Section 8.1.10 Types of Precipitation - charts and diagrams

Types of Precipitation - charts and diagrams

It is important to assess the likelihood of different types of precipitation, particularly those of a hazardous nature.  The method of assessment of the type of surface precipitation by the IFS models depends critically upon the temperature structure of the model atmosphere, which includes the layers through which the model precipitation falls.   But modelling of this can be difficult, especially if the structure of the model atmosphere is imprecisely defined.  

The ecCharts products incorporate some post-processing related to the minimum permissible precipitation rate, which varies according to type, and which has been incorporated to try to deliver relatively "bias-free" products for the user.  In tests this helped greatly to minimise net under- or over-prediction of the occurrence of the different types of precipitation.  This aspect is not discussed directly in this user guide, but more information can be found in the Additional Sources of Information links for this section. 

Rain at the surface can sometimes change to snow perhaps because of evaporative cooling of the airmass as the precipitation falls.     The ensemble gives an effective way of assessing possible variations in the temperature and humidity structure of the lower troposphere and hence the probabilities of the types of precipitation that may occur.  Probabilities are naturally assigned according to the distribution of types of precipitation among the ensemble members.  Even a small probability of hazards such as heavy snowfall or, more especially, freezing rain/drizzle can be useful information for the forecaster and ultimately for the customer, even at quite short lead-times.  

ECMWF products currently available in ecCharts aim to help with these forecasting challenges in different ways.  One can examine charts that relate to the instantaneous type of precipitation, and its instantaneous intensity (in map and meteogram/histogram formats), and also to maps that display accumulations of a certain type of precipitation over a period, or probabilities thereof.

There are a number of additional useful options related to different types of precipitation in ecCharts which are not directly discussed in this section, but which the user should be aware of; notably:

• total snowfall probability,
• total snowfall rate probability,
• probability of combined events of wind gust and total snowfall.

Freezing precipitation

A major weather hazard is freezing precipitation (freezing rain and freezing drizzle) which requires a particular and relatively rare type of temperature and humidity structure in the vertical.  It is important to appreciate that diagnosis of freezing rain or freezing drizzle in IFS takes no account of the temperature of the surface, only on the temperature structure of the boundary layers.  IFS indication of freezing rain/drizzle indicates only that super-cooled droplets are likely to exist in the boundary layer but gives no guidance upon the likely formation of glaze or glazed ice on exposed surfaces.  Nevertheless, the forecast rate of precipitation does give some indication of the amount of ice accretion that may be expected.  The user should consider:

• the kind of surface in question and its probable temperature before assessing the result of any indicated freezing precipitation.  
• the various physical effects of precipitation types when deposited on surfaces and the way IFS handles them.

Histograms of Types of Precipitation

HRES/Ensemble Control gives no information on the probability of a type of precipitation and should not be used on its own;  reference should always be made to ensemble output, particularly by use of the histogram, to assess the probability of other types of precipitation.  Histograms of the ensemble "Types of Precipitation" are available as an option on ecCharts and on Opencharts.   This gives easy to use information about the probability of alternative types of precipitation from the results of all ensemble members.   

Fig8.1.10-1:  Method to display histograms of probability of types of precipitation from ecCharts.  The location of the histogram may be selected using the probe tool on the chart.

Instantaneous, single member HRES/Ensemble control

A layer is available on ecCharts to show the type of precipitation for precipitation rates greater than 0.1mm/hr.  The precipitation types are shown by colouration.

These types of precipitation charts give no information on probability of the type of precipitation shown, or on the probability of any alternative precipitation types.

It is important to assess the temperature structure of the lower layers of the atmosphere to enable a tentative probability, or at least the risk, of potential severe weather types.

Fig8.1.10-2 ecChart forecast chart showing HRES forecast of instantaneous type of precipitation forecast DT 00UTC 20 January 2018, T+60 VT 12UTC 22 January 2018.  A type of precipitation is shown wherever the forecast rate of precipitation is greater than 0.1mm/hr.  The types of precipitation are represented by colours: Green-Rain, Red-Freezing Rain, Blue-Snow, Dark Blue-Wet Snow, Cyan-Sleet, Orange-Ice Pellets.

At Straubing, Lower Bavaria (shown by the pin) if the precipitation area is moving eastwards then the initial snow will probably turn to freezing rain followed by rain.   However, this type of precipitation chart give no information on probability of the type of precipitation shown at the given time nor on any alternative types of precipitation.

Fig8.1.10-3:  ecChart forecast chart showing HRES/Ensemble Control forecast of instantaneous type of precipitation forecast DT 00UTC 20 February 2018, T+36 VT 12UTC 21 February 2018.  A type of precipitation is shown wherever the forecast rate of precipitation is greater than 0.1mm/hr.  The types of precipitation are represented by colours: Green-Rain, Red-Freezing Rain, Blue-Snow, Dark Blue-Wet Snow, Cyan-Sleet, Orange-Ice Pellets.  The type of precipitation is also given in the "probe" information (top of diagram) according to a code - in this case for Quebec City (shown by the pin), 3 represents freezing rain at this time.  

The forecast shown on "'Precipitation Type" charts is based on HRES/Ensemble Control alone and is different to guidance from the ensemble.  The HRES/Ensemble Control (unperturbed) member of the ensemble may or may not be similar to all, or even any, of the other ensemble member solutions.  It gives no information on the probability of a type of precipitation and should not be used on its own.  Reference should always be made to ensemble output to assess the probability of other types of precipitation.

An indication of freezing precipitation gives no information of likely accumulation of glazed ice although there must be a serious risk, and heavier precipitation rates suggest a potential  for greater accumulation.

Instantaneous most probable type of precipitation

A more informative ecChart display of instantaneous type of precipitation is based upon ensemble output and shows the most probable type of precipitation but gives no information on any, possibly hazardous, precipitation having a lower probability.   Such information can be obtained by reference to the instantaneous type of precipitation meteogram/histogram product.

Fig8.1.10-4: ecChart forecast chart showing HRES/Ensemble Control forecast of instantaneous type of precipitation forecast DT 00UTC 20 January 2018, T+60 VT 12UTC 22 January 2018 (Same ecChart as Fig8.1.10-2).  A type of precipitation is shown wherever the forecast rate of precipitation is greater than 0.1mm/hr.  The types of precipitation are represented by colours: Green-Rain, Red-Freezing Rain, Blue-Snow, Dark Blue-Wet Snow, Cyan-Sleet, Orange-Ice Pellets.  Areas where precipitation rates are less than 0.1 are coloured grey.  

The histogram shows the distribution among ensemble members of types of precipitation at Quebec City (pin shows location) at 09UTC 21 February 2018. 

The ensemble chart that at Straubing at 12UTC 22 January 2018 several possibilities of types of precipitation are forecast by the ensemble members: ~26% rain (of which ~4% light, ~10% moderate, ~12% heavy intensity), ~2% sleet, ~2% wet snow, ~14% Snow (varying intensities), ~18% ice pellets (varying intensities), ~34% freezing rain (of which 4% light, ~20% moderate, 10% heavy intensity), ~6% no precipitation.  The histogram for Straubing shows the greatest probability (34%) is for freezing rain (shown as red on the "Most Probable Type of Precipitation" chart based on the ensemble).  But the probability of rain is 26% and probability of snow 14% (shown as blue on the "Type of Precipitation" chart based on HRES/Ensemble Control).

Fig8.1.10-5:  ecChart forecast chart showing ensemble forecast of instantaneous type of precipitation forecast DT 00UTC 20 February 2018, T+36 VT 12UTC 21 February 2018.  A type of precipitation is shown wherever the forecast rate of precipitation is greater than 0.1mm/hr.  The types of precipitation are represented by colours: Green-Rain, Red-Freezing Rain, Blue-Snow, Dark Blue-Wet Snow, Cyan-Sleet, Orange-Ice Pellets with shades graded according to the scale above the chart.  Areas where precipitation rates are less than 0.1 are coloured grey.

The histogram shows the distribution among ensemble members of types of precipitation at Quebec City (pin shows location) at 09UTC 21 February 2018. 

The ensemble chart shows the area of freezing rain lies to the northeast of Quebec at this time and the most probable type of precipitation at Quebec is rain.  The histogram for Quebec shows the probability of freezing rain overnight was very high but that the risk has greatly reduced by 09UTC.  However, the probability of freezing rain at 09UTC is still about 21% - heavy (dark red) 8%, moderate (red) 10% – so a risk of occurrence of a potentially dangerous phenomenon persists.  

It is important to note:

• The "Precipitation Type" chart is based on forecast results from HRES/Ensemble Control.  
• The "Probability of Type of Precipitation" chart is based on forecast results from the ensemble members.  It only shows the most probable type.  Other precipitation types even if only a little less probable are not shown.
• Histograms show the probabilities of all precipitation types including potentially hazardous precipitation, even at low probabilities. 

In the German example above, the "Precipitation Type" chart showed snow.  The "Probability of Type of Precipitation" chart showed the highest probability was for freezing rain.  The histogram showed a probability of rain higher than that for snow.

In the Canadian example above, the "Precipitation Type" chart indicated that the risk of freezing precipitation had moved away from Quebec.  The "Probability of Type of Precipitation" chart also showed the highest probability was for rain.  But the histogram showed the risk (some 21%) for freezing precipitation persisted through the morning. 

Users should inspect the histogram of precipitation types and not rely only on the "Precipitation Types" charts or "Probability of Precipitation Type" charts alone.  They give no information on any alternative types of precipitation.  The histogram shows probabilities of each type of precipitation measured as the proportion among the ensemble members of each type of precipitation forecast at the selected location. 

It is very important to capture occasions when hazardous precipitation is forecast with a lower probability.   This often occurs at longer lead-times.  Freezing rain is such a significant hazard that even a small probability might be worth a warning to customers sensitive to this type of precipitation even though rain or snow might be more probable and shown as such on the charts. 

The ensemble grid point altitude is displayed at the top of the meteogram.  Users should consider the impact of differences in altitude of the location of interest and the model grid point altitude. 

It should be remembered that an indication of freezing precipitation gives no information of likely accumulation of glazed ice although there must be a serious risk, and heavier precipitation rates suggest a potential  for greater accumulation.

Variation of probability with forecast time

The "Probability of Type of Precipitation" chart clearly shows the areas at greater risk for precipitation of any kind and also the areas where there is greater uncertainty.   However, the uncertainty also varies with forecast lead-time:

• At shorter lead-times the ensemble solutions will usually be fairly similar.  The probability of the types of precipitation are likely to be high.  Charts will show a lot of detail.
• As lead-time increases the spread of ensemble solutions will be greater.  The development, timing and location of precipitation events will become less certain.  Charts will show larger areas of grey (<50% probability of precipitation).

Fig8.1.10-6: Multiplots of ensemble probability of type of precipitation forecasts all verifying at 12UTC 21 February 2018 from a series of ensemble forecast runs at 24hr intervals.  As lead-time increases the more hazardous, less common types of precipitation are less prominent or do not appear, and greys (total probability <50%) are more prominent. 

However, IFS models is able to predict freezing rain several days in advance despite the finely balanced vertical thermodynamics structure required.

Fig8.1.10-7: Sequence of precipitation types DT:00UTC 04 March 2023.   VTs:00UTC 04 Mar (T+00) to 12UTC 06 Mar (T+60).  Precipitation type shown by colours.

Interpretation of colouring on charts

It is important to note that the colour scales on type of precipitation charts and the accompanying histograms indicate different things - they are not interchangeable. 

• The colours in the chart show the most probable type of precipitation
• The colours in the histogram show the probability of each intensity of precipitation at the chosen probe location.

Fig8.1.10-8: Opencharts Probabilities. Most probable precipitation type DT 00UTC 31 June 2023, VT 12UTC 01 July 2023.  To help users to have a better understanding of the situation, where the total precipitation probability is less than 50% the type of precipitation is not shown, but the total probability of the precipitation (between 10-30 or 30-50%) is shown by the shades of grey.  The histogram location is for the SE of Iceland and shown by the arrow.

Colours on the chart show:

• Colours show most probable precipitation types.
• Shading shows percentages of the most probable precipitation.

Colours on the Meteogram/Histogram show:

• Colours show precipitation types
• Shading shows precipitation rates (scale above histograms).

Further examples

Freezing rain is a very hazardous type of precipitation which brings a significant risk to aviation, transport, communication and indeed to life.  There are outputs to highlight the probability and amounts of freezing rain.  It should be remembered that an indication of freezing precipitation gives no information of likely accumulation of glazed ice although there must be a serious risk, and heavier precipitation rates suggest a potential for greater accumulation.

Fig8.1.10-9A: HRES forecasts freezing rain (total over 12hr).  DT 00UTC 23 February 2018, T+72 VT 00UTC 26 February 2018.  Colour scale: Light Blue 0.0-0.2mm, Mid Blue 0.2-0.5mm, Dark Blue 0.5-1.0mm, Dark Red 1.0-2.0mm, Red 2.0-5.0mm, Pink 5.0-10.0mm, Orange >10.0mm.  The pin marks the location of Quebec City with the forecast 12hr total of freezing rain given in the probe information frame.  Freezing rain total values are not the same as accumulation of glaze or glazed ice although some proportional accretion must be expected.

Fig8.1.10-9B: The ensemble forecasts freezing rain probability (>1mm over 12hr).  DT 00UTC 23 February 2018, T+72 VT 00UTC 26 February 2018.  Colour scale: Yellow 5-35%, Green 35-65%, Darker Green 65-95%, Blue >95%.  The pin marks the location of Quebec City with the forecast probability of >1mm 12hr total of freezing rain given in the probe information frame.

Fig:8.1.10-10: ecCharts presentation of HRES forecast freezing rain accumulations over the previous 6hr, DT 00UTC 16 February 2023, T+42 VT 18UTC 17 February 2023.  The vertical profile at Bangor, Maine, USA shows the classic freezing rain structure of a very moist and precipitating frontal zone overlying the sub-zero layer near the surface.

Modulation of Precipitation Type Probabilities by Sea Track and Topography

The following plots illustrate how the handling of precipitation type by ensemble forecasts in a marginal rain-snow situation can make physical sense; and specifically how user-relevant subtle changes are predicted with some precision.

Fig8.1.10-11: Illustration of the probabilities of different instantaneous precipitation types.  The flow is mainly easterly over England and illustrates the impact of different length sea tracks over the relatively warm sea, and the impact of topography.  Consider an approximate low level trajectory from Belgium to Wales (dashed arrow).  Colour is used wherever the probability of some precipitation falling is 50% (from the ensemble).  The colour itself illustrates the most likely type, whilst the darkness of the shading indicates how likely that type is.  Dry snow over Belgium, wet snow and sleet over the relatively warm southern North Sea, wet snow over colder southeastern England, dry snow further away from the sea (most likely as the air re-cools partly via evaporation), then over Welsh mountains the probability of dry snow is very high (because the high probability of temperatures being below zero and of high probability of precipitation falling due to orographically forced ascent).

Fig8.1.10-12: Typical histograms of probabilities of instantaneous precipitation type for locations within the airstream.  Colours in Fig8.1.10-11 represent the most likely (i.e. produced by the greatest percentage of ensemble members) but don't show other types, even if they are marginally less likely.  The use of histograms gives a better overview of precipitation types and enables a more confident forecast to be made by the user.  Considering 12UTC 31 Jan 2019: In Belgium there is high confidence of dry snow with very small probability of any alternative precipitation type.  

Sometimes the probabilities of two or more precipitation types may be very similar.  For example, the difference in probability between problem-causing wet snow and less hazardous sleet or rain may be small and it may be may be difficult to decide between them.  The charts of most probable precipitation type only show the precipitation type that has the greatest probability, no matter how small the probability is greater than the next most probable precipitation type.

Therefore it is wise to use histograms of precipitation type in conjunction with charts of most probable precipitation type to assess the most likely precipitation type and the probability of alternatives.  The histograms are readily available on ecCharts.

Freezing drizzle

Freezing drizzle can be as much of a hazard as freezing rain.  The "Probability of Freezing Rain" option on ecCharts can show 0% when the default threshold is used.  Freezing drizzle can be seen if a very low threshold (say >0.01mm in previous 6hr) is applied.

Fig:8.1.10-13 ecCharts presentation of ensemble forecast of probability of freezing rain accumulations, threshold 0.01 mm in previous 6 hr, DT 12UTC 24 January 2023, T+21 VT 09UTC 25 January 2023.  The vertical profile at Reading (located by the pin) shows a saturated layer of stratus at about 950 hPa with temperature above 0°C.  Very slight precipitation produced from the stratus by the model falls through an underlying sub-zero layer near the surface. The model gave above 65% probability of very light freezing precipitation.  Freezing drizzle was observed at Reading during the period.

Additional Sources of Information

(Note: In older material there may be references to issues that have subsequently been addressed)

• Read more information on the updates to ecCharts regarding type of precipitation products.
• Read more information on the verification of type of precipitation products.
• Read more on the probability of precipitation type products (from page 2).