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Introduction
Weather systems
Fronts
Relationship between isobars and
wind
Understanding station plots
on a weather map
Plotting a station plot
Weather charts consist of curved lines drawn on a
geographical map in such a way as to indicate weather
features. These features are best shown by charts
of atmospheric pressure, which consist of isobars
(lines of equal pressure) drawn around depressions
(or lows) and anticyclones (or highs). Other features
on a weather chart are fronts and troughs. These are
drawn to highlight the areas of most significant weather,
but that does not mean that there is nothing of significance
elsewhere on the chart.
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High pressure or anticyclones
Anticyclones are areas of high pressure, whose
centres are often less well defined than depressions,
and are associated with quiet, settled weather.
Winds blow in a clockwise direction around anticyclones
in the northern hemisphere, this is reversed
in the southern hemisphere.
Fig 1: An anticyclone
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Low pressure or depressions
Depressions are areas of low pressure, usually
with a well-defined centre, and are associated
with unsettled weather. Winds blow in an anticlockwise
direction around depressions in the northern
hemisphere, this is reversed in the southern
hemisphere.
Fig 2: A depression
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Early weather charts consisted simply of station
plots and isobars, with the weather being written
as comments, like 'Rain, heavy at times'. During the
1920's, a group of Scandinavian meteorologists, known
collectively as the Bergen School, developed the concept
of representing the atmosphere in terms of air masses.
Since the air masses could be considered as being
in conflict with each other, the term 'front' was
used to describe the boundary between them. Three
types of front were identified which depend on the
relative movement of the air masses.
Cold Front
A cold front marks the leading edge of an advancing
cold air mass. On a synoptic chart a cold front appear
as a blue line with triangles. The direction in which
the triangles point is the direction in which the
front is moving.
Warm Front
A warm front marks the leading edge of an advancing
warm air mass. On a synoptic chart a warm front appears
as a red line with semi-circles. The direction in
which the semi-circles point is the direction in which
the front is moving.
Occlusion (or occluded front)
Occlusions form when the cold front of a depression
catches up with the warm front, lifting the warm air
between the fronts into a narrow wedge above the surface.
On a synoptic chart an occluded front appears as a
purple line with a combination of triangles and semi-circles.
The direction in which the symbols point is the direction
in which the front is moving.
Troughs
Fronts describe thermal characteristics. They also
happen to be where there is significant precipitation.
However, precipitation is not confined to fronts.
Drizzle in warm sectors or showers in cold air occur
fairly randomly, but occasionally, lines of more organized
precipitation can develop. These are called troughs.
Isobars
Isobars are lines joining places with equal mean
sea-level pressures (MSLP).
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| Fig 3: Identification of weather systems,
isobars and front |
Weather systems and fronts
| Relationship
between isobars and wind |
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Fig 4: Relationship between isobars and
wind speed |
Wind is a significant feature of the weather (see
Figure 4). A fine, sunny day with light winds can
be very pleasant.
Stronger winds can become inconvenient and, in extreme
cases, winds can be powerful enough to cause widespread
destruction. The wind can easily be assessed when
looking at a weather map by remembering that:
- closer isobars mean stronger winds;
- the wind blows almost parallel to the isobars;
- in the northern hemisphere, the wind blows round
a depression in an anticlockwise direction and around
an anticyclone in a clockwise direction. In the
southern hemisphere, the opposite is true;
- winds around anticyclones can sometimes be even
stronger than indicated by the isobars;
- in warm air, the wind is relatively steady and
tends to blow at about two-thirds the speed that
the chart would suggest, though there are exceptions
to this ;
- in cold air, the wind is usually as strong as
indicated by the isobars and can be very gusty.
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station plots on a weather map |
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Good quality observations are one of the basic
'tools of the trade' for a weather forecaster.
The weather conditions at each individual
station can be represented on a surface chart
by means of station plot.
This means that information which would take
up a lot of space if written on to a chart can
be displayed in a quick easy to understand format.
Figure 5 shows an example of a plotted chart.
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| Fig 5: An example of a plotted
chart |
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The land station plot can represent all the elements
reported from that station, these typically include:
- Air temperature
- Dewpoint temperature
- Wind speed
- Wind direction
- Visibility
- Atmospheric pressure and three-hour tendency
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- Cloud amounts
- Cloud types
- Cloud heights
- Present weather
- Past weather
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Traditionally station plots for manned observing
sites were based around a central station circle.
However increasingly, automatic weather observations
are replacing these and being plotted on weather charts.
To differentiate between the two, automatic observations
are plotted around a station triangle. Each element
of the observation, with the exception of wind, is
plotted in a fixed position around the station circle
or triangle so that individual elements can be easily
identified.
Fig 6: Plotting positions on a station
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Fig 7: A typical coded manual observation
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Fig 8: A typical coded automatic observation |
Total cloud amount
The total amount of the sky covered by cloud is expressed
in oktas (eighths) and is plotted within the station
circle for manned observations or station triangle
for automatic stations, by the amount of shading.
The symbols used for both manual and automatic observations
are shown below.
Wind speed and direction
The surface wind direction is indicated on the station
plot by an arrow flying with the wind. Direction is
measured in degrees from true North. Therefore a wind
direction of 180 is blowing from the south. The wind
speed is given by the number of 'feathers' on the
arrow. Half feathers represent 5 knots whilst whole
feathers indicate 10 knots. A wind speed of 50 knots
is indicated by a triangle. Combinations of these
can be used to report wind speed to the nearest 5
knots. The symbols used are as follows.
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| Fig 11: Symbols for wind speed |
Air temperature
Air temperature is plotted to the nearest whole degree
Celsius, i.e. 23 would indicate 23 degrees Celsius.
Dew point temperature
Dew point temperature is plotted to the nearest whole
degree Celsius, i.e. 18 would indicate a dew point
of 18 degrees Celsius.
Pressure
Pressure is recorded in millibars and tenths and
the last three digits are plotted. Therefore 1003.1
would be plotted as 031 and 987.1 would be plotted
as 871.
Present weather
In total the Met Office has 100 codes for recording
the current weather at the time of the observation.
Different types of weather are represented using different
weather symbols, a key to which can be found below.
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| Fig 12: Symbols for present weather |
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| Fig 13: Symbols for present weather |
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| Fig 14: Symbols for present weather |
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| Fig 15: Symbols for present weather |
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| Fig 16: Symbols for present weather |
Past weather
A simplified version of the present weather plots
is used to indicate past weather.
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| Fig 17: Symbols for past weather |
Pressure Tendency
Pressure trend shows how the pressure has changed
during the past three hours i.e rising or falling,
and pressure tendency shows by how much it has changed.
The tendency is given in tenths of a millibar, therefore
'20' would indicate a change of two millibars in the
last three hours. Pressure tendency is indicated by
the following symbols:
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| Fig 18: Symbols for pressure tendency |
Visibility
Visibility, which is how far we can see, is given
in coded format, in either meters or kilometres. Visibilities
below five kilometres are recorded to the nearest
100 metres, whilst those above five kilometres are
given to the nearest kilometre.
For visibilities equal to and less than five km:
Table 1: Codes
for visibilities of less than five km
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Code
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Distance in km
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Code
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Distance in km
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Code
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Distance in km
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00
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<0.0
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19
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1.9
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38
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3.8
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01
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0.1
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20
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2.0
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39
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3.9
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02
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0.2
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21
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2.1
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40
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4.0
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03
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0.3
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22
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2.2
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41
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4.1
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04
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0.4
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23
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2.3
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42
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4.2
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05
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0.5
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24
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2.4
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43
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4.3
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06
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0.6
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25
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2.5
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44
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4.4
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07
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0.7
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26
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2.6
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45
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4.5
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08
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0.8
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27
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2.7
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46
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4.6
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09
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0.9
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28
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2.8
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47
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4.7
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10
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1.0
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29
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2.9
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48
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4.8
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11
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1.1
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30
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3.0
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49
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4.9
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12
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1.2
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31
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3.1
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50
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5.0
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13
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1.3
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32
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3.2
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51
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Not Used
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14
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1.4
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33
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3.3
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52
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Not Used
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15
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1.5
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34
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3.4
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53
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Not Used
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16
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1.6
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35
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3.5
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54
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Not Used
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17
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1.7
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36
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3.6
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18
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1.8
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37
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3.7
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For visibilities greater than five km:
Table 2: Codes
for visibilities of more than five km
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Code
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Distance in km
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Code
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Distance in km
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56
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6
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73
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23
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57
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7
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74
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24
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58
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8
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75
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25
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59
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9
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76
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26
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60
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10
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77
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27
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61
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11
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78
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28
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62
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12
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79
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29
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63
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13
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80
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30
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64
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14
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81
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35
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65
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15
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82
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40
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66
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16
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83
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45
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67
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17
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84
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50
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68
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18
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85
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55
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69
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19
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86
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60
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70
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20
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87
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65
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71
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21
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88
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70
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72
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22
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89
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>70
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Low cloud type
The type of low cloud present is provided in coded
format, using the symbols below.
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| Fig 19: Symbols for low cloud type |
Medium cloud type
The type of medium cloud present is provided in coded
format, using the symbols below.
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| Fig 20: Symbols for medium cloud type |
High cloud type
The type of high cloud present is provided in coded
format, using the symbols below.
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| Fig 21: symbols for high cloud type |
Cloud height
Cloud heights are measured in hundreds or thousands
of feet. The way these are plotted varies depending
on whether the station is an automatic or manned observing
site.
For automatic stations, indicated by a station triangle,
the following codes are used.
Table 3: Cloud
heights for automatic stations
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Code
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Height in feet
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00
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<100
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05
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500
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10
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1000
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15
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1500
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20
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2000
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...
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...
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50
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5000
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60
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6000
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For manned stations, indicated by a station circle,
the following codes are used.
Table 4: Cloud
heights for manned stations
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Code
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Height in feet
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0
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0-149
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1
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150-299
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2
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300 - 599
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3
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600 - 999
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4
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1,000 - 1,999
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5
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2,000 - 2,999
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6
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3,000 - 4,999
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7
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5,000 - 6,499
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8
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6,500 - 7,999
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9
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8,000 - or above
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Cloud height unknown
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Gust Speed
Gust speeds are measured in knots and proceeded by
the letter G. Gust speeds are normally only recorded
if they exceed 25 knots and are plotted as whole knots
i.e. G35 indicates a gust of 35 knots.
Example
The decode of this station plot is as follows:
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Type of observation:
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Manned |
Fig 22: Example plot
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Total cloud amount:
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8 oktas |
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Wind Speed:
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28-32 knots |
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Wind direction:
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South-westerly |
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Air temperature:
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23 degrees Celsius |
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Dew point temperature:
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18 degrees Celsius |
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Pressure:
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1004.2 millibars |
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Present weather:
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Continuous moderate rain |
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Past weather:
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Rain |
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Pressure tendency:
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Falling 0.5 millibars in the past
three hours |
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Visibility:
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6km |
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Low cloud type:
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Stratus |
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Low cloud amount:
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6 oktas |
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Low cloud height:
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1000 feet |
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Medium cloud type:
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Altostratus |
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High cloud type:
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Cirrus |
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Gust speed:
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45 knots |
Exercise
Why not try decoding the following observational
plots.
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