Rads to Watts: Darpa erforscht Nuklearbatterien aus Atommüll
Das US-Militärprojekt Rads to Watts untersucht kompakte Mini-Generatoren aus Strontium-90 für Drohnen und Satelliten. (Energie, Darpa)
Quelle: Golem
Das US-Militärprojekt Rads to Watts untersucht kompakte Mini-Generatoren aus Strontium-90 für Drohnen und Satelliten. (Energie, Darpa)
Quelle: Golem
Im Schatten des Flipper One wurde die Firmware-Entwicklung des Flipper Zero gestoppt. Nach einem Aufschrei der Community geht es nun aber weiter. (Flipper Zero, Firmware)
Quelle: Golem
Rüstungsunternehmen suchen Softwareentwickler. Die Jobs wirken oft gewöhnlich, doch ihr Code kann Panzer, Drohnen oder Sensorik einsatzfähig machen. Ein Bericht von Oliver Jessner (Militär, Softwareentwicklung)
Quelle: Golem
Einige Fahrassistenzsysteme verringern Unfallschäden merklich. Viele Autofahrer schalten sie ab – weil die Systeme zu aggressiv sind. (Auto, Security)
Quelle: Golem
Der elektrische Schraubendreher mit 16 Bits und 2.000 mAh Akku plus Alu-Case ist jetzt zum reduzierten Amazon-Preis verfügbar. (Technik/Hardware, Amazon)
Quelle: Golem
Einem ehemaligen Microsoft-Entwickler gefällt der Bloat im aktuellen Notepad nicht. Deshalb hat er eine sehr kompakte Alternative entwickelt. (Editor, Windows)
Quelle: Golem
Microsoft hat die Surface-Go-Reihe offenbar eingestellt. Die Tablets und Laptops waren vor allem wegen ihres geringen Preises beliebt. (Surface, Microsoft)
Quelle: Golem
Das Auktionshaus geht davon aus, dass die handsignierte Jacke des Nvidia-CEOs für mehr als 40.000 Euro verkauft wird. (Nvidia, Wirtschaft)
Quelle: Golem
A Manifesto for Organizational Intelligence That SurvivesA Different QuestionFor centuries, humanity has asked a single question:How do we preserve knowledge?We built libraries. We built archives. We built databases. We built clouds.And yet knowledge continues to disappear.Engineers retire. Teams reorganize. Projects are abandoned. Companies are acquired. Entire decades of hard-won experience vanish with the people who created it.The problem is not storage.The problem is continuity.Infrastructure Can Already Heal ItselfWe have been building self-healing digital infrastructure with OpenKubes.Git stores the desired state. Kubernetes reconciles reality back to that state. Servers fail. Clusters disappear. Entire environments get rebuilt from scratch — automatically, without human intervention.Infrastructure survives because it remembers what it should be.We call this the Immortal Platform.Git is the contract.Kubernetes is the enforcer.Target recovery time: under ten minutes. No runbook. No 3am call. No tribal knowledge required.When we built this, we thought we were solving an infrastructure problem.We were actually solving the beginning of a much larger problem.What About Intelligence?Organizations face a different kind of failure — one that no monitoring system detects, no alert fires for, and no on-call engineer gets paged about.The slow disappearance of organizational intelligence.What happens when the engineer who designed the system retires?Who remembers why that architectural decision was made in 2019?Who remembers the three failed approaches before the solution that worked?Who remembers the lessons from the production incident that took down the factory floor for six hours?Most organizations have no answer.Their infrastructure is documented. Their intelligence is not.We have spent ten years building and operating Kubernetes platforms across automotive plants, financial institutions, industrial facilities, and government agencies. We have seen the same pattern repeat itself dozens of times: a new team inherits a platform built by people who are no longer there. They spend months — sometimes years — reverse-engineering decisions that took the original team weeks to make. They repeat mistakes that were already made and documented somewhere no one can find. They abandon patterns that worked because nobody explained why they were there.The cost is not just time. It is confidence. Every inherited system that lacks its original context becomes a system nobody fully trusts, nobody fully understands, and nobody wants to touch.This is not a technology problem. This is a memory problem.The Immortal MindOpenKubes AI begins with a simple idea:Knowledge should be as durable as infrastructure.The founding principle of OpenKubes is that the platform owns contracts, not components. Infrastructure components come and go — the contracts they fulfill persist. The Immortal Mind extends that same principle to knowledge: decisions, context, and lessons are contracts too. Individual people, teams, and documents come and go — the organizational intelligence they carry must persist.If we can build infrastructure that heals itself — that reads a desired state from Git, reconciles toward it, and recovers from failure without human intervention — then we can build intelligence systems that do the same.Not storing documents in a folder that nobody reads.Not writing runbooks that become outdated before the ink dries.But genuinely living knowledge — continuously updated, continuously reconciled, continuously connected to the systems and decisions it describes.Just as Kubernetes reconciles infrastructure to its desired state, future AI systems can continuously reconcile organizational knowledge to its current reality.Git is the contract.Kubernetes is the enforcer.AI is the memory.To be precise about what we mean: the memory itself does not live inside a model. It lives in Git, in architecture decision records, in the knowledge graph, and in the context that evolves with the platform. AI is what connects, understands, and makes that memory accessible. Models will come and go. The organizational memory must endure.The Architecture of Organizational ImmortalityOpenKubes AI envisions four foundational layers — not as a product announcement, but as an architectural direction:Layer 1: Knowledge GraphA structured, living representation of organizational knowledge.People. Systems. Projects. Decisions. Failures. Lessons. Relationships. Dependencies. Evolution.Not a static diagram. A continuously updated graph that reflects the current state of the organization and its history — connected to the actual infrastructure it describes.When a cluster is deployed, the knowledge graph knows why. When an architectural decision is made, it is captured — not in a document folder nobody will find, but in a structured, queryable, AI-accessible form.Not a mockup: the OpenKubes knowledge graph, extracted from Git by a 200-line script — every decision, component, and commit, connected.Explore the interactive version: https://kubernauts.de/en/openkubes/openkubes_knowledge_graph_force_layout.htmlLayer 2: Context StoreGitOps for knowledge.Architecture decision records. Runbooks. Postmortem analyses. Design rationale. Lessons learned. Every significant decision — versioned, auditable, and connected to the code and infrastructure it influenced.Not documentation as an afterthought. Documentation as infrastructure — with the same discipline, the same tooling, the same lifecycle.When you git blame a Kubernetes manifest, you can trace it back to the incident that caused it. When you ask why a system is designed the way it is, the answer is a git log away.This is not theory. It is how OpenKubes is already built: every architectural decision lives as a versioned ADR in the platform repository, and every deviation from upstream in our deployment guides is recorded with its reason and its operational impact. The Context Store simply makes that discipline queryable — and permanent.Layer 3: Model RuntimeOpen AI runtimes deployed anywhere — on the same infrastructure that runs your workloads.Cloud. Edge. Air-gapped factory floors. Sovereign government infrastructure.The intelligence follows the workload. Not locked in a vendor’s cloud. Not dependent on an external API that may change, disappear, or become unavailable in an air-gapped facility.The same platform engineering principles that make OpenKubes infrastructure sovereign make OpenKubes AI intelligence sovereign.Layer 4: Immortal Platform IntegrationThe platform heals itself. The intelligence remembers itself. The system continuously rebuilds both.When a cluster fails and is reprovisioned on fresh bare metal, the AI layer knows the history of that cluster — every deployment, every incident, every change. The infrastructure is new. The memory is intact.Beyond AutomationIt is important to say clearly what this is not.This is not a vision of autonomous machines replacing human engineers.This is not digital immortality for individuals.This is not artificial general intelligence.This is preservation of organizational intelligence.A future where critical knowledge no longer disappears when individuals leave.A future where the organization remembers — not just what it built, but why it built it.The engineer retires. The knowledge stays.The team disbands. The context remains.The company is acquired. The intelligence survives.Why This Matters for Industrial SystemsIn a factory, a hospital, a power grid, or a government agency — the stakes of lost knowledge are not measured in developer productivity.They are measured in production downtime, patient safety, grid stability, and national security.We have seen what happens when a factory floor loses the engineer who understood the control system. We have seen what happens when a hospital’s IT team inherits infrastructure nobody documented. We have seen what happens when a critical system needs to be rebuilt and nobody remembers the original architecture rationale.The infrastructure survived. The intelligence did not. The consequences were real.This is why OpenKubes AI is not a feature.It is a responsibility.The Complete VisionWhen we look at where OpenKubes is going, we see a platform designed not merely for uptime — but for continuity:OpenKubes IMP → Infrastructure survivesOpenKubes AI → Knowledge survivesOpenKubes Robotics → Actions surviveThe Robotics layer is not hypothetical. Open-RMF — the open robotics middleware framework for fleet management, traffic coordination, task dispatching, and simulation — runs today as a reference robotics workload on the OpenKubes platform, deployed through the same GitOps-based operational model as everything else, consistently across local, edge, bare-metal, and public cloud environments.Together these layers form something that has never existed before:A platform where systems, knowledge, and actions persist — regardless of hardware failures, software updates, team changes, or the passage of time.Infrastructure that heals itself. Intelligence that remembers itself. Systems that evolve themselves.An InvitationThis manifesto is not a product announcement.It is a direction.OpenKubes AI does not exist yet as a shipping product. But the architectural foundation does — in the Git repositories, the Crossplane compositions, the Cluster API providers, the running robotics reference workload, and the knowledge accumulated across ten years of building and operating critical Kubernetes infrastructure.The Immortal Mind is where that foundation leads.If you are building systems that cannot afford to forget — factory automation platforms, critical infrastructure, sovereign AI systems, industrial knowledge management — we want to build this with you.Not for you. With you.Because the most important knowledge to preserve is the knowledge we build together.Git is the contract. Kubernetes is the enforcer. AI is the memory.Together, they create systems that do not merely survive failure. They learn from it.???? github.com/openkubes/openkubes ???? OpenKubes Platform Presentation ???? blog.kubernauts.io ???? OpenKubes Roadmap: OK-30 Immortal PlatformArash Kaffamanesh is the founder of Clouds Sky GmbH & Kubernauts GmbH and has been building and operating Kubernetes platforms for over ten years across automotive, industrial, financial, and healthcare environments. He is the creator of OpenKubes — the open platform for self-healing sovereign Kubernetes infrastructure.The Immortal Mind was originally published in Kubernauts on Medium, where people are continuing the conversation by highlighting and responding to this story.
Quelle: blog.kubernauts.io
A couple of months ago, I sat across from my nine-year-old daughter’s teachers at a parent-teacher conference. They were kind but concerned. She takes her time on assignments, they said—often deep in thought. How would she do on timed tests next year? I told them I wasn’t worried. What they described as a problem is, to me, one of the most important things she can learn: the ability to take a hard problem and reason through it from beginning to end. In a world optimized for efficiency, qualities like patience, perseverance, and attention to detail are not deficiencies. They are the foundation of sound judgment, which will become the skills we need most.
The more time I spend working with AI, the more convinced I become: the question that matters for her future isn’t how quickly she can answer. It’s whether she has the judgment to know when an answer can be trusted.
I’ve spent decades at Microsoft watching this tension play out: first building tools for other developers, then working across AI as models moved from research curiosities to systems deployed at scale. Now we’re building Microsoft IQ, where we’re exploring how an organization’s collective intelligence can become its greatest advantage. Through every one of those chapters, one thing has remained true: it’s never enough for a system to be powerful, it must also be trustworthy.
Trust is what turns assistance into delegation. When we can trust an agent to do what we intend, within the limits we set, we can hand off the work we never wanted to spend our lives on: the repetitive tasks that drain attention, the mundane work that fills a day without moving anything meaningful forward, the dangerous work humans should not have to do, the work too vast for any individual or team. Agents should take on that toil, extend our reach, and give us back our time for the work that calls for something only humans bring.
My daughter doesn’t know any of this yet. But by the time she’s grown, most of the work that rewards speed and repetition will be work we delegate. What will matter then is exactly what gave her teachers pause: the patience to stay with a hard problem, reason through it, and decide when she’s reached a conclusion she can trust. The very thing they feared might hold her back could be exactly what the next era prizes most.
So no, I’m not worried about the timed test. I hope she grows up in a world where software carries the toil and people are freed for the work that is unmistakably ours—to think, to judge, to create, to care for one another. That is the future I want agents to make real.
But my hope is not evidence it will happen. The future I just described turns on a single question: can we trust agents to do the work? Trust is earned one task at a time. So, I went looking for evidence of where it’s been earned, and where it hasn’t.
For the past year, the conversation around AI agents has circled the same promise: eliminate toil so people can focus on what matters. But I keep coming back to sharper questions. What, exactly, is toilsome? Where does toil actually live in people’s work? What are the technical leaders closest to this shift willing to hand off—and what gives them the confidence to do it? To find out, we partnered with MIT Technology Review Insights on new research that draws directly from the people building this frontier. Not the people talking about it, the people doing it. We surveyed 300 technical experts across AI, data, and cloud domains, spanning 12 industries and 4 regions of the world, asking them to rank their confidence across 101 of the top tasks. What we got back is the 2026 Agent Confidence Index, an honest map of where agents are delivering real value, so our community can see what’s working and move forward together with conviction.
Explore the 2026 Agent Confidence Index report
Learn from where confidence is highest
Across the 101 tasks measured, average confidence already lands at 64 out of 100, and thirty tasks clear 70. The highest scores cluster on work that is both predictable and draining: the late nights, the interruptions, the low-value repetition. Automated report generation leads at 83.5. Boilerplate code generation for new features sits at 82.5, the hours a developer no longer spends rewriting the same patterns, freed for the work that challenges them. Certificate expiration monitoring and renewal, at 81.5, ends the scramble that pulls engineers off high-stakes problems for something entirely routine. Real-time data stream monitoring follows at 80.5, and release note generation from commit history at 79.5, the manual end-of-sprint commit review, gone. This is where frontier teams are already delegating to agents, regularly.
The pattern holds across every discipline. In developer and AI workflows it extends to API client maintenance and code identification; in cloud operations, to ticket routing and cost optimization; in data, to anomaly detection. Wherever it sits in the stack, this is work technical teams now trust agents to own.
What matters most here isn’t what the data says about the tasks, it’s what it says about the people delegating them. When technical experts believe in something deeply enough to hand it real work, that belief ripples outward. It becomes the recommendation they make to their leadership, the solution they build for their customers, and the culture they create for their teams.
Even the toughest agent tasks are gaining traction
Here’s what strikes me most: the tasks ranked lower on the index are still high in absolute terms. Service mesh configuration and troubleshooting sits at 37.5, database schema migration scripting at 46.5, memory leak detection at 48.5. These sit at the very frontier, the interconnected, high-stakes work where investment and innovation are concentrated right now.
Consider what they demand. Service mesh configuration touches many systems at once. Database migration carries real stakes, requiring precision across data, application, and infrastructure layers at the same time. Memory leak detection means diving deep into a system’s behavior under load, accounting for conditions that shift from one deployment to the next. These are the challenges that have separated great engineers from exceptional ones—and even here, experts see agents helping. Not carrying the work alone, but contributing where it used to be unthinkable. That confidence is still climbing, and that’s telling.
We’re shipping new capabilities constantly to support this momentum. Database migration tooling in GitHub Copilot now covers not just scripts but the full application and infrastructure migration story. The Azure Site Reliability Engineering (SRE) Agent brings decades of experience operating Azure at scale and deep profiling capabilities directly into memory analysis and performance diagnosis.
Why human judgment remains paramount
When we asked technical experts how they’re navigating agent adoption, 59% named “keeping humans in the loop” as their top priority—ahead of better observability, ahead of governance documentation, and ahead of everything else. That’s a mark of maturity. Teams moving forward with clarity treat agent oversight as non-negotiable, regardless of how capabilities evolve.
The boundary itself is straightforward. Agents excel at well-specified, high-volume, reversible work: they synthesize data, automate known workflows, and surface anomalies at a speed and scale no human team could match. The moment a decision becomes high-stakes, context-dependent, or hard to undo, a human signs off. That isn’t a limitation of the technology, it’s the architecture of a trustworthy system.
What’s changing, and what remains underappreciated, is the skill it takes to draw that boundary well: the discipline of full-lifecycle evaluations and guardrails. Success means measuring agent output against intent and keeping behavior inside your business strategy. It’s new territory for most engineering teams, and it’s becoming table stakes for modern software faster than most organizations realize. The good news: the same tools generating the work can help you build the harness. Ask GitHub Copilot to write the evals and it will. Frontier teams are already doing this, and it’s why they’re pulling ahead.
Agents are opening career doors for engineering
Across system reliability and site operations, evaluations and quality assurance, and data pipeline management, 80% or more of respondents see meaningful career opportunity ahead. We believe this is one of the most significant moments in the history of building software, not because agents replace what technical people do, but because what’s left when they take on the toil is the work that defines a career: the judgment calls, the architectural vision, the reasoning to navigate complexity under pressure. That fluency will define the next generation of technical leadership.
We’re living this shift at Microsoft, right alongside our customers. Junior developers are using agents to explore codebases on their own and arriving at mentoring conversations with sharper, more sophisticated questions. Senior engineers are covering more ground because the repetitive work that used to fill their days is now delegated, and the work that’s left is harder, more interesting, and more consequential. Both are growing into more capable versions of themselves. For me, that’s the outcome I’ve always believed technology could deliver.
An integrated approach to intelligence and trust
Designing more sophisticated agent systems has made one thing clear: agents thrive in well-integrated environments, working best when your whole stack draws on a single source of truth. The high-confidence tasks are the ones we’ve already figured out; the meaningful frontier is the harder, interconnected work, and that’s exactly where observability, governance, security, and unified intelligence have to operate as one.
Microsoft IQ brings your enterprise context into a single, continuous intelligence layer. Within it, Work IQ builds semantic understanding of how your business operates across email, calendar, meetings, chats, files, people, and collaboration patterns. Such depth of knowledge is the reason technical teams choose us and it’s what drives my focus and passion in learning how people actually work so their agents get them. My colleague Kim Manis, CVP of Product for Microsoft Fabric, has written specifically about what this means for data professionals, and the integral role of Fabric IQ.
It’s all part of the Microsoft Agent Platform, which is becoming the operating system for enterprise AI at scale. From building in GitHub and contextualizing with Microsoft IQ, to running in Microsoft Foundry and governing in Microsoft Agent 365, Microsoft is uniquely positioned to help customers bring together data, models, agents, and human judgment into a continuously improving and secure system.
Frontier transformation is being led by builders like you.
Next steps:
Download The 2026 Agent Confidence Index from our partners at MIT Technology Review Insights.It is a free, ungated deep dive into all 101 tasks, broken out by role and workflow, with the patterns and reasoning behind where confidence is strongest and the frontier is expanding.
Join us at the AI Engineering World’s Fair (June 29-July 2) where our very own Pablo Castro will keynote, and our teams will offer 16 breakout sessions and 4 labs. Swing by the Microsoft booth as well to explore an interactive 3D visualization of the Index data. We want to hear what’s working for you right now.
Learn more about Microsoft IQ and how it connects across Work IQ, Fabirc IQ, Foundry IQ, and the newly announced Web IQ. You can catch up on all the developer innovation from Microsoft Build through Satya Nadella’s keynote, Kyle Daigle’s blog post, and the Microsoft Build CLI.
What’s Working in Agentic AI
The 2026 Agent Confidence Index report reveals where agents are trusted, the challenges they face, and what leaders should do next
Download the 2026 Agent Confidence Index report
The post The 2026 Agent Confidence Index: Where 300 builders see real momentum appeared first on Microsoft Azure Blog.
Quelle: Azure