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Surface Weather Map a. k. a: Surface Synoptic Chart Surface Weather Map a. k. a: Surface Synoptic Chart

Available here: http: //www. atmos. washington. edu/data/vmaproom/ Available here: http: //www. atmos. washington. edu/data/vmaproom/

Why Surface Weather Maps? • Summarizes weather conditions at the surface (where we are!) Why Surface Weather Maps? • Summarizes weather conditions at the surface (where we are!) • Using a progression of charts can see how weather is evolving. • Summarizes our conceptional model of the atmosphere (fronts).

First Surface Weather Map • Perhaps the first surface weather map was created by First Surface Weather Map • Perhaps the first surface weather map was created by H. W. Brandes in 1820 for March 6, 1783. • The arrows indicate wind direction and the lines show the deviation of pressure from average conditions

• One of the weather maps created by Elias Loomis in his groundbreaking • One of the weather maps created by Elias Loomis in his groundbreaking paper on the storms of February 1842. Surface wind direction is indicated by arrows and the deviations from average pressure are shown by the dashed lines. Temperatures are indicated by dotted lines and the sky or precipitation type by the color shading. This map indicates a strong lowpressure center over the Ohio Valley, rain on the coast, and snow-laden northwesterly winds to the west.

The Telegraphic Communication Revolution • By 1849 a telegraphic network was organized in the The Telegraphic Communication Revolution • By 1849 a telegraphic network was organized in the United States for the transmission of daily meteorological observations for a collection of stations. • In England during the l 851 World's Fair, a telegraphic company prepared daily weather maps for display, and by 1859 the British Meteorological Department began to operationally distribute weather information using this new technology. The internet of the 19 th century

First Real-Time Weather Maps First Real-Time Weather Maps

Fronts • The Norwegian Cyclone Model, around 1920 Fronts • The Norwegian Cyclone Model, around 1920

Fronts • Regions of enhanced temperature changes and major weather (clouds and precipitation) Fronts • Regions of enhanced temperature changes and major weather (clouds and precipitation)

1950 Surface Weather Map 1950 Surface Weather Map

Still Used Today Still Used Today

What is on surface charts? • Station models: meteorological shorthand describing the observations at What is on surface charts? • Station models: meteorological shorthand describing the observations at locations • Isobars (lines of constant sea level pressure) • Fronts and troughs (locations of low pressure)

Surface Observations are plotted using the station model Surface Observations are plotted using the station model

Station Model • In the U. S. , the station model uses temperatures in Station Model • In the U. S. , the station model uses temperatures in F; other countries used C • Sea level pressure. 3 digits in tenths of a h. Pa (mb). • Divide by 10 and add either 9 or 10. • 237 > 23. 7>1023. 7 h. Pa • When choosing between 9 and 10, use the one that gives one a reasonable pressure (hint: average SLP is around 1000 h. Pa)

Practice • 198 is 1019. 8 h. Pa, not 919. 8 h. Pa • Practice • 198 is 1019. 8 h. Pa, not 919. 8 h. Pa • 745 is 974. 5 h. Pa, not 1074. 5 h. Pa • 247 is 1024. 7 h. Pa, not 924. 7 h. Pa

Pressure Change over the Past 3 hr • Surface pressure change in tenths of Pressure Change over the Past 3 hr • Surface pressure change in tenths of h. Pa • Over past 3 hr. • 3 means pressure increase of. 3 h. Pa in last 3 hr. • Cartoon next to it.

Current Weather Current Weather

Sky Coverage Sky Coverage

Sky Obscured…you are in cloud Sky Obscured…you are in cloud

Wind Pennants Wind Pennants

Wind Speed Wind Speed

You need to be able to read the station models You need to be able to read the station models

What kind of observations are plotted on surface charts? What kind of observations are plotted on surface charts?

ASOS: Automated Surface Observing System: Backbone Observing System in the U. S. ASOS: Automated Surface Observing System: Backbone Observing System in the U. S.

Hydrothermograph Hydrothermograph

Precipitation Gauges Precipitation Gauges

Laser Weather Identifier Laser Weather Identifier

Anemometer Wind Vane Laser Ceilometer Anemometer Wind Vane Laser Ceilometer

The ASOS Freezing Rain Sensor uses an ultrasonically vibrating probe to detect the presence The ASOS Freezing Rain Sensor uses an ultrasonically vibrating probe to detect the presence of icing conditions. The vibrating frequency of the probe decreases with the accumulation of ice.

Lightning Sensor Visibility Sensor Lightning Sensor Visibility Sensor

Full ASOS system in Arizona Full ASOS system in Arizona

Marine Reports Marine Reports

Ocean and Lake Weather Buoys Anchored Ocean and Lake Weather Buoys Anchored

Drifting Buoys Wind Pressure Drifting Buoys Wind Pressure

Coastal Marine (CMAN) Reports from the Coast Guard Coastal Marine (CMAN) Reports from the Coast Guard

Northwest Buoy and CMAN Locations Northwest Buoy and CMAN Locations

Ship Reports: Marine VOS Program Volunteers Observers--generally 6 -hourly reports Highly variable quality and Ship Reports: Marine VOS Program Volunteers Observers--generally 6 -hourly reports Highly variable quality and frequency

Isobars of sea level pressure are found on station map • Isobars are lines Isobars of sea level pressure are found on station map • Isobars are lines of constant or equal pressure • Everywhere along each line the pressure is the same • Labeled in h. Pa/mb (e. g. , 996, 1000, 1004, etc)

Why use sea level pressure rather than station pressure—the pressure at the elevation of Why use sea level pressure rather than station pressure—the pressure at the elevation of the barometer? • Because pressure decreases with height! • The pressure variations on weather maps would be dominated by terrain changes.

H L L H L L

Terrain effects on pressure would swamp the meteorological signal • So why not take Terrain effects on pressure would swamp the meteorological signal • So why not take the terrain effects of pressure out? • Adjust the station (surface) pressures to get the pressure at a standard level: sea level. • Called pressure reduction to sea level. • For example, near sea level, pressure drops about 1 h. Pa for every 8 meters in elevation.

Example of Pressure Reduction * 1024 h. Pa 64 m Sea Level * 1032 Example of Pressure Reduction * 1024 h. Pa 64 m Sea Level * 1032 h. Pa

Pressure Reduction • In reality, done in a more sophisticated way, but still somewhat Pressure Reduction • In reality, done in a more sophisticated way, but still somewhat artificial • Particular problems for high elevation stations • Sea level pressure is found at all major observing locations and plotted in the station models. • But how make SL pressure maps?

Technique called isoplething Isobars generally drawn every 4 h. Pa (e. g. 1000, 1004) Technique called isoplething Isobars generally drawn every 4 h. Pa (e. g. 1000, 1004)

Once the analysis is done, put on H’s and L’s • High- “H” -high Once the analysis is done, put on H’s and L’s • High- “H” -high sea level pressure relative to the surroundings. Also known as a ridge. Generally associated with fair weather. • Low- “L” - low sea level pressure relative to the surroundings. Also known as a trough. Generally associated with cloudy, stormy weather.

Pressure patterns are also very important because they influence winds • Strong winds are Pressure patterns are also very important because they influence winds • Strong winds are generally associated with strong horizontal pressure gradients, where pressure changes rapidly with distance. • Weak wind with weak strong pressure gradients weak

Winds and pressure • Near terrain winds tend to go directly from high to Winds and pressure • Near terrain winds tend to go directly from high to low pressure • Away from terrain, winds tend to parallel isobars, with a small angle towards lower pressure

Will explain why in a few weeks L Surface wind H Will explain why in a few weeks L Surface wind H

In the northern hemisphere winds tend to blow countclockwise around lows and clockwise around In the northern hemisphere winds tend to blow countclockwise around lows and clockwise around highs (opposite in the southern hemisphere)

Other features on surface charts Other features on surface charts

What are fronts? • The tropics are warmer than the Arctic/Antarctic regions. • But What are fronts? • The tropics are warmer than the Arctic/Antarctic regions. • But temperatures don’t change gradually between north and south. • There are regions of large horizontal temperature changes, which are known as fronts. • Frontal boundaries are generally located on the warm side of the zone of temperature change.

Definition A front is a boundary between air of relatively uniform warm air and Definition A front is a boundary between air of relatively uniform warm air and a zone in which temperatures cools rapidly

Front 51 52 53 54 58 65 67 relatively uniform cool air 68 68 Front 51 52 53 54 58 65 67 relatively uniform cool air 68 68 Frontal Zone relatively uniform warm air

Four Main Types of Fronts Four Main Types of Fronts

Warm Front Warm Front

Stationary Fronts Stationary Fronts

Occluded Front (a hybrid) Occluded Front (a hybrid)

Fronts and Pressure Fronts and Pressure

Fronts are associated with bands of clouds Fronts are associated with bands of clouds