Svelte is a radical new approach to building user interfaces. Whereas traditional frameworks like React and Vue do the bulk of their work in the browser, Svelte shifts that work into a compile step that happens when you build your app. Instead of using techniques like virtual DOM diffing, Svelte writes code that surgically updates the DOM when the state of your app changes.
Svelte is a radical new approach to building user interfaces. Whereas traditional frameworks like React and Vue do the bulk of their work in the browser, Svelte shifts that work into a compile step that happens when you build your app. Instead of using techniques like virtual DOM diffing, Svelte writes code that surgically updates the DOM when the state of your app changes.
I built Whispering v4, an open-source cross-platform app powered by Svelte 5, SvelteKit, Tauri, Plasmo, Effect-TS, TanStack Table...
Tech of the highest order! Cheers 🥂
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
How dramatically does land rise from the ocean? Hawaii Edition
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
How dramatically does land rise from the ocean? California Edition
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 3x the OceanJut of Big Sur! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
All things paddling related! Kayaks, canoes, even SUPs are welcome -- this is your place to post your paddling photos, ask your gear questions, share your experiences, or just be a part of the paddling community!
About this infographic:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
Picture based reference guides for anything and everything. If it seems like something someone might print, physically post, and reference then it is a good link for this sub. Remember: Infographics are learning tools, guides are reference tools. Sometimes it's grey.
Picture based reference guides for anything and everything. If it seems like something someone might print, physically post, and reference then it is a good link for this sub. Remember: Infographics are learning tools, guides are reference tools. Sometimes it's grey.
A cool guide to dramatic mountains-meet-ocean scenery along Hawaii's coastline
About this cool guide:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
Picture based reference guides for anything and everything. If it seems like something someone might print, physically post, and reference then it is a good link for this sub. Remember: Infographics are learning tools, guides are reference tools. Sometimes it's grey.
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
DataIsBeautiful is for visualizations that effectively convey information. Aesthetics are an important part of information visualization, but pretty pictures are not the sole aim of this subreddit.
DataIsBeautiful is for visualizations that effectively convey information. Aesthetics are an important part of information visualization, but pretty pictures are not the sole aim of this subreddit.
How dramatically does land rise from the ocean? Hawaii Edition [OC]
About this map:
How dramatically a landform rises from the ocean is determined not only by how high it rises above the ocean, but also how steeply. A 1000-foot vertical ocean cliff is incredibly spectacular, whereas a 1000-foot mountain located dozens of kilometers from the ocean is a fairly mundane sight. Hence, I developed OceanJut, measure that factors both how high and how steeply a landform rises from the ocean into an overall indicator of impressiveness.
A landform with an OceanJut of X is considered to rise from the ocean as impressively as a vertical ocean cliff of height X. So for instance, a vertical ocean cliff of height 100 ft, a 45° coastal slope of height 141 ft, and a 30° coastal slope of height 200 ft would all measure an OceanJut of 100 ft and be considered equally imposing. Specifically, a location’s OceanJut is defined as h × |sin θ|, where h is how high the location rises above the closest point on the ocean, and θ is the angle of elevation at which the location rises above the closest point on the ocean.
Incredibly, there are places in the world with even more spectacular mountains-meets-ocean scenery, some with over 1.5x the OceanJut of the Molokai Sea Cliffs! You can find where they are on this interactive world map.
This map was created in Google Earth Engine using the 3DEP and MERIT elevation models.
Please let us know in the comments if you have any questions!
A community for discussing local kine things. If you are here for travel advice, please visit /r/VisitingHawaii instead! Questions about moving to Hawaii? You can read our Moving to Hawaii wiki. Please visit /r/movingtohawaii to ask your questions.
DataIsBeautiful is for visualizations that effectively convey information. Aesthetics are an important part of information visualization, but pretty pictures are not the sole aim of this subreddit.
Ahh great question! I color in all points for which angle of elevation is positive when you're looking towards it from the nearest coastal location, factoring in Earth's curvature. Keep in mind that if something is too far away, it will dip below your horizon due to curvature. You definitely can't see Mount Shasta from the ocean due to obstructing mountains in front. But if those mountains were removed, you would be able to look standing at the ocean at a slightly upwards angle to see the summit.
Ah, good point! I should mention, I color in all points for which the angle of elevation is positive when viewed from the ocean, factoring in Earth's curvature. So theoretically, if your eye level was at sea level, you would still be looking slightly upwards to see Mount Shasta, if no coastal mountains blocked your view.
That's a good question! Given how far a point is from the ocean and how high it rises above it, we can calculate the angle of elevation. If you're asking about how we account for the fluctuation of the waves, I just use the mean sea level :)
The official subreddit for San Diego California, "America's Finest City", we’re a rapidly growing (over 370,000 strong!) community serving the whole of the San Diego. We also serve the various counties, plus info concerning our sister city Tijuana MX in the sharing of information, opinion and events to bring us closer together in the richness & diversity that makes us “America’s finest city” *Please READ our rules before posting*
The official subreddit for San Diego California, "America's Finest City", we’re a rapidly growing (over 370,000 strong!) community serving the whole of the San Diego. We also serve the various counties, plus info concerning our sister city Tijuana MX in the sharing of information, opinion and events to bring us closer together in the richness & diversity that makes us “America’s finest city” *Please READ our rules before posting*
How does the San Diego coast compare in grandeur to the rest of California?
Hahaha! I did not want to dilute the mountaineering focus of r/mountaineering, considering that this post is more beach and travel/tourism oriented. But if there's something especially relevant, I'll post it!
Ah - I should clarify - OceanJut is not the same as height. Rather, it's equal to the height of an equally impressive vertical ocean cliff. So for instance, a vertical ocean cliff of height 100 ft, a point that rises at 45° from the ocean with height 141 ft, and a point that rises 30° from the ocean with height 200 ft will all measure an OceanJut of 100 ft.
This is motivated by the fact that the further away a feature is from the ocean, the less impressively it rises from the ocean.
Good intuition! Mount Pico in the Azores has an OceanJut of 980 meters!
You can actually find it on the interactive map - enjoy!