coordinated effort of many nations and many types of organization. To be successful GOOS must be underpinned by a diverse range of partnerships which bring together governmental, academic and private sector organizations at a national and an international level. This paper provides three examples of practical mechanisms which contribute to building a global observing and forecasting system able to deliver products and services to end-users and customers

  • Educational needs in the changing field of operational oceanography: training the people that will sustain Munk's 1+1 = 3 scenario

    The Rutgers University Graduate Program in Oceanography (GPO) has initiated a new Masters Degree in Oceanographic Technologies. Within the collaborative setting of the Rutgers University (R.U.) Coastal Ocean Observation Lab's (COOL) Operations Center, students will receive hands-on training in the use of advanced ocean observing technologies and will participate in the year- round field activities supported by the Center. Potential Masters, theses topics include improvements to the capabilities of sensors and sampling platforms, and the analysis of the observatory datasets for a wide spectrum of applications. The program was designed with input from a pair of AMS Interactive Workshops on Operational Oceanography, and with input from people working in Navy and NOAA operational centers. Graduates will directly support the sustained technology needs of the Integrated Ocean Observing System and the Ocean Observation Initiative.

  • Surface circulation and Lagrangian transport in the SE Bay of Biscay from HF radar data

    Two HF Radar CODAR SeaSonde stations are working operationally in the south- eastern Bay of Biscay since 2009 (Fig. 1). The HF radar stations are emitting at a central frequency of 4.86 MHz and provide hourly surface currents with 5 km radial and 5° angular resolutions and a 150 km mean radial coverage. The examination of 3 year HF radar data reveals a well-defined seasonal variability of sea surface currents and the circulation along the slope in the area. In this contribution different Lagrangian exercises have been performed to evaluate the skills of the HF radar system to reproduce the drifter trajectories available in the study area at different periods. The mean distance observed between real and radar derived trajectories after 6 hours of simulation is of 4.6 km. Moreover, a description of the surface circulation in the area from a Lagrangian point of view is provided, with regard to the variability observed at different time-space scales. In addition to a well- defined seasonality, the presence of mesoscale cyclonic and anticyclonic eddies is recurrent in the area covered by the HF radar. Mesoscale variability is observed to have a substantial impact on the Lagrangian transport in the area.

  • Development of operational oceanography in Greece by means of the POSEIDON system

    The POSEIDON system consists of the following three major components: a marine monitoring network (POSEIDON network) and the corresponding telecommunication devices, an operational centre for data management, analysis and dissemination of the products to the user community, as well as an operational forecasting system including an operational wave and weather forecasting model, a 3-D hydrodynamic model and a buoyant pollutant transport model. Operational oceanography in Greece has been until now in its infancy mostly due to the lack of marine monitoring systems. The POSEIDON project fills this gap and gives an opportunity to efficiently match scientific efforts with up-to-date technological applications. The authors discuss and analyze some principles, issues and strategies related to the development of operational oceanography in Greece by means of the POSEIDON system. To achieve this goal a brief description of the POSEIDON system is made. The strategic and scientific plan of the POSEIDON project reveals some of the most important aspects that should be borne in mind in order to increase the expected benefits from the POSEIDON project.

  • Evaluation of wind forecasts above sea surface obtained from numerical models of atmosphere

    Wind parameter data sets, obtained from the mesoscale atmosphere model UMPL, were compared with data recorded by the MIG-1 measurement buoy of the Maritime Institute in Gdansk, which was anchored near the Hel Peninsula. Significant agreement between the simulation and field observations was achieved, and carried out statistical analysis allowed a qualitative assessment of model data used for analysing and predicting wind conditions over the open sea. An increase of the model resolution, especially in areas close to the coast, should significantly decrease existing inaccuracies.



Standards related to Operational Oceanography

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Jobs related to Operational Oceanography

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