1 / 16

Supplemental Topic

Supplemental Topic. Weather Analysis and Forecasting. Background. Weather analysis Using maps, charts, tables, or any other data to determine what is happening or what happened Presumably precise and accurate Weather forecasting

moses-zamora
Download Presentation

Supplemental Topic

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. Supplemental Topic Weather Analysis and Forecasting

  2. Background • Weather analysis • Using maps, charts, tables, or any other data to determine what is happening or what happened • Presumably precise and accurate • Weather forecasting • Predicting what may occur using analyses, observations, computer models, education, & experience • Considered imperfect • Must know composition of atmosphere • Atmospheric conditions constantly changing • Complicated further by complex terrain, limited understanding of atmosphere, operating costs, disagreement among forecast models, etc.

  3. Use of Weather Maps in Analysis • Two types of maps • 1. Surface • 2. Upper-air • Surface and upper-levels of atmosphere interact constantly at a wide range of scales • Meteorologists/climatologists must be able to keep both surface and upper-air in mind when performing analyses and making forecasts

  4. Surface Maps • General representation of pressure patterns and fronts (isobars, pressure centers, precip, etc.) • Can determine what happened by looking at consecutive maps • Can infer what is occurring using what learned to this point • Station models – symbols that show conditions at a location at observation time

  5. Station Model

  6. Upper-air Maps • Measurements for location of launch plotted on thermodynamic chart for use in forecast • Maps produced for “standard levels” – 1000mb, 850mb, 700mb, 500mb, 300mb, 250mb, 200mb • Provide height of pressure level, temp, dewpoint (or dewpoint depression), wind speed and direction, and (at 300, 250, 200mb), location of jet stream • Analyze for troughs, ridges, advection of warm/cool air, divergence/convergence, etc.

  7. Thermodynamic Chart

  8. Examples of Upper-air Maps 850mb 500mb 700mb 300mb

  9. Other Analysis Tools • Satellite • Generally use three types of imagery: visible, infrared, water vapor • Also sounder data • Radar • Pulses of energy sent out by radar, hit object (hopefully precip.), energy returned to radar reveals distance and number/size of particles • Useful for detecting precipitation, fronts, tornadoes, wind direction, and even masses of insects or flocks of birds

  10. Forecasting Procedures • Analysis: just discussed • Prediction • Models use data to solve equations that estimate behavior of atmosphere • Equations solved at various intervals and use previous results in subsequent forecast – why should this concern a forecaster? (chaos) • Post-processing • Production of maps from model output • Usefulness of model data varies by location, time of year, conditions, and forecaster ability • Model output statistics (MOS) try to take local factors, such as topography, into account

  11. Forecasting Methods • Climatological • Based on long-term averages • Accuracy and precision vary by location • Persistence • Based on trends: current conditions will continue • Usually reliable for short periods • Analog • Based on records: what happened in past under similar conditions? • Could lead to poor forecast – why? • Numerical • Based on output from computer models/programs • Must rely on accuracy of model given initial condition

  12. Three Types of Forecasts • Quantitative • Predicts specific value • Examples: precipitation amount, temperature • Qualitative • Predicts class or category • Examples: type of precipitation, partly cloudy • Probability • Chance of event occurring (in percent) • Likelihood of rain

  13. Three Types of Forecasts TONIGHT...PARTLY CLOUDY... SCATTERED SHOWERS AND THUNDERSTORMS MAINLY IN THE EVENING. LOWS 68 TO 78. WEST WIND 5 TO 10 MPH BECOMING SOUTHEAST AROUND 5 MPH AFTER MIDNIGHT. CHANCE OF PRECIPITATION 30 PERCENT.

  14. Forecast Periods • “Nowcasts” • What’s happening now and what’s expected in next few hours • Most detailed, usually most accurate • Short-term • Covers from 3 to 72 hours • Fairly detailed, accuracy tends to decrease a bit • Medium range • 72 hrs to 7-10 days • Utilize ensemble forecasts • Detail and accuracy decrease, esp. after 7 days • Long range • Performed by Climate Prediction Center (in US) • Ranges from end of medium range to weeks, months, or longer • Made of period (not individual days), probability usually low, skill varies by location, time of year, and variable forecasted • Use climatology, numerical models, statistics, and subjective judgment

  15. Assessing Forecasts/Post-processing • Need to determine usefulness of data and forecasts, justify expenditures, and predict importance of changes • Quality vs. value • Quality: is forecast right? : Example: did it rain in Tucson as predicted? • Value: does forecast perform desired goals? : Example – did hurricane warning work? • Accuracy vs. skill • Accuracy: how close are predicted and actual conditions? • Skill: is method used the best choice?

  16. Limitations on Forecasting • Computing power • Understanding of atmosphere • Funding/expenses • Chaos • Model error • Stubborn and/or old-school forecasters • Human error • Coverage of instruments for measurements/observations

More Related