1 / 38

METADATA TO DOCUMENT SURFACE OBSERVATION

METADATA TO DOCUMENT SURFACE OBSERVATION. Michel Leroy, Météo-France. METADATA. Metadata is necessary to use efficiently observed data. Latitude, longitude, altitude, station Id., date and time are obvious metadata.

symona
Download Presentation

METADATA TO DOCUMENT SURFACE OBSERVATION

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. METADATA TO DOCUMENT SURFACE OBSERVATION Michel Leroy, Météo-France

  2. METADATA • Metadata is necessary to use efficiently observed data. • Latitude, longitude, altitude, station Id., date and time are obvious metadata. • A detailed description of the site and the instruments used, their characteristics, the historic of any instrument and site change, etc. is highly recommended and wished by climatologists. But the way to document this information is not yet standardized, this information is often missing and when available, the information is not easy to use by automatic means, due to its complexity. • The site environment is one of the important factor affecting a field measurement and its representativeness for various applications. • Though quite well known by the meteorological services, WMO siting recommendations are not always followed in the real world (or cannot be followed). • It is the same thing for the measurement uncertainty when compared to recommended and achievable measurement uncertainty stated in WMO doc n°8 (CIMO Guide),

  3. Some “condensed” metadata • In order to document the site environment and the sustained characteristics of the measurement system in an easy to handle way, Météo-France has defined two classifications : • A siting classification, ranging from 1 to 5, for each basic parameter. • A “maintained performance” classification, ranging from A to E, for each basic measurement. • Reducing the site characteristics and the equipment’s performances to single numbers or letters hide many interesting details, but a major advantage is to let the results easy to use. And these single numbers don’t restrict an additional detailed documentation (such as photos). • The definition of these classifications is coming from an initial analysis of quality factors influencing a measurement

  4. Drawbacks • These classifications don’t allow any corrections of the data. They are not developed for that. • Especially for wind, may be for precipitation, some correction methods exist and could be applied. These methods need a detailed knowledge of the site environment and sometimes additional parameters. There would be a great interest in applying standardized methods to correct raw measurements using the available metadata of a site. But the set of metadata needed to apply corrections is not clearly defined or standardized (except for wind for the reduction of the measured wind to a “standard” wind at 10 meters with a roughness length of 0.03 m). It would be ideal to have them, but this approach may be impracticable in the real world. • The advantage of the proposed classification is its practicability in the real world, therefore adding a practicable value to the information.

  5. Quality factors of a measurement • The intrinsic characteristics of sensors or measurement methods • The maintenance and calibration needed to maintain the system in nominal conditions. • The site representativeness

  6. Site representativeness • Exposure rules from CIMO recommendations. • But not always followed and not always possible to follow, depending on the geographical situation. • In 1997, Météo-France defined a site classification for some basic surface variables. • Class 1 is for a site following WMO recommendations • Class 5 is for a site which should be absolutely avoided for large scale or meso-scale applications. • Class 2, 3 and 4 are intermediate • This classification has been presented during TECO98 in Casablanca.

  7. Classification for wind measurements • Roughness classification : Davenport, see CIMO Guide, WMO Doc n°8 • Siting classification • The existence of obstacles nearly always lead to a decrease of the mean wind speed. Extreme values are generally also decreased, but not always. Obstacles increase turbulence and may lead to (random) temporary increase of instantaneous wind speed. • The following classes are considering a conventional 10 m measurement.

  8. Class 1 • -The wind tower must be erected at a distance of at least 10 times the height of the nearby obstacles (therefore seen under an elevation angle below 5.7°) • -An object is considered as an obstacle if it is seen under an angular width greater than 10°. • -The obstacles must be below 5.5 m within a 150 m distance around the tower (and if possible be below 7 m within a 300 m distance). • -The wind sensors must be located at a minimum distance of 15 times the width of thin nearby obstacles (mast, thin tree with angular width < 10°). • -The surrounding country must not present any relief change within a 300 m radius. A relief change is a 5 m height change.

  9. Class 2 (error 10% ?) -The wind tower must be erected at a distance of at least 10 times the height of the nearby obstacles (elevation angle < 5.7°) -An object is considered as an obstacle if it is seen under an angular width greater than 10°. -A relief change within a 100 m radius is also considered as an obstacle. -The wind sensors must be located at a minimum distance of 15 times the width of thin nearby obstacles (mast, thin tree with angular width < 10°).  Class 3 (error 20% ?) -The wind tower must be erected at a distance of at least 5 times the height of the nearby obstacles (elevation angle < 11.3°) -A relief change within a 50 m radius is also considered as an obstacle. -The wind sensors must be located at a minimum distance of 10 times the width of thin nearby obstacles.

  10. Class 4 (error 30% ?) • -The wind tower must be erected at a distance of at least 2.5 times the height of the nearby obstacles (elevation angle < 21.8°) • Class 5 (error > 40% ?) • -Obstacles are existing at a distance less than 2.5 times their height. • - Obstacles with a height greater than 8 m, at a distance less than 25 m.

  11. St-SulpiceNord Est

  12. St-SulpiceSudOuest

  13. St-Sulpice. Relevé de masques • Class 4 for wind. • New Radome AWS settled at a distance of 60 m, away from the woods  class 3

  14. Saint Sulpice, DIRCERatio of mean wind speed (10 min.) between Patac et XariaSouth winds North winds

  15. Classification of stations • Between 2000 and 2006, 400 AWS have been installed for the Radome network. • The objective was class 1 for each parameter (Temp, RH, wind, precip., solar radiation). • But class 2 or class 3 were accepted when class 1 not possible. • Météo-France is now classifying al the surface observing stations, including the climatological cooperative network: ~4300 sites, before the end of 2008. • Update at least every 5 years.

  16. Where are we ?

  17. Other quality factors • Intrinsic performances • Maintenance and calibration • Within a homogeneous network, these factors are known and generally the same. But Météo-France is using data from various networks: • Radome (554) • Non-proprietary AWS (~800) • Climatological cooperative network (> 3000) • The intrinsic performances, maintenance and calibration procedures are not the same.

  18. Several reasons • The objectives may be different. • But some uncertainty objectives are sometimes (often) unknown ! • To get cheap measurements ? • The maintenance and/or the calibration are not always organized ! • Within the ISO 9001-2000 certification process, Météo-France was forced to increase his knowledge of the various networks’ characteristics.

  19. Another classification ! • After site classification (1 to 5), definition of an additional classification, to cover the two quality factors : • Intrinsic performances • Maintenance and calibration • 5 levels were defined : • Class A : WMO/CIMO recommendations (Annex 1B of CIMO guide) • Class B : Lower specs, but more realistic or affordable : “good” performances and “good” maintenance and calibration. RADOME specs. • Class C: Lower performances and maintenance, but maintenance/calibration organized. • Class D : No maintenance/calibration organized. • Class E : Unknown performances and/or maintenance • This classification is called : Maintained performance classification

  20. Air temperature • Class A: Overall uncertainty of 0.1°C. Therefore, the uncertainty of the temperature probe lower than 0.1°C and use of a “perfect” artificially ventilated screen. Achievable measurement uncertainty is 0.2°C. • Class B: Pt100 (or Pt1000) temperature probe of class A ( 0.25°C). Acquisition uncertainty < 0.15°C. Radiation screen with known characteristics and over-estimation of Tx (daily max. temperature) < 0.15°C in 95% of cases. Laboratory calibration of the temperature probe every 5 years. • Class C: Temperature probe with uncertainty < 0.4°C. Acquisition uncertainty < 0.3°C. Radiation screen with known characteristics and over-estimation of Tx < 0.3°C in 95% of cases. • Class D: Temperature probe and/or acquisition system uncertainty lower than for class C. Radiation screen or with “unacceptable” characteristics (for example, over-estimation of Tx > 0.7°C in 5% of cases).

  21. Relative humidity • Class A: Overall uncertainty of 1%! Achievable 2%. • Class B: Sensor specified for  6%, over a temperature range of –20°C to +40°C. Acquisition uncertainty < 1%. Calibration every year, in an accredited laboratory. • Class C: Sensor specified for  10%, over a temperature range of –20°C to +40°C. Acquisition uncertainty < 1%. Calibration every two years in an accredited laboratory, or calibration every year in a non-accredited laboratory. • Class D: Sensor with specifications worst than  10% over the common temperature conditions. Calibration not organized.

  22. Global solar radiation • Class A: Pyranometer of ISO class 1. Uncertainty of 5% for daily total. Ventilated sensor. Calibration every two years. Regular cleaning of the sensor (at least weekly). • Class B: Pyranometer of ISO class 1. No ventilation. Calibration every two years. No regular cleaning of the sensor. • Class C: Pyranometer of ISO class 2. No ventilation. Calibration every five years. No regular cleaning of the sensor. • Class D: Sensor not using a thermopile. Calibration not organized.

  23. Other parameters • Pressure • Amount of precipitation • Wind • Visibility • Temperature above ground • Soil temperature

  24. Status of the RADOME network • Air temperature : Class B • RH : Class B • Amount of precipitation : Class B or Class C, depending on the rain gauge used. • Wind : Class A • Global solar radiation : Class A for manned station, class B for isolated sites. • Ground temperatures : Class B • Pressure : Class B • Visibility (automatic) : Class B

  25. Status of the cooperative network • Air temperature (liquid in glass thermometers) : Class C • Amount of precipitation : Class B

  26. Status of non-Météo-France additional networks • Air temperature : Class B to D • RH : Class B to D • Amount of precipitation : Class B to C • Wind : Class B to D • Global solar radiation : Class B to D • Ground temperature : Class B to C • Pressure : Class B to D

  27. Metadata • These classification for each site are meta data, part of the climatological database. • Site classification is on going. • Maintained performance classification has been defined this year and is being applied : is it possible to “easily” classify the additional networks. • With these two classifications, a measurement on a site can be given a short description. • Example : C3 for global solar radiation is for a class 2 pyranometer without ventilation, calibrated every 2 years, installed on a site with direct obstructions, but below 7°.

  28. An image of a network

  29. An image of the RADOME network

  30. Conclusion • These classifications are intended to describe the real world of measuring networks, which is sometimes far form the WMO/CIMO recommendations. • WMO (CIMO, CBS) has decided to develop a site classification, on the example of this classification. Such a standard would be further recognized by ISO. • This topic has been recently discussed by the CIMO Expert Team on Surface Technology and Measurement Techniques. • Any suggestions or comments are welcomed. To be addressed to Michel Leroy

  31. Proposed change for precipitation • Change class 1 for having in class 1 a well protected site : homogeneous obstacles around the rain gauge which can reduce the wind speed at the gauge level. • Class 2 unchanged : no obstacles closer than 2 times their height.

  32. Proposed change for temperature/humidity • To use the climatology of wind for temperature classification. • % of low wind speed ( < 1.5 or 2 m/s) ? Trappes St Denis, La Réunion

  33. Proposed change for temperature/humidity • The perturbation from artificial surface is greatly reduce with wind. With a 1 m/s wind, the air moves by 60 m in one minute. The frequency of mean wind speed (at 10 m) below 1.5 m/s could be used to reduce the influence of artificial surface in the classification. • The shading conditions currently used are a big constraint. It could be partly replaced by the global angle of view of obstacles : • No obstacles, angle of view is 0 • Obstacles everywhere : angle of view is 2P (100%). • Screen along a wall : angle of view is P (50%). • Angle of view thresholds could be 5%, 10%, 20% • But more difficult to evaluate.

More Related