NATS 101-06 Lecture 23 Weather (and Climate) Forecasting

Review: ET Cyclones Ingredients for Intensification Strong Temperature Contrast Jet Stream Overhead S/W Trough to West UL Divergence over Surface Low If UL Divergence exceeds LL Inflow, Cyclone Deepens Similar Life Cycles deepening filling Ahrens, Meteorology Today, 5th Ed.

Reasons to Forecast Weather & Climate Should I bring my umbrella to work today? Should Miami be evacuated for a hurricane? How much heating oil should a refinery process for the upcoming winter? Will the average temperature change if CO2 levels double during the next 100 years? How much to charge for flood insurance? These questions require weather-climate forecasts for today, a few days, months, years, decades

Forecasting Questions How are weather forecasts made? How accurate are current weather forecasts? How accurate can weather forecasts be? We will emphasize mid-latitude forecasts out to 15 days where most progress has been made. PLUS comments about climate models where relevant

Types of Forecasts Persistence - forecast the future atmospheric state to be the same as current state -Raining today, so forecast rain tomorrow -Useful for few hours to couple days

Types of Forecasts Trend - add past change to current condition to obtain forecast for the future state -Useful for few hours to couple days 10 am 11 am 12 pm 59 F 63 F 67 F Past Now Future

Types of Forecasts Analog - find past state that is most similar to current state, then forecast same evolution -Difficulty is that no two states exactly alike -Useful for forecasts up to one or two days Can be useful for seasonal forecasts

Types of Forecasts Climatology - forecast future state to be same as climatology or average of past weather for date -Forecast July 4th MAX for Tucson to be 100 F -Most accurate for long forecast projections, forecasts longer that 30 days

Types of Forecasts Numerical Weather Prediction (NWP) - use mathematical models of physics principles to forecast future state from current conditions. Process involves three major phases Analysis Phase (most expensive piece) Prediction Phase (modeling, computing) Post-Processing Phase (use of products) To justify NWP cost, it must beat forecasts of persistence, trend, analog and climatology

Analysis Phase PURPOSE: to generate the best estimate of the state of the atmosphere (e.g. density, press, temp, winds, humidity, clouds), and the state of the ocean and land which are needed to start the next weather forecast cycle The analysis state estimate is a combination of the latest observations and the most recent weather forecast

Analysis Phase Current weather conditions are observed around the globe (surface data, radar, weather balloons, satellites, aircraft). Millions of observations are transmitted via the Global Telecommunication System (GTS) to the various weather centers. U.S. center is in D.C. and is named National Centers for Environmental Prediction (NCEP)

Analysis Phase The operational weather centers sort, archive, and quality control the observations. Computers then combine the latest observations and most recent weather forecast to generate the weather analysis and draw maps to help us interpret weather patterns. Procedure is called Objective Analysis. Final chart is referred to as an Analysis. Computer models at weather centers make global or national weather forecast maps

Sparse data over oceans and Southern Hemisphere Surface Data Sparse data over oceans and Southern Hemisphere Courtesy ECMWF

Some buoy data over Southern Hemisphere Surface Buoy Reports Some buoy data over Southern Hemisphere Courtesy ECMWF

Little data over oceans and Southern Hemisphere Radiosonde Coverage Little data over oceans and Southern Hemisphere Courtesy ECMWF

Little data over oceans and Southern Hemisphere Aircraft Reports Little data over oceans and Southern Hemisphere Courtesy ECMWF

Weather Satellites Satellite observations fill data void regions Geostationary Satellites High temporal sampling Lower horizontal resolution Limited vertical information Can’t penetrate clouds (yet) Polar Orbiting Satellites Low temporal sampling Higher horizontal resolution Geostationary Polar Orbit Ahrens, Figs. 9.5 & 9.6

Obs from Geostationary Satellites Courtesy ECMWF

Temperature from Polar Satellites Courtesy ECMWF

Prediction Phase: Atmospheric Models Weather models are based on mathematical equations that represent the most important aspects of atmospheric behavior - Newton's 2nd Law (density, press, wind) - Conservation of mass (density, wind) - Conservation of energy (temp, wind) - Equation of state (density, press, temp) Governing equations relate time changes of fields to spatial distributions of the fields e.g. warm to south + southerly winds  warming

Prediction Phase Analysis of the current atmospheric state (wind, temp, press, moisture) are fed into the model equations Equations are solved for a short time period (~5 minutes) over a large number (107 to 108) of discrete locations called grid points Grid spacing is 5 km to 50 km horizontally and 100 m to 500 m vertically

Model Grid Boxes 100-500 m 10-20 km

“A Lot Happens Inside a Grid Box” (Tom Hamill, CDC/NOAA) Rocky Mountains Approximate Size of One Grid Box for NCEP Global Ensemble Model Note Variability in Elevation, Ground Cover, Land Use Denver 50 km Source: www.aaccessmaps.co

13 km Model Terrain Big mountain ranges, like the Sierra Nevada Range, are resolved. But isolated peaks, like the Catalinas, are not evident! 100 m contour

Post-Processing Phase Computer then draws maps of projected state to help humans interpret weather forecast Observations, analyses and forecasts are disseminated to private and public agencies, such as the local NWS Forecast Office and UA Forecasters use the computer maps, along with knowledge of local weather phenomena and model performance, to issue regional forecasts News media broadcast these forecasts to public

Suite of Official NWS Forecasts CPC Predictions Page

SST Forecast Example (from January 2006) Forecasts of El Nino and La Nina generally did not forecast present El Nino but some ensemble members did come close

3-Month SST Forecast (Issued October 23, 2006) SST forecasts for the El Nino region of tropical Pacific are a crucial component of seasonal and yearly forecasts. Forecasts of El Nino and La Nina show skill out to around 12 months. Current El Nino

Winter 2004-2005 Outlook (Issued 20 October 2005)

Winter 2004-2005 Outlook (Issued 18 March 2004)

Winter 2004-2005 Outlook (Issued 18 March 2004)

NCEP GFS Forecasts ATMO GFS Link NCEP global forecast; 4 times per day Run on 50 km grid (approximately) GFS gives the best 2-10 day forecasts

NCEP GFS Forecasts ATMO NAM Link NCEP CONUS forecast; 4 times per day Run on 12 km grid (approximately) NAM gives the best 24 h precip forecasts

Different Forecast Models Ahrens 2nd Ed. Akin to Fig 9.1 Different, but equally defensible models produce different forecast evolutions for the same event. Although details of the evolutions differ, the large-waves usually evolve very similarly out to 2 days. AVN-ETA-NGM Comparison

Forecast Evaluation: Accuracy and Skill Accuracy measures the closeness of a forecast value to a verifying observation Accuracy can be measured by many metrics Skill compares the accuracy of a forecast against the accuracy of a competing forecast A forecast must beat simple competitors: Persistence, Climatology, Random, etc. If forecasts consistently beat these competitors, then the forecasts are said to be “skillful”

How Humans Improve Forecasts Local geography in models is smoothed out. Model forecasts contain small, regional biases. Model surface temperatures must be adjusted, and local rainfall probabilities must be forecast based on experience and statistical models. Small-scale features, such as thunderstorms, must be inferred from long-time experience. If model forecast appears systematically off, human corrects it using current information.

Humans Improve Model Forecasts Forecasters perform better than automated model and statistical forecasts for 24 and 48 h. Human forecasters play an important role in the forecasting process, especially during severe weather situations that impact public safety. Max Temp Accuracy Aguado and Burt Rainfall Skill

Current Skill 0-12 hrs: Can track individual severe storms 12-48 hrs: Can predict daily weather changes well, including regions threatened by severe weather. 3-5 days: Can predict major winter storms, excessive heat and cold snaps. Rainfall forecasts are less accurate. 6-15 days: Can predict average temp and rain over 5 day period well, but daily changes are not forecast well. 30-90 days: Slight skill for average temp and rainfall over period. Forecasts use combination of model forecasts and statistical relationships (e.g. El Nino). 90-360 days: “Slight” skill for SST anomalies.

Why NWP Forecasts Go Awry There are inherent flaws in all NWP models that limit the accuracy and skill of forecasts Computer models idealize the atmosphere Assumptions can be on target for some situations and way off target for others

Why NWP Forecasts Go Awry All analyses contain errors Regions with sparse or low quality observations - Oceans have “poorer” data than continents Instruments contain measurement error - A 20oC reading does not exactly equal 20oC Even a precise measurement at a point location might not accurately represent the big picture - Radiosonde ascent through isolated cumulus

Why NWP Forecasts Go Awry Insufficient resolution Weather features smaller than the grid point spacing do not exist in computer forecasts Interactions between the resolved larger scales and the excluded smaller scales are absent Inadequate representations of physical processes such as friction and heating Energy and moisture transfer at the earth's surface are not precisely known

Chaos: Limits to Forecasting We now know that even if our models were perfect, it would still be impossible to predict precisely winter storms beyond 10-14 days There are countless, undetected small errors in our initial analyses of the atmosphere These small disturbances grow with time as the computer projects farther into the future Lorenz posed, “Does the flap of a butterfly’s wings in Brazil set off a tornado in Texas?”

Chaos: Limits to Forecasting After a few days, these initial imperfections dominate forecasts, rendering it useless. Chaotic physical systems are characterized by unpredictable behavior due to their sensitivity to small changes in initial state. Evolutions of chaotic systems in nature might appear random, but they are bounded. Although bounded, they are unpredictable.

Chaos: Kleenex Example Drop a Kleenex to the floor Drop a 2nd Kleenex, releasing it from the same spot Drop a 3rd Kleenex, releasing it from the same spot, etc. Repeat procedure…1,000,000 times if you like, even try moving closer to the floor Does a Kleenex ever land in the same place as a prior drop? Kleenex exhibits chaotic behavior!

Atmospheric Predictability The atmosphere is like a falling Kleenex! The uncertainty in the initial conditions grow during the evolution of a weather forecast. So a point forecast made for a long time will ultimately be worthless, no better than a guess! There is a limited amount of predictability, but only for a short period of time. Loss of predictability is an attribute of nature. It is not an artifact of computer models.

Limits of Predictability What determines the limits of predictability for the atmosphere? Limits dependent on many factors such as: Flow regime Geographic location Spatial scale of disturbance Weather element

Sensitivity to Initial Conditions DAY 3 FORECAST POSITIVE DAY 3 FORECAST NEGATIVE DAY 3 FORECAST UNPERTURBED VERIFYING ANALYSIS

Summary: Key Concepts Forecasts are needed by many users There are several types of forecasts Numerical Weather Prediction (NWP) Use computer models to forecast weather -Analysis Phase -Prediction Phase -Post-Processing Phase Humans modify computer forecasts

Summary: Key Concepts National Center for Environment Prediction (NCEP) issues operational forecasts for El Nino tropical SST anomalies Seasonal outlooks 10 to 15 day weather forecasts 2 to 3 day fine scale forecasts

Summary: Key Concepts NCEP issues forecasts out to a season. Human forecasters improve NWP forecasts. NWP forecast go awry for several reasons: measurement and analysis errors insufficient model resolution incomplete understanding of physics chaotic behavior and predictability Chaos always limits forecast skill.

Assignment for Next Lecture Topic - Thunderstorms Reading - Ahrens pg 257-271 Problems - 10.1, 3, 4, 5, 6, 7, 16