1 / 21

Network of Networks: A Private-Sector Perspective

Network of Networks: A Private-Sector Perspective. 10 August 2009 AMS Summer Community Meeting Norman, OK. Walter Dabberdt Vaisala CSO Boulder, CO. Some Observations on NoN. Important follow-on to “ Fair Weather ” Partnerships are crucial Frames the problem(s) well

cayla
Download Presentation

Network of Networks: A Private-Sector Perspective

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Network of Networks:A Private-Sector Perspective 10 August 2009 AMS Summer Community Meeting Norman, OK Walter Dabberdt Vaisala CSO Boulder, CO

  2. Some Observations on NoN • Important follow-on to “Fair Weather” • Partnerships are crucial • Frames the problem(s) well • Impedance mismatch: mesoscale meteorology and synoptic observations • Offers important network design and architecture criteria (but not a network design per se) • Articulates the importance and challenges w/r/t observations of the PBL, humidity, air quality, soil moisture • Makes a strong case for comprehensive metadata & QA/QC • Need for and importance of ‘quasi-operational’ network testbeds • Frames the importance of stakeholders and their specific needs • Proposes a ‘soft’ model for a working relationship among the sectors

  3. Range of Scales Fig. 2.1 Time and space scales of ‘high-impact’ weather (source: NoN, 2008)

  4. Table 3.1 Spatial and temporal scales of several meteorological phenomena of consequence for the power-generation industry, and the required measurement resolution Event Space Time Measurement Resolution Heat wave (temp) 500-1500 km 2 days-1 week 0.5°C, 10 km, 1 hr Winda 1-2000 km 1 min-4 days 1 m s−1, 1 km, 1 min Wind (for wind power) 100 m-1000 km; to 1 kmb 10 min-1 week 0.5 m s−1, 100 m, 10 min; (1 m s−1, 30 m, 10min)b Snow and ice storms 50-1000 km minutes-2 days 1 mm snow water equiv. 1 cm snow, 1 km, 30 min Lightning region minutes to hours location to 0.5 km Precipitationc basin to regional Hours-days, 1 mm, 1 km, 1 hr. seasonal to interannual Cloudinessc local to regional daytime hourly to monthly 0.1 sky, 10 km, 20 min Waste heat impact 10 km, lakes and rivers 1 hour-4 days 0.5°C, 100 m, 1 h Normal weather urban (2 km); rural (30 km) 20 min-climate aCould be associated with a Nor’easter (4 days), icing conditions, hurricanes or tornadoes (1 min), straight-line winds, or fire weather. bMeasurements in the vertical direction. cCould be from short-term (management) or long-term (planning) for hydropower production. SOURCE: Derived from Schlatter et al. (2005). (source: NoN, 2008)

  5. Table 3.2 Key capabilities of key meteorological observations to meet public health and safety applications ParameterMeasurement Resolution Issue Horizontal Vertical Temporal Air Quality SurfaceFair n/a Good AloftPoorPoorPoor PBL Depth NBL Poor Poor Poor CBL Fair FairPoor MBL PoorPoorPoor Winds SurfaceGood n/a Good AloftFair FairPoor Temperature SurfaceGood n/a Good AloftFair FairPoor Relative Humidity SurfaceGood n/a Good AloftFair GoodPoor CloudsGoodGoodGood PrecipitationGoodn/aGood Pressure SurfaceGood n/a Good AloftGoodGoodGood NOTE: NBL, CBL, and MBL refer to the nocturnal, continental and marine boundary layers, respectively. SOURCE: Tim Dye, Sonoma Technologies, Air Quality Community’s Meteorological Data Needs. (source: NoN, 2008)

  6. Some Issues in Creating a Public-Private-Academic Enterprise • Who provides what functions? • What sectors are engaged? Public? Private? Academia? • How are the parties selected? Entry criteria? Exit criteria? • How do they work together? • What is the business model? • What is the governance? • Who are the customers? • IP rights and issues?

  7. The Value Chain Decision Support Prediction Analyses Observations  Data Technology/Sensors/Systems To be successful, the “Enterprise” must participate throughout the value chain. But, who does what?

  8. Transportation Roads & railroads Airports Marine terminals and harbors Energy industry Demand and supply forecasting Wind & solar power management Distribution Maintenance Emergency management Flooding Toxic releases – accidental & deliberate Public health and Safety Forecasts Watches and warnings Air quality alerts Heat stress and severe cold outbreaks Construction management High winds – e.g. tall crane ops Lightning Precipitation Entertainment and Recreation Outdoor entertainment & sporting venues Agriculture Freezes Irrigation Commodities exchange Insurance industry Some Example Applications of the Enterprise

  9. The Value Chain Decision Support Prediction Analyses Observations  Data Technology/Sensors/Systems To be successful, the “Enterprise” must participate throughout the value chain. But, who does what?

  10. Other Soil moisture Sensor & Other Suppliers Component Functions of the Enterprise Radar Profil- ers AWS QA & QC Infra Installation & Maintenance Commun- ications Civil Works Other? Other? Archival Modeling Operations & Command & Control Analysis Decision Support Decision- Making & Actions Sales & Marketing Governance R&D

  11. Some Rules of the Road • The value of testbeds • Learn during the demo phase • Test network designs • Establish relationships: B2B; B2G; G2B; G2G; B2G2A; etc. • Keep it simple • Play to the strengths of the different sectors • Make sure the goals are clearly defined and pursued • Address the needs of all levels of the value chain

  12. Academic Private Public • Science • People (technical resource base) • Research risk- taking • Research centers • Neutral ground • Innovation • Value-added products • Entrepreneurship • Agility • Risk taking • Efficiencies • Operational capabilities • Market expertise • Public interest • Policy justification • Infrastructure • Stable environment (incl. research) • Standards (data, metadata, interface) Primary strengths of the sectors Source: USWRP Mesoscale Workshop, Boulder, CO (2003)

  13. Strawman #1 • Business as in the past • Government leads and pays • Industry is a contractual supplier of government-dictated products and services • Academia does the R&D

  14. Strawman #2 • An emerging (though still limited) approach • Industry leads and takes financial risks and rewards • Government is a core customer among many customers • Academia does directed R&D for industry and government

  15. Other Strawmen • Industry, academia and government form a new joint venture? Isn’t this happening today with the banks and auto industry (govt. + industry) but also CPB, Amtrak, USPS? • Or, government creates a GOCO (Government-Owned, Contractor Operated facility that is owned by the Government and operated under contract by a non-governmental, private firm) • All parties do their own thing, collaborating where there is mutual benefit?

  16. The NoN Recommendation

  17. The CASA Approach • Vision: to enable vastly improved detection and prediction of adverse weather, and mitigate the associated societal and economic impacts • Goals: Implement, in an operational context, CASA-developed remote sensing and DCAS (together with other) technologies that will enable marked improvements in decision-making for a variety of applications • Strategy: • Throughout the remaining lifetime of the CASA ERC, develop, improve and test sensing, modeling, and decision-support tools • Deploy and test one or more advanced, quasi-operational networks to demonstrate the benefits and viability of the concept, which provide the justification for • Ultimately: Implement a nationwide capability

  18. CASA's Concept of a distributed adaptive network

  19. CASA’s R2O Transition Plan Industrial Advisory Board (IAB): Public Sector Members: NOAA-NWS DOE EC Private Sector Members: Vaisala Inc. Raytheon Co. EWR Weather Radar WeatherNews International ITT Electronic Systems-Gilfillan OneNet DeTect Inc. IBM Natl. Res. Institute for Earth Science and Disaster Prevention (NIED)  News 9 Oklahoma State Board of Regents for Education University Partners: U. Mass. U. Oklahoma CSU UPR-Mayaguez IAB Members Non-IAB Members private sector; public sector Create and operate a quasi-operational multi-functional network the enterprise IAB + Univs. Suppliers Non-IAB Members IAB Members & university partners service

  20. CASA’s R2O Transition Plan Industrial Advisory Board (IAB): Public Sector Members: NOAA-NWS DOE EC Private Sector Members: Vaisala Inc. Raytheon Co. EWR Weather Radar WeatherNews International ITT Electronic Systems-Gilfillan OneNet DeTect Inc. IBM Natl. Res. Institute for Earth Science and Disaster Prevention (NIED)  News 9 Oklahoma State Board of Regents for Education IAB Members Non-IAB Members private sector; public sector ‘testbed’ = a quasi-operational multi-functional network the enterprise Suppliers Non-IAB Members IAB Members & university partners service

  21. The End mailto: walter.dabberdt@vaisala.com

More Related