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Forecasting Convection An overview of how radar can help in the forecast process. Presentation to MSC radar course, March 24, 2010 By James Cummine, Lead Meteorologist PASPC – Winnipeg Winnipeg, MB CANADA james.cummine@ec.gc.ca. About me….
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Forecasting ConvectionAn overview of how radar can help in the forecast process. Presentation to MSC radar course, March 24, 2010 By James Cummine, Lead Meteorologist PASPC – Winnipeg Winnipeg, MB CANADA james.cummine@ec.gc.ca
About me… • Started as a Severe Weather assistant (summer student) in 1985 in Winnipeg • Forecast for the Prairies most of my 25 year career • Some time in Science Division in mid 1990’s • Worked on evapotranspiration studies – “Role of ET in Convection on the Prairies” • COMET liaison meteorologist 2005 – 2008 • Olympic forecaster – 2010 Winter Olympics
Goal of this presentation • Not to teach you about convection • All very well explained in the COMET modules and other places • Not to teach you about specific radar products or URP • But to help you understand what you are seeing and ANTICIPATE how it will evolve. • We want to forecast the weather, not observe it!
Introduction • Radar observes the weather • Forecasters use the observations to help make a diagnosis • With the diagnosis, forecasters can then make a prognosis • Warnings are issued based on the diagnosis from radar observations • The Radar does NOT forecast! • Thus forecasters need to understand what they are looking at!
Summary • Don’t rely solely on the radar • Use the radar (with caution) to aid in the forecast process • (Observation/analysis – Diagnosis – Prognosis) • A strong understanding of conceptual models and situational awareness lead to quick and accurate decisions in “short-fuse” situations
Radar in Operations • Variety of Products • Different GUI’s (Graphical User Interface) and ways to view the products • Animation • Algorithms • Experience and understanding
Experience and understanding • Know strengths and limitations of radar • Products • Algorithms • Scanning strategy • Colour enhancements • Situational awareness • Pre-storm environment • Most probable area for development
Radar Limitations • Distance from radar of convective cell • Height of the beam above ground (where is it really sampling the cell in a CAPPI) • Attenuation • Dome wetting • Behind another cell • Time between scans • Scanning strategy
Situational Awareness • A good work-up • Dynamic features • Thermodynamic parameters • Monitor evolution of situation • Cap strength • Moisture flux • Surface convergence • Changing stability (convective temperature)
Anticipation • What types of storms are most likely to develop and how will they evolve? • Super cell • Multicell lines (bow echo’s, Derecho, etc) • “popcorn” convection • Plan warning strategy in advance • Are watches already issued? • What is the “expected” motion (including a “right deviator”) • Be aware of any heavily populated areas/activities • Campgrounds, outdoor concerts, fairs, etc.
Final moments • Why are you waiting for one more scan? • Be proactive and warning “in advance” don’t observe and react. • Be confident of your analysis and diagnosis • Radar shows you what you already think will happen…however, don’t deny what you see; make sure you understand it.
Identifying Features • Knowledge of conceptual models • Super cell • Squall line, usually with super cells embedded (or at end) • Bow Echo, Derecho • Outflow boundary, Sea/lake breeze convergence boundary • Use animation – motion and evolution • Use all products (CAPPI, doppler velocity, cross sections, etc.) • Remember radar limitations (attenuation, dome wetting)
Super Cell • Classic super cell • Lemon conceptual model • Overhang/BWER • RFD/outflow boundary
Squall Line/Bow Echo • May have to connect the dots • Development typically on south end (in NA/NH) • Watch for embedded super cells (“right-movers” or “left-movers”) • Cells developing out ahead of the line • Atypical synoptic flows (northwest vs southwest)
Outflow boundary/Convergence zones • Use lowest level scan • Only close to radar • Remember height of beam above ground • Extrapolate motion • Anticipate collisions/rapid development
Wind/Gust Fronts • “Who has seen the wind?” • Radar detects targets – usually precipitation • Watch for descending jets (RFD) • Keep in mind storm motion and synoptic flow (adding/subtracting from speed) • Remember beam elevation and “wind on the ground” (slope) • Warn before it gets there!
Examples Some “pretty pictures”
Final Wrap-up • Radars are a great tool for observations Leads to better diagnosis • By using a knowledge of convective storms, good situational awareness and recent radar observations Forecasters can issue warnings in advance of event reaching a location!