Sensors continuously record the height of the water level with respect to a height reference surface close to the geoid. Water enters the device by the bottom pipe (far end of the tube, see picture), and electronic sensors measure its height and send the data to a tiny computer.
Historical data are available for about 1,450 stations worldwide, of which about 950 have provided updates to the global data center since January 2010. At some places records cover centuries, for example in Amsterdam where data dating back to 1700 is available.
When it comes to estimating the greater ocean picture, new modern tide gauges can often be improved upon by using satellite data.
Tide gauges are used to measure tides and quantify the size of tsunamis. The measurements make it possible to derive the mean sea level. Using this method, sea level slopes up to several 0.1 m/1000 km and more have been detected.
Tidal poles and float gauges were the primary means of sea-level measurement for over 150 years and continue to operate at some locations today. While still part of modern-day tide gauge instrumentation, these technologies have since been superseded by pressure gauges (similar to depth gauges), acoustic/ultrasonic gauges, and radar gauges.
The following types of tide gauges have been used historically:
- Kelvin type tide gauge
- Fuess type tide gauge
- GSI type tide gauge
- High accuracy automatic tide gauge
- High resolution automatic tide gauge
Tide gauges have a practical application in the shipping and fishing industries where low or high tide levels can hinder or prohibit access to shallow bays or locations with bridges. An example is the Cascais tide gauge in Portugal, which was originally installed because of the sand bar in the River Tagus that causes difficulties for shipping entering Lisbon port. Because of similar problems many industries have installed private tide gauges in ports around the world, and also rely on government agencies (such as NOAA).
Data collected from tide gauges is also of interest to scientists measuring global weather patterns, the mean sea water level, and trends - notably those potentially associated with global warming.
In recent years new technologies have developed allowing for real-time, remote tide information to be published online via a solar powered wireless connection to a tide sensor. Acoustic/ultrasonic sensors have already been deployed to great effect and the data is regularly broadcast via Twitter and also displayed online.
- "The Kronstadt sea-gauge". Your Guide in St Petersburg. Retrieved 26 April 2019. With explanatory diagram showing Lea-type float gauge and stilling-well.
- International Tsunami Information Center. "4. Tide, Mareograph, Sea Level". UNESCO.
- Ian Shennan; Antony J. Long; Benjamin P. Horton, eds. (2015). Handbook of Sea-Level Research. Wiley. p. 557. ISBN 978-1-118-45257-8.
- "Definition of LIMNIMETER". www.merriam-webster.com. Retrieved 2021-08-14.
- "Obtaining Tide Gauge Data". Permanent Service for Mean Sea Level. PSMSL. Retrieved 2016-03-07.
- "Other Long Records not in the PSMSL Data Set". PSMSL. Retrieved 2015-05-11.
- Tide gauge history UK National Oceanographic Centre Archived 2015-08-24 at the Wayback Machine
- "History of tide gauges". Tide Observation. Geospatial Information Authority of Japan. Retrieved 2014-04-19.
- "Remote Monitoring a MaxSonar®".
- "ioBridge Apps - Ockway Bay Tide Levels".
- Gerd Morgenschweis (2010). Hydrometrie: Theorie und Praxis der Durchflussmessung in offenen Gerinnen. Springer-Verlag. ISBN 978-3-642-05390-0. (in German)
|Wikimedia Commons has media related to Tide gauges.|