The wettest months in the United Kingdom tend to be at the start and end of the year. In the period of consideration, the greatest measurement of rainfall was nearly 217 millimeters, recorded in December 2015. The lowest level of rainfall was recorded in April 2021, at 20.6 millimeters. Rainy days The British Isles are known for their wet weather, and in 2024 there were approximately 164 rain days in the United Kingdom. A rainday is when more than one millimeter of rain falls within a day. Over the past 30 years, the greatest number of rain days was recorded in the year 2000. In that year, the average annual rainfall in the UK amounted to 1,242.1 millimeters. Climate change According to the Met Office, climate change in the United Kingdom has resulted in the weather getting warmer and wetter. In 2022, the annual average temperature in the country reached a new record high, surpassing 10 degrees Celsius for the first time. This represented an increase of nearly two degrees Celsius when compared to the annual average temperature recorded in 1910. In a recent survey conducted amongst UK residents, almost 80 percent of respondents had concerns about climate change.

In the third quarter of 2024, the average rainfall in the United Kingdom was approximately 7.1 millimeters higher than the long-term mean. In the previous quarter, average rainfall was about 12 millimeters higher than the mean from 2002 to 2021.

Between 2001 and 2024, the average rainfall in the United Kingdom varied greatly. In 2010, rainfall dropped to a low of 1,020 millimeters, which was a noticeable decrease when compared to the previous year. However, the following year, rainfall increased significantly to a peak of 1,889 millimeters. During the period in consideration, rainfall rarely rose above 1,500 millimeters. In 2024, the annual average rainfall in the UK surpassed 1,386 millimeters. Monthly rainfall On average, rainfall is most common at the start and end of the year. Between 2014 and 2024, monthly rainfall peaked in December 2015 at approximately 217 millimeters. This was the first of only two times during this period that the average monthly rainfall rose above 200 millimeters. This was a deviation from December’s long-term mean of some 134 millimeters. Rainfall highest in Scotland In the United Kingdom, rain is often concentrated around mountainous regions such as the Scottish Highlands, so it is no surprise to see that – on average – it is Scotland that receives the most rainfall annually. However, in 2024, Wales received the highest rainfall amounting to approximately 1,600 millimeters. Geographically, it is the north and west of the United Kingdom that receives the lion's share of rain, as it is more susceptible to rainfall coming in from the Atlantic.

The United Kingdom experienced an average of 1,242.1 millimeters of rainfall in 2024, a decrease of 5.8 percent in comparison to the previous year. While 2024 saw substantial rainfall, it did not surpass the thus-far peak of the century, with 1,373 millimeters of rain recorded in 2000. Regional variations and seasonal patterns Rainfall distribution across the UK is far from uniform, with Scotland and Wales consistently receiving the highest annual precipitation. In 2024, they recorded an average of 1,571.7 millimeters and 1,600.8 millimeters, respectively, significantly above the UK’s average. This disparity is largely due to both countries’ mountainous terrain, which is more susceptible to Atlantic weather systems. Seasonally, the wettest months in the UK typically occur in the winter, with the highest precipitation levels seen between November and February. Climate change impact on UK weather Climate change is influencing UK weather patterns, leading to warmer and wetter conditions overall. While annual rainfall fluctuates, there is a trend towards more extreme weather events. For example, 2020 and 2022 saw rain deviations from the long-term mean in the UK of more than 100 millimeters in February. As weather patterns continue to evolve, monitoring rainfall trends remains crucial for understanding and adapting to a changing climate.

Since 2015, the greatest monthly rainfall deviation in the United Kingdom occurred in February 2020. This month saw a considerable increase of 139 millimeters from the long-term mean. In comparison, the same month in 2023 saw a decrease of almost 40 millimeters compared to the mean from 2002 to 2021.

The UK daily rainfall data contain rainfall accumulation and precipitation amounts over a 24 hour period. The data were collected by observation stations operated by the Met Office across the UK and transmitted within the following message types: NCM, AWSDLY, DLY3208 and SSER. The data spans from 1853 to 2023. Over time a range of rain gauges have been used - see section 5.6 and the relevant message type information in the linked MIDAS User Guide for further details.

This version supersedes the previous version (202308) of this dataset and a change log is available in the archive, and in the linked documentation for this record, detailing the differences between this version and the previous version. The change logs detail new, replaced and removed data. These include the addition of data for calendar year 2023.

This dataset is part of the Midas-open dataset collection made available by the Met Office under the UK Open Government Licence, containing only UK mainland land surface observations owned or operated by Met Office. It is a subset of the fuller, restricted Met Office Integrated Data Archive System (MIDAS) Land and Marine Surface Stations dataset, also available through the Centre for Environmental Data Analysis - see the related dataset section on this record. A large proportion of the UK raingauge observing network (associated with WAHRAIN, WADRAIN and WAMRAIN for hourly, daily and monthly rainfall measurements respectively) is operated by other agencies beyond the Met Office, and are consequently currently excluded from the Midas-open dataset. Currently this represents approximately 13% of available daily rainfall observations within the full MIDAS collection.

The UK hourly rainfall data contain the rainfall amount (and duration from tilting syphon gauges) during the hour (or hours) ending at the specified time. The data also contains precipitation amounts, however precipitation measured over 24 hours are not stored. Over time a range of rain gauges have been used - see the linked MIDAS User Guide for further details.

This version supersedes the previous version of this dataset and a change log is available in the archive, and in the linked documentation for this record, detailing the differences between this version and the previous version. The change logs detail new, replaced and removed data.

The data were collected by observation stations operated by the Met Office across the UK and transmitted within the following message types: NCM, AWSHRLY, DLY3208, SREW and SSER. The data spans from 1915 to 2023.

This dataset is part of the Midas-open dataset collection made available by the Met Office under the UK Open Government Licence, containing only UK mainland land surface observations owned or operated by the Met Office. It is a subset of the fuller, restricted Met Office Integrated Data Archive System (MIDAS) Land and Marine Surface Stations dataset, also available through the Centre for Environmental Data Analysis - see the related dataset section on this record. A large proportion of the UK raingauge observing network (associated with WAHRAIN, WADRAIN and WAMRAIN for hourly, daily and monthly rainfall measurements respectively) is operated by other agencies beyond the Met Office, and are consequently currently excluded from the Midas-open dataset.

There were around 15 rainy days in the United Kingdom in July 2024. A rainday is when one millimeter or more of rain occurs in a day. The highest number of rain days was recorded in December 2015, at 22.2 The fourth quarter was the wettestThe wettest periods of the year tend to be the start and the end. In 2023, the fourth quarter was the wettest, with an average of 419 mm of rainfall. October and December of that year recorded the highest monthly rainfall levels at 177 and 189 mm, respectively. Regional weatherDue to the United Kingdom’s geographical location and landscape, weather conditions can vary greatly. Scotland is, on average, the wettest country. Most rainfall is concentrated in the Scottish Highlands, as precipitation often occurs in mountainous regions. As rainfall comes in from the Atlantic, the northern and western parts of the UK are most susceptible to precipitation. This explains why England is the driest of all the regions, as rain deposits reduce as they move east.

Average Rainfall (mm) and average Temperature (centigrade) for the North East England and East England Met Office Climate district, which includes Lincolnshire. This dataset shows the average Rainfall in millimetres and average Temperature in centigrade, by month, meteorological season, and annual calendar year. The data is sourced from the UK Met Office website. See the Source link for more information about the data and the area it covers.

Average rainfall in the United Kingdom has generally been higher during the fourth quarter of every year. In the period of consideration, the highest rainfall average was recorded in the fourth quarter of 2011, at 738.6 millimeters.

Since 2011, rainfall in Scotland has typically been the highest out of the countries that comprise the United Kingdom. Rainfall in Scotland peaked at 1,862 millimeters in 2011, while rainfall in England amounted to 712.8 millimeters that same year. In 2024, however, Wales recorded the highest amount of rainfall across the United Kingdom, at nearly 1,601 millimeters.

The annual number of rain days in the UK has fluctuated over the past three decades. In 2024, there were *** days in which * mm or more of rain fell. The year with the greatest number of rain days was 2000 when ***** days had at least * mm of rain. England is the driest country in the UK England is on average the driest country in the United Kingdom. In 2024, the country recorded an annual rainfall of **** mm. After England, Northern Ireland is the country that receives the least amount of rainfall across the UK. Wettest regions in Britain Despite Cardiff being the wettest city in the United Kingdom according to the Met Office, Scotland had received on average the largest volume of annual rainfall in the past 10 years. The northern and western regions of the UK – where rainfall is arriving from the Atlantic – tend to be the wettest in the country.

HadUK-Grid is a collection of gridded climate variables derived from the network of UK land surface observations. The data have been interpolated from meteorological station data onto a uniform grid to provide complete and consistent coverage across the UK. The dataset at 60 km resolution is derived from the associated 1 km x 1 km resolution to allow for comparison to data from UKCP18 climate projections. The dataset spans the period from 1836 to 2024, but the start time is dependent on climate variable and temporal resolution.

The gridded data are produced for daily, monthly, seasonal and annual timescales, as well as long term averages for a set of climatological reference periods. Variables include air temperature (maximum, minimum and mean), precipitation, sunshine, mean sea level pressure, wind speed, relative humidity, vapour pressure, days of snow lying, and days of ground frost.

This data set supersedes the previous versions of this dataset which also superseded UKCP09 gridded observations. Subsequent versions may be released in due course and will follow the version numbering as outlined by Hollis et al. (2019, see linked documentation).

The changes for v1.3.1.ceda HadUK-Grid datasets are as follows:

Changes to the dataset * Added data for calendar year 2024 * Extended the daily temperature grids back to 1931

Changes to the input data * Incorporated additional daily rainfall data for 60 sites in Scotland, 1922-45 * Incorporated additional monthly rainfall data for two sites - Westonbirt (1880-1951) & Ackworth School (1852-53) * Fixed a 1-day offset for sunshine duration values for six stations between 1971 and 1993 * Corrected the daily rainfall data for Macclesfield, 1958-60 (the values had been stored in the wrong units) * Improved the quality control of the most recent three months of rainfall data (Oct-Dec 2024) * Removed Corpach from the wind speed grids (the station is poorly modelled - this only affects 14 months) * Reviewed the quality control flags that had been applied automatically to historical air and grass minimum temperature data. In many cases it was possible to remove the flags and this has allowed us to incorporate additional data into the grids for 1961-1997 for these variables. * Improved the business logic relating to data completeness. This affects monthly wind speed and has allowed us to re-introduce some of the data that were excluded in the previous release.

• Net changes to the input station data:
  • Total of 131314637 observations
  • 126821432 (96.6%) unchanged
  • 105327 (0.08%) modified for this version
  • 4387878 (3.34%) added in this version
  • 44224 (0.03%) deleted from this version

The primary purpose of these data are to facilitate monitoring of UK climate and research into climate change, impacts and adaptation. The datasets have been created by the Met Office with financial support from the Department for Business, Energy and Industrial Strategy (BEIS) and Department for Environment, Food and Rural Affairs (DEFRA) in order to support the Public Weather Service Customer Group (PWSCG), the Hadley Centre Climate Programme, and the UK Climate Projections (UKCP18) project. The output from a number of data recovery activities relating to 19th and early 20th Century data have been used in the creation of this dataset, these activities were supported by: the Met Office Hadley Centre Climate Programme; the Natural Environment Research Council project "Analysis of historic drought and water scarcity in the UK"; the UK Research & Innovation (UKRI) Strategic Priorities Fund UK Climate Resilience programme; The UK Natural Environment Research Council (NERC) Public Engagement programme; the National Centre for Atmospheric Science; National Centre for Atmospheric Science and the NERC GloSAT project; and the contribution of many thousands of public volunteers. The dataset is provided under Open Government Licence.

This is version v3.4.0.2023f of Met Office Hadley Centre's Integrated Surface Database, HadISD. These data are global sub-daily surface meteorological data.

This update (v3.4.0.2023f) to HadISD corrects a long-standing bug which was discovered in autumn 2023 whereby the neighbour checks (and associated [un]flagging for some other tests) were not being implemented. For more details see the posts on the HadISD blog: https://hadisd.blogspot.com/2023/10/bug-in-buddy-checks.html & https://hadisd.blogspot.com/2024/01/hadisd-v3402023f-future-look.html

The quality controlled variables in this dataset are: temperature, dewpoint temperature, sea-level pressure, wind speed and direction, cloud data (total, low, mid and high level). Past significant weather and precipitation data are also included, but have not been quality controlled, so their quality and completeness cannot be guaranteed. Quality control flags and data values which have been removed during the quality control process are provided in the qc_flags and flagged_values fields, and ancillary data files show the station listing with a station listing with IDs, names and location information.

The data are provided as one NetCDF file per station. Files in the station_data folder station data files have the format "station_code"_HadISD_HadOBS_19310101-20240101_v3.4.1.2023f.nc. The station codes can be found under the docs tab. The station codes file has five columns as follows: 1) station code, 2) station name 3) station latitude 4) station longitude 5) station height.

To keep informed about updates, news and announcements follow the HadOBS team on twitter @metofficeHadOBS.

For more detailed information e.g bug fixes, routine updates and other exploratory analysis, see the HadISD blog: http://hadisd.blogspot.co.uk/

References: When using the dataset in a paper you must cite the following papers (see Docs for link to the publications) and this dataset (using the "citable as" reference) :

Dunn, R. J. H., (2019), HadISD version 3: monthly updates, Hadley Centre Technical Note.

Dunn, R. J. H., Willett, K. M., Parker, D. E., and Mitchell, L.: Expanding HadISD: quality-controlled, sub-daily station data from 1931, Geosci. Instrum. Method. Data Syst., 5, 473-491, doi:10.5194/gi-5-473-2016, 2016.

Dunn, R. J. H., et al. (2012), HadISD: A Quality Controlled global synoptic report database for selected variables at long-term stations from 1973-2011, Clim. Past, 8, 1649-1679, 2012, doi:10.5194/cp-8-1649-2012

Smith, A., N. Lott, and R. Vose, 2011: The Integrated Surface Database: Recent Developments and Partnerships. Bulletin of the American Meteorological Society, 92, 704–708, doi:10.1175/2011BAMS3015.1

For a homogeneity assessment of HadISD please see this following reference

Dunn, R. J. H., K. M. Willett, C. P. Morice, and D. E. Parker. "Pairwise homogeneity assessment of HadISD." Climate of the Past 10, no. 4 (2014): 1501-1522. doi:10.5194/cp-10-1501-2014, 2014.

A precipitação no Reino Unido aumentou para 1404,08 mm em 2023, em comparação com 1121,47 mm em 2022. Esta página inclui um gráfico com dados históricos para a Precipitação Média no Reino Unido.

The United Kingdom rain gutter market size reached around USD 551.33 Million in 2024. The market is projected to grow at a CAGR of 5.30% between 2025 and 2034 to reach nearly USD 924.05 Million by 2034.

Rainfall in England amounted to *** millimeters in February 2020. This was the most rainfall recorded in a single month during the period of consideration. Meanwhile, the driest month during this period was in May 2020, in which less than ** millimeters of rain fell. In April 2025, England's precipitation amounted to **** millimeters, a decrease of ** percent in comparison to the same month the previous year.

HadUK-Grid is a collection of gridded climate variables derived from the network of UK land surface observations. The data have been interpolated from meteorological station data onto a uniform grid to provide complete and consistent coverage across the UK. The datasets cover the UK at 1 km x 1 km resolution. These 1 km x 1 km data have been used to provide a range of other resolutions and across countries, administrative regions and river basins to allow for comparison to data from UKCP18 climate projections. The dataset spans the period from 1836 to 2024, but the start time is dependent on climate variable and temporal resolution.

The gridded data are produced for daily, monthly, seasonal and annual timescales, as well as long term averages for a set of climatological reference periods. Variables include air temperature (maximum, minimum and mean), precipitation, sunshine, mean sea level pressure, wind speed, relative humidity, vapour pressure, days of snow lying, and days of ground frost.

This data set supersedes the previous versions of this dataset which also superseded UKCP09 gridded observations. Subsequent versions may be released in due course and will follow the version numbering as outlined by Hollis et al. (2019, see linked documentation).

The changes for v1.3.1.ceda HadUK-Grid datasets are as follows:

Changes to the dataset * Added data for calendar year 2024 * Extended the daily temperature grids back to 1931

Changes to the input data * Incorporated additional daily rainfall data for 60 sites in Scotland, 1922-45 * Incorporated additional monthly rainfall data for two sites - Westonbirt (1880-1951) & Ackworth School (1852-53) * Fixed a 1-day offset for sunshine duration values for six stations between 1971 and 1993 * Corrected the daily rainfall data for Macclesfield, 1958-60 (the values had been stored in the wrong units) * Improved the quality control of the most recent three months of rainfall data (Oct-Dec 2024) * Removed Corpach from the wind speed grids (the station is poorly modelled - this only affects 14 months) * Reviewed the quality control flags that had been applied automatically to historical air and grass minimum temperature data. In many cases it was possible to remove the flags and this has allowed us to incorporate additional data into the grids for 1961-1997 for these variables. * Improved the business logic relating to data completeness. This affects monthly wind speed and has allowed us to re-introduce some of the data that were excluded in the previous release.

• Net changes to the input station data:
  • Total of 131314637 observations
  • 126821432 (96.6%) unchanged
  • 105327 (0.08%) modified for this version
  • 4387878 (3.34%) added in this version
  • 44224 (0.03%) deleted from this version

The primary purpose of these data are to facilitate monitoring of UK climate and research into climate change, impacts and adaptation. The datasets have been created by the Met Office with financial support from the Department for Business, Energy and Industrial Strategy (BEIS) and Department for Environment, Food and Rural Affairs (DEFRA) in order to support the Public Weather Service Customer Group (PWSCG), the Hadley Centre Climate Programme, and the UK Climate Projections (UKCP18) project. The output from a number of data recovery activities relating to 19th and early 20th Century data have been used in the creation of this dataset, these activities were supported by: the Met Office Hadley Centre Climate Programme; the Natural Environment Research Council project "Analysis of historic drought and water scarcity in the UK"; the UK Research & Innovation (UKRI) Strategic Priorities Fund UK Climate Resilience programme; The UK Natural Environment Research Council (NERC) Public Engagement programme; the National Centre for Atmospheric Science; National Centre for Atmospheric Science and the NERC GloSAT project; and the contribution of many thousands of public volunteers. The dataset is provided under Open Government Licence.

Snapshot img

Smart Home Weather Stations And Rain Gauge Market Size 2024-2028

The smart home weather stations and rain gauge market size is forecast to increase by USD 100.5 million, at a CAGR of 9.77% between 2023 and 2028.

The market is experiencing significant growth, driven by the continuous product innovation in terms of technology, performance, features, and design. These advancements enable weather stations to offer more accurate and real-time weather forecasting data, integrating seamlessly with smart home systems and IoT devices. Furthermore, the increasing popularity of wireless connecting devices and the Internet of Things (IoT) is fueling market expansion. However, challenges persist, particularly in developing and underdeveloped countries, where product awareness remains low. Companies seeking to capitalize on market opportunities must focus on raising awareness and providing affordable, user-friendly solutions tailored to these regions.
Navigating these challenges effectively will require strategic partnerships, targeted marketing efforts, and a deep understanding of local market dynamics. Overall, the market presents a compelling growth opportunity for businesses that can successfully innovate, adapt, and expand their reach.

What will be the Size of the Smart Home Weather Stations And Rain Gauge Market during the forecast period?

Explore in-depth regional segment analysis with market size data - historical 2018-2022 and forecasts 2024-2028 - in the full report.
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The smart home weather station market continues to evolve, integrating various technologies to provide real-time meteorological data for diverse applications. IoT integration enables seamless data acquisition and transmission, allowing for weather alerts and barometric pressure sensors to inform users of potential weather changes. The smart home ecosystem incorporates temperature sensors, humidity sensors, and UV sensors to optimize home automation and energy efficiency. Beyond residential use, agricultural applications benefit from professional weather stations, which provide historical data for climate science and solar power optimization. DIY weather station kits cater to the DIY community, offering open source hardware and software for personal weather stations.

These stations can also be used for educational applications and environmental monitoring. Ultrasonic rain gauges and wind speed sensors contribute to data logging and weather forecasting, while cloud-based platforms ensure data security and data visualization. Open API integration allows for mobile app integration, providing users with easy access to weather information. Green technology and climate change initiatives further drive the market, as weather data analysis becomes increasingly important for home security and environmental studies. The ongoing unfolding of market activities reveals a dynamic industry, with continuous innovation and integration of new technologies. Weather station kits cater to various sectors, from home security to scientific research, and offer wireless connectivity for real-time data and user interface customization.

The evolving patterns in this market reflect the growing importance of weather data in our daily lives and the role of technology in providing accurate and timely information.

How is this Smart Home Weather Stations And Rain Gauge Industry segmented?

The smart home weather stations and rain gauge industry research report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD million' for the period 2024-2028, as well as historical data from 2018-2022 for the following segments.

Product

  Smart weather stations
  Smart rain gauge


Distribution Channel

  Online
  Offline


Geography

  North America

    US


  Europe

    France
    Germany
    UK


  APAC

    China


  Rest of World (ROW)

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By Product Insights

The smart weather stations segment is estimated to witness significant growth during the forecast period.

Smart weather stations represent advanced home weather monitoring systems, seamlessly integrating with Android and iOS devices. These systems enable users to access comprehensive weather information on their smartphones, surpassing the reliance on television broadcasts. Smart weather stations offer both indoor and outdoor data, including humidity, temperature, and barometric pressure readings. The outdoor sensor facilitates weather-driven planning. The global market for smart weather stations experiences growth due to the increasing popularity of smart homes and connected devices. Moreover, these weather stations cater to diverse applications, such as agriculture, home security, and scientific research. They incorporate features like data visualization, real-time data transmission, and user interfaces.

Open source hardware and software, cloud-based platfor