Download Isoplething Connecting equal values of a particular meteorological

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
Document related concepts
no text concepts found
Transcript 
1
Isoplething
Connecting equal values of a particular meteorological variable. An example for isotherms is
shown below.
Drawing isopleths for isobars or contours (lines of constant geopotential height) is somewhat
similar. An example for you to complete as a homework assignment is shown on the next page.
Draw the isobars every 4 mb (i.e., 1000, 996, 992. etc.).
Drawing isobars or contours is different than drawing other scalar fields since you MUST TAKE
THE WINDFIELD INTO ACCOUNT. At the 500 mb level, the contours or isobars are drawn
approximately parallel to the wind direction since the flow is close to being geostrophic. This is
not as stringent at other levels. Closer to the surface, the flow has a component of flow toward
low pressures due to friction. At higher levels near the jet stream, the flow is accelerating and
decelerating so it also deviates from geostrophy (recall the geostrophic flow is non-accelerating
flow).
2
3
Analysis of charts
How to read Upper-level Charts
4
What is Geopotential Height?
z
1
gdz
9.8ms−2 ∫0
dp
pg
hydrostatic equation =
= − ρg =
dz
Rd Tv
Rd
dp
Z=
Tv
−2 ∫
9.8ms
p
The
geopotential
height = Z =
above equation for geopotential height can
be easily calculated if you have data from a
radiosonde (i.e., data that provides information
of temperature and pressure with height).
\
c
ht is a onstant
g
i
he
Pole
Eq
al height is
nti
a
te
t
tan
ns
co
Earth
ge
op
o
5
250 mb
025
-50
250 mb
250 mb
025
+01
-50
aircraft
500 mb
-15
air temp°C)
(
dew point
depression (°C)
7
545
+02
025
-50
satellite
700 mb
00
9
034
+02
850 mb
10
14
geopotential
height
451
+02
Height tendency
(past 12 h)
250 mb -
Contours drawn in solid black lines every 120 gpm (geopotential meters; start
with 10560 gpm).
Isotherms drawn as dashed red lines every 5oC.
Isotachs drawn as purple lines every 20 kts (start at 50 kts). Cross-hatch for
regions 70 kt or greater. Please refer to current charts for an example.
500 mb -
Contours drawn in solid black lines every 60 gpm (geopotential meters; start with
5760 gpm).
Isotherms drawn as dashed red lines every 5oC.
700 mb -
Contours drawn in solid black lines every 30 gpm (geopotential meters; start with
3000 gpm).
Isotherms drawn as dashed red lines every 5oC.
850 mb -
Contours drawn in solid black lines every 30 gpm (geopotential meters; start with
1500 gpm).
Isotherms drawn as dashed red lines every 2oC.
NOTE: GPM are plotted in meters below the 500 mb level. They are plotted in decameters at
500 mb and aloft.
6
Surface Charts
Draw isobars in black pencil at 4 mb intervals (start with 1016 mb for example).
High (H) and Low (L) pressure centers should be marked in blue and red pencil, respectively.
Use the following colors for these weather features:
Cold fronts are blue
Warm fronts are red
Stationary fronts are alternating blue/red
Occluded fronts are purple
Squall lines are blue
Surface troughs (TROF" on NCEP surface analyses) are orange
Shade in green regions where precipitation is reported.
FRONTS
cold air
warm air
The front is located at the leading edge of the intense gradient in temperature. Dew point temperatures can also be useful. Dew points are generally lower in cold air than they are in warm
air. Accordingly, there should be a drop in dew point temperature across the front.
7
Fronts develop in pressure troughs. The winds will shift cyclonically as you cross the front from
the cold air to the warm air side. As a result, wind shifts are also a good indicator of the frontal
location. Other indicators are precipitation and pressure tendency.
Finding troughs and ridges.
L
1
2
3
H
A
C
B
8
9
What is the wind direction? Can you tell what kind of front this is?
Cold front
10
Warm front
11
NOTE: That there is a frontal inversion for both the cold and warm fronts----frontal zones are
statically stable. This can be a confusing concept since fronts are associated with precipitating
weather as the moist air is forced up the front; however, the front itself is a stable region.
Current Weather Depiction
Clear < 1/10, Scattered - 1/10-5/10, Broken - 6/10-9/10, Overcast>9/10.
12
Sky cover - overcast, temperature - 56oF, dew point - 54oF, wind from the southwest at 20 kts,
sea-level pressure is 997.8 mb (having fallen 0.8 mb in the last 3 hours), visibility is 3 miles in
light continuous drizzle, and there has been rain in the last 6 hours.
13
Evolving fronts within a life cycle of the extratropical cyclone.
14
15
Related documents
Chapter 21 Review - The Summer Science Safari Summer Camp
Chapter 21 Review - The Summer Science Safari Summer Camp
Lecture 5 (10/01) METR 1111
Lecture 5 (10/01) METR 1111
Meteorology Name Period _____ Ch. 9 pages 262
Meteorology Name Period _____ Ch. 9 pages 262
Chapter 16 Weather Maps and Isotherms/Isobars Lab
Chapter 16 Weather Maps and Isotherms/Isobars Lab
metIstudyguide_S16
metIstudyguide_S16
Fronts /Pressure Systems
Fronts /Pressure Systems
INTRODUCTION TO EARTH SCIENCE (ESCI 121) SAMPLE
INTRODUCTION TO EARTH SCIENCE (ESCI 121) SAMPLE
Name: Date: ______ Period: _____TOC # _____ Fronts and Air
Name: Date: ______ Period: _____TOC # _____ Fronts and Air
How To Read A Weather Map
How To Read A Weather Map
Weather Station Symbols
Weather Station Symbols
Understanding Weather Maps - University of Alaska Fairbanks
Understanding Weather Maps - University of Alaska Fairbanks
Model RA-28 - AirDelights.com
Model RA-28 - AirDelights.com
Commander Fleet Dispenser
Commander Fleet Dispenser
SEISCO ELECTRIC TANKLESS WATER HEATERS
SEISCO ELECTRIC TANKLESS WATER HEATERS