{"id":168,"date":"2025-05-19T08:33:11","date_gmt":"2025-05-19T15:33:11","guid":{"rendered":"https:\/\/scienceblog.com\/neuroedge\/?p=168"},"modified":"2025-05-19T08:33:11","modified_gmt":"2025-05-19T15:33:11","slug":"ai-goes-off-grid-this-brain-inspired-chip-runs-without-the-internet","status":"publish","type":"post","link":"https:\/\/scienceblog.com\/neuroedge\/2025\/05\/19\/ai-goes-off-grid-this-brain-inspired-chip-runs-without-the-internet\/","title":{"rendered":"AI Goes Off-Grid: This Brain-Inspired Chip Runs Without the Internet"},"content":{"rendered":"<p>Researchers at the Technical University of Munich (TUM) have developed an innovative AI chip that functions entirely without relying on cloud servers or internet connections. The new processor, <a href=\"https:\/\/ieeexplore.ieee.org\/stamp\/stamp.jsp?tp=&amp;arnumber=10931124\">named AI Pro<\/a>, processes information locally using a brain-inspired design that could revolutionize how AI is deployed in everyday devices while dramatically reducing energy consumption.<\/p>\n<p>Unlike conventional AI chips that send data to remote servers for processing, the AI Pro performs all calculations directly on the device, eliminating privacy concerns while slashing power requirements. The chip achieves up to ten times greater energy efficiency than comparable processors, a critical advantage for battery-powered devices and applications where power is limited.<\/p>\n<p>The breakthrough comes as AI integration accelerates across industries, with many current solutions requiring constant internet connectivity and raising privacy concerns about sensitive data being processed in the cloud. Could this new approach spark a shift toward more secure, self-contained AI systems that keep data local?<\/p>\n<h2>How the Brain-Inspired Chip Works<\/h2>\n<blockquote><p>&#8220;While NVIDIA has built a platform that relies on cloud data and promises to solve every problem, we have developed an AI chip that enables customized solutions. There is a huge market there,&#8221; explains Professor Hussam Amrouch, who leads the Chair of AI Processor Design at TUM.<\/p><\/blockquote>\n<p>The key innovation in the AI Pro is its neuromorphic architecture, which mimics how the human brain processes information. Unlike conventional chips where computing and memory units are separated, the AI Pro integrates them together, significantly improving efficiency.<\/p>\n<p>The chip applies &#8220;hyperdimensional computing&#8221; \u2013 a computational approach that recognizes patterns and similarities rather than requiring massive datasets to learn. This means the chip can make intelligent decisions without the extensive training data needed by most AI systems.<\/p>\n<p>&#8220;Humans also draw inferences and learn through similarities,&#8221; notes Professor Amrouch, explaining the intuitive way the chip processes information.<\/p>\n<h3>Energy Efficiency and Real-World Applications<\/h3>\n<p>In testing, the new chip demonstrated remarkable energy efficiency. For a sample task, the AI Pro consumed just 24 microjoules of energy, while comparable chips required ten to one hundred times more \u2013 &#8220;a record value,&#8221; according to Professor Amrouch.<\/p>\n<p>This efficiency makes the chip ideal for applications like:<\/p>\n<ul>\n<li>Processing health data from wearable devices without sending sensitive information to the cloud<\/li>\n<li>Navigation systems for drones that can function without internet connectivity<\/li>\n<li>IoT devices that need to make intelligent decisions with minimal power<\/li>\n<li>Edge computing in environments where internet access is unreliable or unavailable<\/li>\n<\/ul>\n<p>By processing data locally, the chip also reduces the carbon footprint of AI applications by eliminating the need for energy-intensive server computing and data transfers.<\/p>\n<h2>Security and Privacy Benefits<\/h2>\n<p>Beyond its energy advantages, the AI Pro offers significant security and privacy benefits. Since data never leaves the device, issues with internet connections, cybersecurity vulnerabilities, and data privacy concerns are effectively eliminated.<\/p>\n<p>&#8220;The future belongs to the people who own the hardware,&#8221; Professor Amrouch emphasizes, highlighting how local processing maintains user control over their data.<\/p>\n<p>While the one-square-millimeter chip currently costs around 30,000 euros and has approximately 10 million transistors \u2013 far fewer than NVIDIA&#8217;s chips with 200 billion transistors \u2013 its specialized design makes it highly efficient for specific applications rather than trying to be an all-purpose solution.<\/p>\n<p>The first prototypes have already been produced by semiconductor manufacturer Global Foundries in Dresden, demonstrating the technology&#8217;s viability for real-world production.<\/p>\n<p>As AI continues to integrate into more aspects of daily life, chips like the AI Pro represent a potential shift in how we approach artificial intelligence \u2013 moving from centralized, cloud-based systems to distributed, energy-efficient devices that keep data local and secure while making intelligent decisions at the edge.<\/p>\n","protected":false},"excerpt":{"rendered":"<p>Researchers at the Technical University of Munich (TUM) have developed an innovative AI chip that functions entirely without relying on cloud servers or internet connections. The new processor, named AI Pro, processes information locally using a brain-inspired design that could revolutionize how AI is deployed in everyday devices while dramatically reducing energy consumption. Unlike conventional &#8230; <a title=\"AI Goes Off-Grid: This Brain-Inspired Chip Runs Without the Internet\" class=\"read-more\" href=\"https:\/\/scienceblog.com\/neuroedge\/2025\/05\/19\/ai-goes-off-grid-this-brain-inspired-chip-runs-without-the-internet\/\" aria-label=\"Read more about AI Goes Off-Grid: This Brain-Inspired Chip Runs Without the Internet\">Read more<\/a><\/p>\n","protected":false},"author":1297,"featured_media":169,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_jetpack_newsletter_access":"","_jetpack_dont_email_post_to_subs":false,"_jetpack_newsletter_tier_id":0,"_jetpack_memberships_contains_paywalled_content":false,"_jetpack_memberships_contains_paid_content":false,"footnotes":"","jetpack_post_was_ever_published":false},"categories":[1],"tags":[],"class_list":["post-168","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-uncategorized","generate-columns","tablet-grid-50","mobile-grid-100","grid-parent","grid-50"],"yoast_head":"<!-- This site is optimized with the Yoast SEO Premium plugin v27.7 (Yoast SEO v27.7) - https:\/\/yoast.com\/product\/yoast-seo-premium-wordpress\/ -->\n<title>AI Goes Off-Grid: This Brain-Inspired Chip Runs Without the Internet - NeuroEdge<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/scienceblog.com\/neuroedge\/2025\/05\/19\/ai-goes-off-grid-this-brain-inspired-chip-runs-without-the-internet\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"AI Goes Off-Grid: This Brain-Inspired Chip Runs Without the Internet\" \/>\n<meta property=\"og:description\" content=\"Researchers at the Technical University of Munich (TUM) have developed an innovative AI chip that functions entirely without relying on cloud servers or internet connections. 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Under a dark-field microscope it glows faintly, a grid of tiny crystalline specks arranged with the regularity of pixels on a screen. Each speck is a distinct material, a unique combination of atoms no chemist has ever made in bulk, and\u2026","rel":"","context":"In &quot;Computational Innovation&quot;","block_context":{"text":"Computational Innovation","link":"https:\/\/scienceblog.com\/neuroedge\/category\/computational-innovation\/"},"img":{"alt_text":"Using Second Harmonic Generation Microscopy to map megalibraries of nanoparticles swiftly reveals the location of piezoelectric, optically active non-centrosymmetric perovskites in complex materials spaces.","src":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/05\/megalibrary.jpg?resize=350%2C200&ssl=1","width":350,"height":200,"srcset":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/05\/megalibrary.jpg?resize=350%2C200&ssl=1 1x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/05\/megalibrary.jpg?resize=525%2C300&ssl=1 1.5x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/05\/megalibrary.jpg?resize=700%2C400&ssl=1 2x"},"classes":[]},{"id":339,"url":"https:\/\/scienceblog.com\/neuroedge\/2026\/06\/01\/probe-thinner-than-a-hair-can-now-listen-to-brain-cells-and-boss-them-around-at-the-same-time\/","url_meta":{"origin":168,"position":2},"title":"Probe Thinner Than a Hair Can Now Listen to Brain Cells and Boss Them Around at the Same Time","author":"NeuroEdge","date":"June 1, 2026","format":false,"excerpt":"The thing is narrower than a single human hair, and along its silicon length sit close to a thousand tiny recording points and twenty-eight microscopic windows that spit out light. Slide it into the brain of a mouse and it does two jobs that neuroscientists have, for years, been forced\u2026","rel":"","context":"In &quot;Brain Health&quot;","block_context":{"text":"Brain Health","link":"https:\/\/scienceblog.com\/neuroedge\/category\/brain-health\/"},"img":{"alt_text":"Figure 1. Neuropixels Opto probe design and system architecture. a, Probe Cross-Section: Shows the titanium nitride (TiN) recording sites connected to the silicon CMOS layer, alongside silicon nitride (SiN) waveguides that guide light to the emitters. b, Layout: Placement of the recording sites and two-color light emitters on the probe. c, Emitter Photos: The probe shank with two red and two blue emitters lighting up in sequence. d, Packaging: The fully assembled device package. e, System Architecture: The data system, featuring PXI modules for recording data (white) and controlling light delivery (purple).","src":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/06\/41592_2026_3076_Fig1_HTML.png.webp?resize=350%2C200&ssl=1","width":350,"height":200,"srcset":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/06\/41592_2026_3076_Fig1_HTML.png.webp?resize=350%2C200&ssl=1 1x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/06\/41592_2026_3076_Fig1_HTML.png.webp?resize=525%2C300&ssl=1 1.5x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2026\/06\/41592_2026_3076_Fig1_HTML.png.webp?resize=700%2C400&ssl=1 2x"},"classes":[]},{"id":90,"url":"https:\/\/scienceblog.com\/neuroedge\/2025\/04\/28\/brain-decoder-controls-spinal-cord-stimulation\/","url_meta":{"origin":168,"position":3},"title":"Brain decoder controls spinal cord stimulation","author":"NeuroEdge","date":"April 28, 2025","format":false,"excerpt":"In a significant development for spinal cord injury treatment, researchers at Washington University in St. Louis have created a neural decoder that bridges the communication gap between brain and spine, potentially opening new avenues for rehabilitation. The research team, led by Ismael Se\u00e1\u00f1ez, assistant professor of biomedical engineering at WashU,\u2026","rel":"","context":"In &quot;Computational Innovation&quot;","block_context":{"text":"Computational Innovation","link":"https:\/\/scienceblog.com\/neuroedge\/category\/computational-innovation\/"},"img":{"alt_text":"EEG Cap and walking man","src":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/eeg-cap.jpg?resize=350%2C200&ssl=1","width":350,"height":200,"srcset":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/eeg-cap.jpg?resize=350%2C200&ssl=1 1x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/eeg-cap.jpg?resize=525%2C300&ssl=1 1.5x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/eeg-cap.jpg?resize=700%2C400&ssl=1 2x"},"classes":[]},{"id":273,"url":"https:\/\/scienceblog.com\/neuroedge\/2025\/12\/01\/brain-like-ai-emerges-without-training-data-in-new-study\/","url_meta":{"origin":168,"position":4},"title":"Brain-Like AI Emerges Without Training Data in New Study","author":"NeuroEdge","date":"December 1, 2025","format":false,"excerpt":"Before these systems ever see a single cat photo or traffic sign, some AI models are already humming in tune with the visual cortex. In new work from Johns Hopkins University, scientists showed that carefully designed, biologically inspired architectures can mimic activity in human and primate visual brain areas even\u2026","rel":"","context":"In &quot;Brain Health&quot;","block_context":{"text":"Brain Health","link":"https:\/\/scienceblog.com\/neuroedge\/category\/brain-health\/"},"img":{"alt_text":"circuit-board-brain","src":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/12\/circuit-board-brain.jpg?resize=350%2C200&ssl=1","width":350,"height":200,"srcset":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/12\/circuit-board-brain.jpg?resize=350%2C200&ssl=1 1x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/12\/circuit-board-brain.jpg?resize=525%2C300&ssl=1 1.5x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/12\/circuit-board-brain.jpg?resize=700%2C400&ssl=1 2x"},"classes":[]},{"id":98,"url":"https:\/\/scienceblog.com\/neuroedge\/2025\/04\/29\/ai-blood-test-sniffs-out-hidden-brain-tumors\/","url_meta":{"origin":168,"position":5},"title":"AI Blood Test Sniffs Out Hidden Brain Tumors","author":"NeuroEdge","date":"April 29, 2025","format":false,"excerpt":"A simple blood test may soon catch brain cancers months before symptoms appear, thanks to artificial intelligence that detects previously invisible tumor signals. Johns Hopkins researchers have developed a liquid biopsy technique that identifies brain cancers with unprecedented accuracy, potentially transforming how these deadly tumors are diagnosed. Brain cancer detection\u2026","rel":"","context":"In &quot;Brain Health&quot;","block_context":{"text":"Brain Health","link":"https:\/\/scienceblog.com\/neuroedge\/category\/brain-health\/"},"img":{"alt_text":"Release of cell-free DNA and altered blood cells in patients with cancer.","src":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/ai-liquid-biopsy-brain-tumor.jpg?resize=350%2C200&ssl=1","width":350,"height":200,"srcset":"https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/ai-liquid-biopsy-brain-tumor.jpg?resize=350%2C200&ssl=1 1x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/ai-liquid-biopsy-brain-tumor.jpg?resize=525%2C300&ssl=1 1.5x, https:\/\/i0.wp.com\/scienceblog.com\/neuroedge\/wp-content\/uploads\/sites\/14\/2025\/04\/ai-liquid-biopsy-brain-tumor.jpg?resize=700%2C400&ssl=1 2x"},"classes":[]}],"_links":{"self":[{"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/posts\/168","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/users\/1297"}],"replies":[{"embeddable":true,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/comments?post=168"}],"version-history":[{"count":1,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/posts\/168\/revisions"}],"predecessor-version":[{"id":170,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/posts\/168\/revisions\/170"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/media\/169"}],"wp:attachment":[{"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/media?parent=168"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/categories?post=168"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/scienceblog.com\/neuroedge\/wp-json\/wp\/v2\/tags?post=168"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}