ActivityPub Viewer

A small tool to view real-world ActivityPub objects as JSON! Enter a URL or username from Mastodon or a similar service below, and we'll send a request with the right Accept header to the server to view the underlying object.

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{ "@context": [ "https://www.w3.org/ns/activitystreams", { "ostatus": "http://ostatus.org#", "atomUri": "ostatus:atomUri", "inReplyToAtomUri": "ostatus:inReplyToAtomUri", "conversation": "ostatus:conversation", "sensitive": "as:sensitive", "toot": "http://joinmastodon.org/ns#", "votersCount": "toot:votersCount", "blurhash": "toot:blurhash", "focalPoint": { "@container": "@list", "@id": "toot:focalPoint" }, "Hashtag": "as:Hashtag" } ], "id": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008", "type": "Note", "summary": null, "inReplyTo": null, "published": "2025-04-15T11:54:37Z", "url": "https://wisskomm.social/@MPI_ScienceOfLight/114341843919547008", "attributedTo": "https://wisskomm.social/users/MPI_ScienceOfLight", "to": [ "https://www.w3.org/ns/activitystreams#Public" ], "cc": [ "https://wisskomm.social/users/MPI_ScienceOfLight/followers", "https://wisskomm.social/users/unihannover" ], "sensitive": false, "atomUri": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008", "inReplyToAtomUri": null, "conversation": "tag:wisskomm.social,2025-04-15:objectId=10088996:objectType=Conversation", "content": "<p>Photonic computing needs more nonlinearity — <a href=\"https://wisskomm.social/tags/acoustics\" class=\"mention hashtag\" rel=\"tag\">#<span>acoustics</span></a> can help</p><p>Researchers from <a href=\"https://wisskomm.social/tags/MPL\" class=\"mention hashtag\" rel=\"tag\">#<span>MPL</span></a>, <span class=\"h-card\" translate=\"no\"><a href=\"https://wisskomm.social/@unihannover\" class=\"u-url mention\">@<span>unihannover</span></a></span> &amp; <a href=\"https://wisskomm.social/tags/MIT\" class=\"mention hashtag\" rel=\"tag\">#<span>MIT</span></a> demonstrate an all-optically controlled activation function using traveling sound waves. This optoacoustic approach enables nonlinear signal processing in the synthetic frequency dimension and could pave the way for more efficient, scalable optical neural networks — compact, fast, and energy-saving.</p><p>Read more 👉 <br /><a href=\"https://mpl.mpg.de/news/article/photonic-computing-needs-more-nonlinearity-acoustics-can-help\" target=\"_blank\" rel=\"nofollow noopener noreferrer\" translate=\"no\"><span class=\"invisible\">https://</span><span class=\"ellipsis\">mpl.mpg.de/news/article/photon</span><span class=\"invisible\">ic-computing-needs-more-nonlinearity-acoustics-can-help</span></a></p><p>📸 © Grigorii Slinkov</p>", "contentMap": { "de": "<p>Photonic computing needs more nonlinearity — <a href=\"https://wisskomm.social/tags/acoustics\" class=\"mention hashtag\" rel=\"tag\">#<span>acoustics</span></a> can help</p><p>Researchers from <a href=\"https://wisskomm.social/tags/MPL\" class=\"mention hashtag\" rel=\"tag\">#<span>MPL</span></a>, <span class=\"h-card\" translate=\"no\"><a href=\"https://wisskomm.social/@unihannover\" class=\"u-url mention\">@<span>unihannover</span></a></span> &amp; <a href=\"https://wisskomm.social/tags/MIT\" class=\"mention hashtag\" rel=\"tag\">#<span>MIT</span></a> demonstrate an all-optically controlled activation function using traveling sound waves. This optoacoustic approach enables nonlinear signal processing in the synthetic frequency dimension and could pave the way for more efficient, scalable optical neural networks — compact, fast, and energy-saving.</p><p>Read more 👉 <br /><a href=\"https://mpl.mpg.de/news/article/photonic-computing-needs-more-nonlinearity-acoustics-can-help\" target=\"_blank\" rel=\"nofollow noopener noreferrer\" translate=\"no\"><span class=\"invisible\">https://</span><span class=\"ellipsis\">mpl.mpg.de/news/article/photon</span><span class=\"invisible\">ic-computing-needs-more-nonlinearity-acoustics-can-help</span></a></p><p>📸 © Grigorii Slinkov</p>" }, "attachment": [ { "type": "Document", "mediaType": "image/png", "url": "https://wisskomm.social/system/media_attachments/files/114/341/841/736/710/676/original/4ff761f1026f9405.png", "name": "The image shows a schematic representation of how an optoacoustic activation function can be employed in an all-optical multi-frequency neural network.", "blurhash": "UMQvzYWY_3Ri~WNGD*jFR.IUtR%2xtt7RiRk", "focalPoint": [ 0, 0 ], "width": 1391, "height": 706 } ], "tag": [ { "type": "Mention", "href": "https://wisskomm.social/users/unihannover", "name": "@unihannover" }, { "type": "Hashtag", "href": "https://wisskomm.social/tags/acoustics", "name": "#acoustics" }, { "type": "Hashtag", "href": "https://wisskomm.social/tags/mpl", "name": "#mpl" }, { "type": "Hashtag", "href": "https://wisskomm.social/tags/mit", "name": "#mit" } ], "replies": { "id": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008/replies", "type": "Collection", "first": { "type": "CollectionPage", "next": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008/replies?only_other_accounts=true&page=true", "partOf": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008/replies", "items": [] } }, "likes": { "id": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008/likes", "type": "Collection", "totalItems": 7 }, "shares": { "id": "https://wisskomm.social/users/MPI_ScienceOfLight/statuses/114341843919547008/shares", "type": "Collection", "totalItems": 3 } }