Hubbry Logo
search
logo
Stevenson screen avatar
Stevenson screen
Stevenson screen
current hub
2018219

Stevenson screen

logo
Community Hub0 Subscribers
Read side by side
Stevenson screen
View on Wikipedia
from Wikipedia

Exterior of a Stevenson screen

A Stevenson screen, or instrument shelter, is a shelter or an enclosure used to protect meteorological instruments against precipitation and direct heat radiation from outside sources, while still allowing air to circulate freely around them.[1] It forms part of a standard weather station and holds instruments such as thermometers, hygrometers, and barometers.

A Stevenson screen may also be called a cotton region shelter, an instrument shelter, a thermometer shelter, a thermoscreen, or a thermometer screen. Its purpose is to provide a standardised environment in which to measure temperature, humidity, dewpoint, and atmospheric pressure. It is white in color to reflect direct solar radiation.

History

[edit]
American variant (cotton region shelter)

The Stevenson screen was designed by Thomas Stevenson (1818–1887), a Scottish civil engineer who designed many lighthouses and was the father of author Robert Louis Stevenson. The development of his small thermometer screen with double-louvered walls on all sides and no floor was reported in 1864.[2] After comparisons with other screens in the United Kingdom, Stevenson's original design was modified.[3]

Modifications by Edward Mawley of the Royal Meteorological Society in 1884 included a double roof, a floor with slanted boards, and a modification of the double louvers.[4] This design was adopted by the British Meteorological Office and, eventually, other national services, such as that of Canada. The national services developed their own variations, such as the single-louvered cotton region shelter design in the United States.[5]

Composition

[edit]

The traditional Stevenson screen is a box shape, constructed of wood, in a double-louvered design.[6] However, it is possible to construct a screen using other materials and shapes, such as a pyramid. The World Meteorological Organization (WMO) agreed standard for the height of the thermometers is between 1.25 and 2 m (4 ft 1 in and 6 ft 7 in) above the ground.

Size

[edit]
Interior of a Stevenson screen

The interior size of the screen will depend on the number of instruments that are to be used. A single screen may measure 76.5 by 61 by 59.3 cm (30.1 by 24.0 by 23.3 in) and a double screen 76.5 by 105 by 59.3 cm (30.1 by 41.3 by 23.3 in).

The top of the screen was originally composed of two asbestos boards with an air space between them. These asbestos boards have generally been replaced by a laminate for health and safety reasons. The whole screen is painted with several coats of white to reflect sunlight radiation, and usually requires repainting every two years.

Siting

[edit]

The siting of the screen is very important to avoid data degradation by the effects of ground cover, buildings and trees: WMO 2010 recommendations, if incomplete, are a sound basis.[7] In addition, Environment Canada, for example, recommends that a screen be placed at at least twice as far away from any object as the object’s height, e.g. 20 m (66 ft) from any tree that is 10 m (33 ft) high.

In the northern hemisphere, the door of the screen should always face north so as to prevent direct sunlight on the thermometers. In polar regions with twenty-four-hour sunlight, the observer must take care to shield the thermometers from the sun and at the same time avoid a rise in temperature being caused by the observer's body heat.

A special type of Stevenson screen with an eye bolt on the roof is used on ships. The unit is hung from above and remains vertical despite the movement of the vessel.

Future

[edit]

In some areas the use of single-unit automatic weather stations is supplanting the Stevenson screen and other standalone meteorological equipment.[citation needed]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Stevenson screen

View on Grokipedia
from Grokipedia
A Stevenson screen, also known as an instrument shelter or thermometer screen, is a standardized, ventilated enclosure designed to house meteorological instruments such as thermometers, hygrometers, and psychrometers, protecting them from direct solar radiation, precipitation, wind, and other environmental influences while permitting free air circulation to ensure accurate measurements of air temperature, humidity, and related variables.[1] Typically constructed as a white-painted wooden box with louvered double walls and a double-layered roof to minimize radiative heating and facilitate ventilation, it is mounted on legs at a height of 1.25 to 2 meters above the ground in open, level terrain to provide representative ambient conditions.[1][2] Invented in 1864 by Scottish civil engineer and meteorologist Thomas Stevenson (1818–1887), the father of author Robert Louis Stevenson, the screen addressed inconsistencies in temperature readings caused by varying exposure methods in early weather stations, establishing a uniform protective structure that quickly became a global standard.[3] Stevenson's design emphasized natural ventilation through overlapping louvers to shield instruments without impeding airflow, and its white exterior reflects sunlight to prevent internal heating, with repainting recommended every one to two years for optimal performance.[1] This innovation was pivotal in advancing reliable meteorological observations, as prior unprotected thermometers could err by up to several degrees under direct sun or calm winds.[1] The World Meteorological Organization (WMO) endorses the Stevenson screen in its guidelines for surface observations, specifying siting in unobstructed areas at least 10 times the height of nearby obstacles away to avoid microclimate distortions, and it remains integral to manual and automatic weather stations worldwide for synoptic, climatological, and aviation purposes.[1] Modern adaptations include radiation shields for automated systems with forced ventilation at 2.5–10 m/s to replicate traditional airflow, though the original design's simplicity and effectiveness continue to underpin temperature and humidity data homogeneity essential for climate monitoring and forecasting.[1] Poor siting or maintenance can introduce errors of ±2.5 K or more, underscoring the screen's role in maintaining data quality across global networks.[1]

Overview and Purpose

Definition

A Stevenson screen is a standardized shelter or enclosure designed to house meteorological instruments, such as thermometers and hygrometers, providing protection while allowing for precise environmental measurements.[2] Its primary function is to shield these instruments from precipitation, direct solar radiation, and wind, while promoting free air circulation to ensure accurate readings of temperature, humidity, and related parameters.[2][4] The design facilitates natural ventilation, preventing localized influences that could skew data. Key physical characteristics include a typically white-painted, louvered wooden box elevated above the ground to minimize the influence of ground heat and surface effects.[5][4] This configuration reflects sunlight and supports standardized observations in meteorological stations worldwide.[2] The shelter is named after its inventor, Thomas Stevenson, a Scottish civil engineer.[4]

Role in Meteorological Measurements

The Stevenson screen plays a pivotal role in meteorological measurements by shielding instruments from direct solar radiation, precipitation, and other environmental interferences that could bias temperature and humidity readings. This protection is essential to prevent overheating during sunny conditions, cooling from evaporative effects of rain or snow accumulation, and convective influences from wind, ensuring that recorded values reflect ambient air conditions rather than localized distortions.[6][7] Commonly housed instruments include maximum and minimum thermometers for tracking daily temperature extremes, dry- and wet-bulb hygrometers for determining relative humidity through psychrometric calculations, and occasionally barometers for pressure readings, all positioned to minimize exposure while allowing adequate ventilation. These setups enable precise monitoring of key variables critical for short-term weather forecasting and long-term atmospheric analysis.[7][6] In global meteorological networks, the Stevenson screen facilitates standardized data collection aligned with World Meteorological Organization (WMO) protocols, supporting consistent inputs for numerical weather prediction models, historical climate records, and cross-national comparisons. By promoting uniformity across stations worldwide, it enhances the reliability of datasets used in international assessments, such as those for climate variability and change detection under WMO guidelines.[7] When properly sited and maintained, the screen reduces measurement errors for temperature to within 0.1–0.5°C, with many configurations achieving over 95% of readings within ±0.5°C of reference standards, thereby upholding high data quality for scientific applications. This error mitigation is particularly vital for extreme value statistics, where even small biases can skew analyses of heatwaves or cold spells.[7][8]

Design and Construction

Materials and Composition

The traditional Stevenson screen is primarily constructed from durable woods such as teak, cedar, or pine for its frame, walls, and base, chosen for their natural resistance to weathering and ability to maintain structural integrity in outdoor environments.[9][10] The walls consist of double-louvered wooden panels that facilitate the screen's protective function while allowing necessary environmental interaction. The base features a slanted wooden floor designed to promote drainage and prevent moisture accumulation.[2] The roof is double-layered to minimize heat transfer and rainwater penetration, originally composed of two asbestos boards separated by an air space for insulation, though this material has been phased out due to health concerns.[2] The entire structure is coated with white, non-toxic, weather-resistant paint to reflect solar radiation, reduce thermal absorption, and protect against warping, fungal growth, and insect damage.[10] In modern adaptations, traditional wooden components have been supplemented or replaced with synthetic materials for enhanced durability and safety, including fiberglass-filled polyester for roofs and enclosures, ABS plastic for panels, and aluminum or stainless steel accents to resist corrosion without compromising insulation properties.[11] These updates, such as substituting asbestos-insulated roofs with fiberglass or laminate alternatives, address environmental and health standards while preserving the screen's core protective role.[11]

Dimensions and Specifications

The standard single Stevenson screen measures approximately 76.5 cm in width, 61 cm in depth, and 59.3 cm in height, providing sufficient internal space to house thermometers and other instruments without restricting airflow.[2] These proportions ensure the enclosure remains compact yet functional for precise meteorological readings, with the base elevated by legs to a height of 1.25–2 m above the ground as recommended by World Meteorological Organization (WMO) guidelines to minimize ground-level temperature influences. A double screen variant, designed for multiple instruments, extends the depth to 105 cm while maintaining the same width and height of 76.5 cm and 59.3 cm, respectively, allowing for expanded capacity in standard land-based installations.[2] The support structure typically consists of four legs for stability on uneven terrain or a single central post for simpler mounting, calibrated to maintain the enclosure's volume and prevent airflow disruptions.[1] Variations include smaller shipboard versions adapted for marine environments, featuring reduced dimensions and eye bolts for secure deck mounting to withstand ship motion and exposure to salt spray.[12]

Ventilation and Protection Mechanisms

The louver system of the Stevenson screen employs double-layered, overlapping slats on all sides to shield meteorological instruments from direct sunlight, precipitation, and radiant heat while allowing sufficient airflow for accurate ambient measurements. This design reduces heat conduction from the outer walls to the inner enclosure, particularly under strong solar radiation, by creating a barrier that limits radiative exchange without impeding ventilation.[13][14] The roof incorporates a double-layered structure with an insulating air gap to minimize radiative heating from solar exposure, ensuring the internal temperature remains representative of surrounding air conditions. An overhanging eaves design further deflects precipitation and direct sunlight, preventing moisture ingress and thermal bias within the enclosure. The white exterior paint on both roof layers enhances reflectivity, reducing absorbed solar energy.[13][15] The hinged door is positioned to face north or away from prevailing winds, minimizing turbulence inside the screen during access and reducing exposure to direct sunlight or wind-driven disturbances that could alter internal airflow. This orientation helps maintain stable conditions for instruments by limiting external influences on the enclosed space.[13] Overall, the airflow principle in the Stevenson screen is based on passive natural ventilation, combining wind-driven motion through the louvers and natural convection from internal temperature gradients to circulate air evenly around the instruments. This prevents stagnation and ensures exposure to unmodified ambient conditions, with typical in-screen ventilation rates averaging around 0.2 m/s under standard meteorological assumptions.[14][16]

History

Invention by Thomas Stevenson

Thomas Stevenson (1818–1887), a prominent Scottish civil engineer, lighthouse designer, and meteorologist, as well as the father of writer Robert Louis Stevenson, developed the Stevenson screen in 1864 to standardize the protection of meteorological instruments.[17][18] His background in engineering, particularly with the Northern Lighthouse Board, informed his contributions to meteorology through the Scottish Meteorological Society, where he served as an active member and honorary secretary from 1871.[19] The primary purpose of the invention was to mitigate inconsistencies in thermometer readings arising from direct exposure to environmental elements, such as solar radiation, precipitation, and wind, which could skew temperature measurements in outdoor settings.[20] Stevenson first detailed his design—a simple "box for holding thermometers"—in the Journal of the Scottish Meteorological Society in 1864, emphasizing its role in ensuring accurate, comparable data across observation sites.[20] At a society council meeting that year, he demonstrated an improved model featuring double louvres for enhanced ventilation.[21] The original design consisted of a basic wooden enclosure with louvered walls on all sides, elevated on legs to promote airflow and shield instruments from ground radiation, rain, and direct sunlight while minimizing heat conduction from the structure itself.[22] This unpretentious yet effective shelter was initially tested in Scottish weather stations, where it proved reliable in the region's variable coastal and highland climates.[3] Early adoption was swift within the Scottish Meteorological Society's network of voluntary observers, where the screen improved the consistency and trustworthiness of manual temperature records, laying the groundwork for broader meteorological standardization.[19] Its recognition as a practical solution for data reliability encouraged initial implementation in regional observation programs by the mid-1860s.[23]

Modifications and Standardization

Following the initial design introduced in 1864, significant modifications to the Stevenson screen were proposed by Edward Mawley of the Royal Meteorological Society in 1884. These changes included the addition of a double roof to enhance protection from solar radiation, a slanted floor to facilitate drainage and prevent moisture accumulation, and refinements to the louver angles for improved airflow while minimizing direct sunlight penetration. These alterations addressed observed issues with overheating and uneven ventilation in the original model, based on comparative trials conducted in the UK. The modified design was adopted by the Royal Meteorological Society and subsequently integrated into practices by the UK Meteorological Office for greater uniformity in temperature measurements.[22] Regional adaptations emerged to suit diverse climates and observational needs. In the United States, the Weather Bureau developed the Cotton Region Shelter (CRS) as a variant tailored for the Cotton Belt's hot, humid conditions, featuring adjusted ventilation louvers and a larger overall structure to better accommodate instruments in agricultural monitoring stations.[24] In Canada, the screen was considered unsuitable for harsh winter conditions due to snow accumulation, leading to local adaptations. While international versions in Europe and Asia similarly varied in size and placement to align with local topography, these changes reflected efforts to maintain measurement accuracy in varied environments.[22] Standardization efforts accelerated in the early 20th century, culminating in the screen's incorporation into World Meteorological Organization (WMO) guidelines by the mid-20th century following the organization's founding in 1950. Height specifications were formalized in the 1950s, mandating placement between 1.25 and 2 meters above the ground to ensure consistent exposure across global networks.[25] This timeline reflected a push for interoperability in meteorological data. By 1920, the Stevenson screen and its variants had achieved widespread global adoption, deployed in weather stations across more than 100 countries and territories, profoundly shaping manual meteorological practices and enabling comparable climate records worldwide.

Installation and Siting

Placement Guidelines

The placement of a Stevenson screen follows standardized procedural guidelines to ensure the accuracy and integrity of meteorological measurements by minimizing influences from ground-level heat, solar radiation, and local obstructions. The base of the screen must be elevated 1.25 to 2 meters above the ground surface, as recommended by the World Meteorological Organization (WMO), to prevent interference from soil heat flux and animal activity while capturing representative air temperatures.[1] Orientation is critical for reducing direct solar exposure to the instruments inside; in the Northern Hemisphere, the door should face true north, while in the Southern Hemisphere, it should face true south. This positioning ensures that sunlight does not enter the screen when the door is opened for readings or maintenance. Assembly begins with securing the legs firmly on level ground to maintain stability and uniform airflow. The screen should be installed in an open area of at least 25 m × 25 m to ensure unobstructed airflow and representative conditions, with nearby surfaces selected for low reflectivity, such as short grass rather than concrete or asphalt, to limit radiative heating.[1] Ongoing maintenance protocols are essential to preserve the screen's protective function; this includes annual repainting with white, non-hygroscopic exterior paint to reflect solar radiation and regular checks of the louvers to ensure they remain free of debris and damage, preventing restricted airflow or contamination.[1]

Siting Considerations for Accuracy

To ensure accurate meteorological measurements within a Stevenson screen, the site must be selected to minimize microclimate distortions caused by surrounding terrain and obstacles. The screen should be placed on level, open ground covered with short, uniform grass, avoiding hollows, steep slopes, or uneven topography that could lead to cold air drainage or altered airflow patterns. The distance to any obstructions should be at least twice (and preferably four times) their height to prevent localized warming or shading effects and maintain representative air conditions.[1] In urban environments, siting challenges are amplified by the urban heat island effect, where impervious surfaces and anthropogenic heat sources can elevate ambient temperatures by several degrees compared to rural areas, necessitating placement in locations that reflect typical urban climate zones while accounting for pollution impacts on sensor longevity. Rural sites generally offer fewer interferences but still require avoidance of natural features like dense vegetation or watercourses that could introduce humidity biases. For coastal installations, exposure to salt-laden air accelerates corrosion, requiring the use of corrosion-resistant materials such as treated wood, fiberglass, or galvanized metal components to maintain structural integrity over time.[26] Proximity to artificial surfaces like asphalt roads or large water bodies can introduce significant errors in temperature readings, with deviations of up to 1–2°C observed due to radiative heating from paved areas or evaporative cooling from nearby water, respectively; a minimum distance of 30 meters from such features is advised to mitigate these influences. Excessive wind exposure or sheltering can also skew results by disrupting natural ventilation within the screen, potentially requiring additional windbreaks or enhanced shielding in exposed locations to stabilize airflow without impeding circulation. Basic orientation of the screen with louvered sides facing cardinal directions helps align with prevailing winds for optimal exposure.[1][27] Site suitability should be validated prior to permanent installation by deploying comparative sensors—such as a reference thermometer in a standard Stevenson screen—alongside the proposed setup for an extended period under varying conditions, allowing for error assessment against calibrated benchmarks with uncertainties as low as 0.04 K. This intercomparison, combined with detailed metadata on obstacle angles and surface types, ensures the location meets exposure standards and supports long-term data reliability.[1]

Modern Developments

Current Standards and Usage

The World Meteorological Organization (WMO) updated its guidelines in the 2018 edition of the Guide to Instruments and Methods of Observation (WMO-No. 8), recommending the continued use of Stevenson screens or equivalent naturally ventilated shelters for protecting temperature and humidity sensors at reference meteorological stations to maintain long-term data consistency and comparability.[28] These revisions highlight the integration of digital sensors within Stevenson screens, allowing automated readings while preserving the enclosure's role in shielding instruments from solar radiation, precipitation, and wind, thereby supporting hybrid systems that combine traditional and modern measurement technologies.[14] This approach ensures compliance with WMO standards for response times, such as achieving 95% sensor response within 60 seconds under natural ventilation.[14] Stevenson screens are widely deployed in global meteorological networks, including those managed by organizations like the National Oceanic and Atmospheric Administration (NOAA) and the United Kingdom Met Office (UKMO).[29] In these networks, the screens house both analog and digital instruments, providing redundancy through parallel measurements that enhance data reliability for weather forecasting and climate monitoring.[30] For instance, NOAA employs Cotton Regional shelters—a variant of the Stevenson design—at many of its automated surface observing system stations, while the UKMO standardizes white louvered screens at its primary observing sites to meet exposure requirements at 1.25 meters above ground.[31][13] Training programs for meteorologists emphasize WMO-compliant practices for Stevenson screen installation, maintenance, and operation, forming a core component of observational competencies outlined in the organization's education framework.[32] These include hands-on instruction in reading instruments within the enclosure, ensuring accurate manual observations, and are integrated into certification courses at WMO Regional Training Centres to preserve skills in traditional techniques amid increasing automation.[33] Such training supports the use of Stevenson screens in educational settings worldwide, where they demonstrate fundamental principles of meteorological exposure and data quality control.[32] To accommodate extreme environments, Stevenson screens have been evaluated in polar stations, where they maintain ventilation standards under sub-zero temperatures and high winds, as shown in WMO intercomparisons like the 2022–2023 Arctic trial at Ny-Ålesund. In desert regions, standard Stevenson screens perform effectively in arid conditions, as demonstrated in field tests in locations like Ghardaïa, Algeria.[7] These evaluations ensure the screens' suitability for remote and harsh deployments without altering their fundamental role in standardized observations.[14]

Recent Research on Performance

A 2024 study conducted by researchers at the University of Reading evaluated the long-term performance of the Stevenson screen by comparing over 1.5 million temperature readings from traditional wooden screens against modern aspirated thermometer systems across European sites. The analysis demonstrated that the Victorian-era design maintains high accuracy, with median biases below 0.06°C for daily maximum and minimum temperatures, and 50% of readings falling within ±0.07°C of the aspirated reference. Errors exceeding 0.2°C were rare, occurring in only about 12% of minimum temperatures under calm, clear nighttime conditions and 4% of maximum temperatures during low-wind winter days with low solar angles, thus validating the screen's reliability over more than 150 years when benchmarked against contemporary sensors.[8][20] Comparative analyses from international intercomparisons have further affirmed the Stevenson screen's consistency with automated radiation shields. A 2022–2023 field trial in the Arctic at Ny-Ålesund, Norway, organized under World Meteorological Organization (WMO) guidelines, tested the Stevenson screen alongside nine other shield models over 14 months in a high-latitude climate with variable winds and solar irradiance. Results showed differences below 0.1°C relative to the reference naturally ventilated shield during low-wind conditions (<2 m/s), with overall uncertainties ranging from 0.27°C to 1.2°C that diminished at higher wind speeds (>5 m/s), indicating over 95% alignment in stable measurements across diverse environmental factors. Earlier WMO-aligned efforts, such as those evaluating shield performance in varied global climates between 2010 and 2020, similarly reported high concordance, with Stevenson screens exhibiting minimal offsets (typically <0.1°C) compared to forced-ventilation alternatives in operational networks.[34] Quantification of errors in Stevenson screens highlights the role of design elements in mitigating biases. The white exterior paint significantly reduces radiative heating by reflecting solar radiation, with studies showing it lowers daytime warm biases by up to 80% relative to unpainted or darker surfaces, as solar absorption is minimized to less than 20% of incident energy. Airflow modeling and field measurements confirm that internal conditions remain largely uniform under typical winds, with mean ventilation rates of 0.2 m s⁻¹—about 7% of external speeds—ensuring adequate mixing despite occasional turbulence, though spatial temperature gradients can emerge below 0.35 m s⁻¹.[35][14][36] Recent updates have addressed historical gaps in material safety and sensor integration within Stevenson screens. Asbestos boards, once used in the roof for fireproofing, have generally been replaced with non-hazardous laminates to eliminate health risks from fiber release, improving operational hygiene without altering thermal performance. Compatibility with digital thermometers, such as platinum resistance sensors (Pt-100), has been enhanced through modern retrofits, as demonstrated in ongoing Met Office deployments and the 2024 Reading study, where electronic sensors inside screens achieved precisions matching analog mercury thermometers while enabling automated data logging and reduced maintenance.[37][20]

Alternatives and Future Trends

In recent years, automated weather stations (AWS) have emerged as viable alternatives to traditional Stevenson screens, incorporating advanced radiation shields with sensor arrays and aspirated fans to enhance ventilation and reduce manual intervention. These systems, such as Vaisala's DTR500 series naturally ventilated shields and Campbell Scientific's TS100SS fan-aspirated shield, protect temperature and humidity sensors from solar radiation while enabling automated data collection, thereby minimizing human error and maintenance requirements in remote or harsh environments.[38][39] Such designs align with World Meteorological Organization (WMO) guidelines for improved accuracy in non-ventilated conditions. Advancements in materials have led to lighter, more durable alternatives to wooden Stevenson screens, including plastic and composite constructions that resist corrosion and require minimal upkeep. For instance, MetSpec instrument shelters utilize UV-stable thermoplastic louvers and aluminum frames, offering enhanced longevity in outdoor settings without the periodic painting needed for wood.[40] These materials are particularly suited for deployment in remote areas, where traditional wooden screens may degrade due to environmental exposure.[36] Integration trends are shifting toward IoT-enabled weather stations that combine radiation shields with real-time data transmission capabilities, facilitating hybrid models for compatibility with legacy systems. Devices like the MeteoHelix IoT PRO incorporate patented double-helix shields with LoRa connectivity for low-power, long-range monitoring, allowing seamless upgrades in existing networks.[41] This approach supports broader data accessibility without fully replacing established infrastructure. Despite these innovations, the Stevenson screen's persistence in developing regions stems from cost-benefit analyses highlighting its low maintenance and affordability compared to imported AWS. Studies indicate that traditional designs incur significantly lower recurring costs in importation-dependent economies, making them preferable for widespread, resource-constrained deployments.[42][43]

References

  1. [PDF] Guide to Meteorological Instruments and Methods of Observation
  2. Stevenson Screen - Pakistan Meteorological Department
  3. [PDF] Stevenson, Thomas (1818-1887), civil engineer and meteorologist ...
  4. nssl0027.jpg | National Oceanic and Atmospheric Administration
  5. Stevenson screen - Oxford Reference
  6. Record high temperatures verified - Met Office
  7. [PDF] Measurements of natural airflow within a Stevenson screen, and its ...
  8. [PDF] wmo field intercomparison of thermometer screens/shields
  9. Accuracy of daily extreme air temperatures under natural variations ...
  10. Stevenson Screen Manufacturer in Roorkee,Exporter in India
  11. [PDF] WEATHER SHELTER (Stevenson Screen) No. 170T-P - large size
  12. https://www.wmo.int/pages/prog/www/IMOP/publications/IOM-106_TD-1579.pdf
  13. [PDF] MET 11 SHIPBOARD SCREEN - Metspec.net
  14. [PDF] Observations - Met Office
  15. Measurements of natural airflow within a Stevenson screen and ... - GI
  16. Stevenson Screen - Instrumentation World
  17. Natural ventilation effects on temperatures within Stevenson screens
  18. Thomas Stevenson (1818-1887) - The Victorian Web
  19. Stevenson screen | Te Ara Encyclopedia of New Zealand
  20. Thomas Stevenson - Graces Guide
  21. Temperature measurement tech still effective 160 years on
  22. The Scottish Meteorological Society's contribution to the science
  23. Thermometer screens and the geographies of uniformity ... - Journals
  24. Thomas Stevenson 1818–1887
  25. [PDF] Effects of Recent Thermometer Changes in the Cooperative Station ...
  26. Cooperative Observer Equipment - National Weather Service
  27. [PDF] A Guide to the Siting, Exposure and Calibration of Automatic ...
  28. https://library.wmo.int/viewer/41650/download?file=8-I-2018_en.pdf&type=pdf
  29. Global Observing System (GOS)
  30. How we measure temperature - Met Office
  31. Weather Instrument Shelter
  32. [PDF] Guide to Instruments and Methods of Observation - WMO Library
  33. Education and Training Programme (ETRP)
  34. [PDF] Intercomparison of Thermometer Radiation Shields in the Arctic
  35. measurement limitations of naturally ventilated thermometer screens
  36. Measuring the temperature of the air (Chapter 5)
  37. Equipment - Stevenson Screen, Thomas Stevenson, ca. 1910
  38. Radiation Shield Series DTR500 - Vaisala
  39. TS100SS: Aspirated Radiation Shield - Campbell Scientific
  40. Instrument Screens/Shelters - Hoskin Scientific
  41. Weather Station LoRa MeteoHelix® IoT PRO
  42. Towards a robust and affordable Automatic Weather Station
  43. Boosting a Weather Monitoring System in Low Income Economies ...
User Avatar
No comments yet.