Waves are the most commonly viewed feature of the ocean.  Forcing of wind on the ocean surface can generate waves that propagate across entire ocean basins.  Wave height is dependent upon wind speed and fetch (or distance over water which a given wind may blow without interruption). Waves represent the exchange of energy from the atmosphere into the ocean and impact air-sea gas exchange and upper ocean mixing.  Observations and predictions of wave generation, height, and direction of propagation throughout the global oceans are critical for safe and efficient commercial shipping, fisheries, mitigating potential hazards in coastal regions, and recreational activities.

Measuring waves has been the long-term job of moored buoys, which are spread along continental shelves with limited availability in the open ocean. Satellite observations provided by radar altimeters, such as the currently operating Ocean Surface Topography Mission (OSTM)/Jason-2 mission, provide global wave height observations on a daily basis.  Another key satellite observational capability is global ocean vector winds provided by radar scatterometers, such as the Advanced Scatterometer (ASCAT) onboard the Metop-A/B satellite. Both ocean vector winds and wave height observations from satellite are used to generate wave fields in global wave forecast models.
In the Northern Pacific Ocean, some of the highest waves are generated in the fall and winter months. Key locales have been identified throughout the world, where extreme waves will arrive from a certain location and direction to form and break over shoaling ocean bottom topography. Such locations became key destinations for big wave surfers, including Mavericks near Half Moon Bay, CA; Waimea Bay on the North Shore of Oahu, HI; Cortes Bank, 100 miles due west of San Diego, CA.  Recently, big wave contests are now held in several of these locations. In big wave and other surfing contests, surfers and contest organizers examine surf wave model forecasts to predict where and when optimum conditions of wave height and propagation direction will occur. When the forecasts appear optimal, surfers travel to the contest sites to challenge their mettle, astonish viewers, and attempt to ride the largest waves of the season. Over the last 15 years, surfers have developed and refined methods to ride the largest waves, such as being towed behind jet skis at sufficient speeds to catch the cresting waves.
To support surfers in determining where and when to surf, multiple services have developed detailed surf forecast products for popular and remote surf locations throughout the world. These specialized products utilize global wave models, which are augmented to include more detailed coastal locales and conditions.  Like global wave forecasters, these services also incorporate satellite data for assimilation into the models as well as forecast validation and nowcasting.  According to Graeme Rae, head of the modeling effort for Surfline, based in Huntington Beach, CA, satellite data plays a key role in their operations.  In particular, the most recent products used have been JASON-1 and OSTM/JASON-2 wave height data, and ocean vector winds  from ASCAT and the Quick Scatterometer (QuikSCAT). After QuikSCAT’s primary operating mode halted in November 2009, Rae said, “QuikSCAT was a big loss for our operations that we haven’t recovered from yet, even with the use of ASCAT”, noting that ASCAT has comparatively limited coverage. Surfline incorporates multiple data sets from buoys, regional higher resolution wind forecast models (if available), weather information, and satellites (most recently from ESA’s CryoSat-2 mission) to continuously improve their products and forecast skill.

Dataset NameProcessing
Start/StopFormatSpatial ResolutionTemporal