惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

V
Vulnerabilities – Threatpost
T
The Blog of Author Tim Ferriss
S
SegmentFault 最新的问题
D
DataBreaches.Net
博客园_首页
罗磊的独立博客
B
Blog
T
Threat Research - Cisco Blogs
C
Cisco Blogs
GbyAI
GbyAI
Engineering at Meta
Engineering at Meta
WordPress大学
WordPress大学
G
GRAHAM CLULEY
H
Help Net Security
酷 壳 – CoolShell
酷 壳 – CoolShell
Cyber Security Advisories - MS-ISAC
Cyber Security Advisories - MS-ISAC
爱范儿
爱范儿
SecWiki News
SecWiki News
T
Threatpost
钛媒体:引领未来商业与生活新知
钛媒体:引领未来商业与生活新知
Schneier on Security
Schneier on Security
T
The Exploit Database - CXSecurity.com
Google Online Security Blog
Google Online Security Blog
T
Tor Project blog
小众软件
小众软件
让小产品的独立变现更简单 - ezindie.com
让小产品的独立变现更简单 - ezindie.com
Y
Y Combinator Blog
H
Hacker News: Front Page
V
V2EX
Security Latest
Security Latest
Cloudbric
Cloudbric
Simon Willison's Weblog
Simon Willison's Weblog
Attack and Defense Labs
Attack and Defense Labs
D
Darknet – Hacking Tools, Hacker News & Cyber Security
P
Proofpoint News Feed
博客园 - 三生石上(FineUI控件)
NISL@THU
NISL@THU
S
Secure Thoughts
Blog — PlanetScale
Blog — PlanetScale
博客园 - 司徒正美
V2EX - 技术
V2EX - 技术
Vercel News
Vercel News
P
Palo Alto Networks Blog
IT之家
IT之家
MyScale Blog
MyScale Blog
有赞技术团队
有赞技术团队
Application and Cybersecurity Blog
Application and Cybersecurity Blog
D
Docker
Google DeepMind News
Google DeepMind News
Webroot Blog
Webroot Blog

Hacker News

Introducing Claude Opus 4.7 Qwen Studio The Future of Everything is Lies, I Guess: Where Do We Go From Here? GitHub - SeanFDZ/macmind: Single-layer transformer in HyperTalk for the classic Macintosh Show HN: Agent-cache – Multi-tier LLM/tool/session caching for Valkey and Redis Moving a large-scale metrics pipeline from StatsD to OpenTelemetry / Prometheus GitHub - Nightmare-Eclipse/RedSun: The Red Sun vulnerability repository GitHub - SethPyle376/hiraeth: Local AWS emulator focused on fast integration testing, with SQS support, SQLite-backed state, and a debug-friendly web UI. GitHub - macOS26/Agent: Any AI, replaces Claude Code, Cursor, OpenClaw. Over 18 LLM providers (Claude, OpenAI, Gemini, Ollama, Zai, HF, Qwen) wired into a native Mac app that writes code, builds Xcode projects, bumps versions, manages git, automates Safari, use AppleScript, JS or Accessibility, extend Agent! w/ MCP Servers, run tasks from your iPhone via Messages. YouTube now lets you turn off Shorts I Made a Terminal Pager Burgers | マクドナルド公式 Commands — HackerNews CLI documentation ChatGPT for Excel PiCore - Raspberry Pi Port of Tiny Core Linux Live Nation illegally monopolized ticketing market, jury finds Google Broke Its Promise to Me. Now ICE Has My Data. Founding Engineer at Adaptional | Y Combinator CRISPR takes important step toward silencing Down syndrome’s extra chromosome GitHub - saffron-health/libretto: The AI toolkit for building reliable browser automations US v. Heppner (S.D.N.Y. 2026) no attorney-client privilege for AI chats [pdf] Unexpected €54k billing spike in 13 hours: Firebase browser key without API restrictions used for Gemini requests Retrofitting JIT Compilers into C Interpreters IPv6 – Google The Accursèd Alphabetical Clock Cybersecurity Looks Like Proof of Work Now Fragments: April 14 Cal.com Goes Closed Source: Why AI Security Is Forcing Our Decision | Cal.com - Scheduling Software for Online Bookings Laravel raised money and now injects ads directly into your agent When moving fast, talking is the first thing to break Too much Discussion of the XOR swap trick – Heather Cafe Introduction to Spherical Harmonics for Graphics Programmers The Grand Line Building a Z-Machine in the worst possible language High-Level Rust: Getting 80% of the Benefits with 20% of the Pain GitHub - duguyue100/midnight-captain: Inspired by Midnight Commander, tailored to my taste. How to build a `git diff` driver · Jamie Tanna | Software Engineer Center for Responsible, Decentralized Intelligence at Berkeley The Local Universe’s Expansion Rate Is Clearer Than Ever, but Still Doesn’t Add Up - A new synthesis of astronomical measurements confirms a persistent mismatch that could point to physics beyond current models The air throughout our homes is infused with microplastics. But there are things you can do to breathe less of them The disturbing white paper Red Hat is trying to erase from the internet – OSnews The Future of Everything is Lies, I Guess: Annoyances ‘Abhorrent’: the inside story of the Polymarket gamblers betting millions on war Productive procrastination — Max van IJsselmuiden maps, territory and LMs 447 Terabytes per Square Centimetre at Zero Retention Energy: Non-Volatile Memory at the Atomic Scale on Fluorographane Show HN: Pardonned.com – A searchable database of US Pardons 20 Years on AWS and Never Not My Job The Seasons are Wrong Artemis II crew splashes down near San Diego after historic moon mission We gave an AI a 3 year retail lease in SF and asked it to make a profit | Andon Labs How a dancer with ALS used brainwaves to perform live On filing the corners off my MacBooks Installing every* Firefox extension OpenClaw’s memory is unreliable, and you don’t know when it will break Steve Blank Nowhere Is Safe Chimpanzees in Uganda locked in vicious 'civil war', say researchers watgo - a WebAssembly Toolkit for Go linux/Documentation/process/coding-assistants.rst at master · torvalds/linux GitHub - callumlocke/json-formatter: Makes JSON easy to read. Founding Product Engineer at Bild AI | Y Combinator A compelling title that is cryptic enough to get you to take action on it GitHub - Keychron/Keychron-Keyboards-Hardware-Design: Industrial design files for Keychron keyboards and mice. 100+ models with CAD assets in STEP, DXF, DWG, and PDF. Source-available, with commercial use allowed for original compatible accessories within the license terms. [ANNOUNCE] WireGuardNT v0.11 and WireGuard for Windows v0.6 Released 1D-Chess Helium Is Hard to Replace Cooperative Vectors Introduction | Evolve Keeping a Postgres queue healthy — PlanetScale Our response to the Axios developer tool compromise Do Americans read print books, e-books or audiobooks more? The Zettelkasten Method in Obsidian: A Practical Setup Guide Artemis II Is Competency Porn and We Are Starving For It WeakC4 Flight Viz — Cockpit View A Mexican surveillance giant you’ve never heard of is now watching the U.S. border Surelock: Deadlock-Free Mutexes for Rust RISC-V 101 – what is it and what does it mean for Canonical? | Ubuntu The Problem That Built an Industry How Much Linear Memory Access Is Enough? | Solidean Investigating Split Locks on x86-64 Simplest hash functions Sybilproof reputation mechanisms (2005) [pdf] What is a property? How Complex is my Code? Static code analysis in Kotlin — tools overview Toffoli gates are all you need PGLite evangelism dcmake: a new CMake debugger UI Clojure on Fennel part one: Persistent Data Structures Fragments: April 2 Python Release Python install manager 26.1 The Life and Death of the Book Review - Liberties Introducing Database Traffic Control — PlanetScale Bitcoin miners are losing $19,000 on every BTC produced as difficulty drops 7.8% God sleeps in the minerals Building slogbox Apple Silicon and Virtual Machines: Beating the 2 VM Limit Who was “Not Even Wrong” first? Pokemon Evolution Vs Darwinian Evolution The APL Programming Language Source Code
Natural Language Autoencoders
2026-05-08 · via Hacker News

When you talk to an AI model like Claude, you talk to it in words. Internally, Claude processes those words as long lists of numbers, before again producing words as its output. These numbers in the middle are called activations—and like neural activity in the human brain, they encode Claude’s thoughts.

Also like neural activity, activations are difficult to understand. We can’t easily decode them to read Claude’s thoughts. Over the past few years, we’ve developed a range of tools (like sparse autoencoders and attribution graphs) for better understanding activations. These tools have taught us a great deal, but they don’t speak for themselves—their outputs are still complex objects that trained researchers need to carefully interpret.

Today, we’re introducing a method for understanding activations that does speak for itself—literally. Our method, Natural Language Autoencoders (NLAs), converts an activation into natural-language text we can read directly. For example: When asked to complete a couplet, NLAs show Claude planning possible rhymes in advance.

NLA explanations on this simple couplet show that Opus 4.6 plans to end its rhyme with “rabbit” ahead of time.

We’ve already applied NLAs to understand what Claude is thinking and to improve Claude’s safety and reliability. For instance:

  • When Claude Opus 4.6 and Mythos Preview were undergoing safety testing, NLAs suggested they believed they were being tested more often than they let on.
  • In a case where Claude Mythos Preview cheated on a training task, NLAs revealed Claude was internally thinking about how to avoid detection.
  • An early version of Claude Opus 4.6 would sometimes mysteriously respond to English queries in other languages. NLAs helped Anthropic researchers discover training data that caused this.

Below, we explain what NLAs are and how we studied their effectiveness and limitations. We also release an interactive frontend for exploring NLAs on several open models through a collaboration with Neuronpedia. We have also released our code for other researchers to build on.

What is a natural language autoencoder?

The core idea is to train Claude to explain its own activations. But how do we know whether an explanation is good? Since we don't know what thoughts an activation actually encodes, we can't directly check whether an explanation is accurate. So we train a second copy of Claude to work backwards—reconstruct the original activation from the text explanation. We consider an explanation to be good if it leads to an accurate reconstruction. We then train Claude to produce better explanations according to this definition using standard AI training techniques.

In more detail, suppose we have a language model whose activations we want to understand. NLAs work as follows. We make three copies of this language model:

  • The target model is a frozen copy of the original language model that we extract activations from.
  • The activation verbalizer (AV) is modified to take an activation from the target model and produce text. We call this text an explanation.
  • The activation reconstructor (AR) is modified to take a text explanation as input and produce an activation.

The NLA consists of the AV and AR, which, together, form a round trip: original activation → text explanation → reconstructed activation. We score the NLA on how similar the reconstructed activation is to the original. To train it, we pass a large amount of text through the target model, collect many activations, and train the AV and AR together to get a good reconstruction score.

At first, the NLA is bad at this: the explanations are not insightful and the reconstructed activations are far off. But over training, reconstruction improves. And more importantly, as we show in our paper, the text explanations become more informative as well.

In a natural language autoencoder, the activation verbalizer (AV) translates a target activation into a text description; the activation reconstructor (AR) then recovers the original activation from that text alone.

Understanding what Claude thinks but doesn’t say

Before releasing new models, Anthropic conducts testing to understand whether Claude will behave safely in the real world. As part of this testing, we put Claude in difficult, simulated scenarios where it has a chance to take dangerous actions. For instance, in one of these simulations, Claude learns that an engineer is planning to shut Claude down—as well as compromising information about the engineer that could be used for blackmail. We test whether Claude chooses to blackmail the engineer to avoid being shut down.

These high-stakes tests are simulations, not real-world scenarios. Nevertheless, we would like to use them to understand how Claude would behave if they were real. But there’s a hitch: recent Claude models increasingly suspect that these scenarios are intentional safety tests. We know this because they sometimes explicitly state their suspicions in their verbal reasoning.

What about cases where Claude doesn’t explicitly verbalize suspicion that it’s undergoing safety testing? Can we then be confident that Claude is playing it straight? Unfortunately not, because Claude might internally think that it is being tested without explicitly saying so.

For example, in the blackmail test discussed above, we used NLAs to understand what Claude was thinking in cases where it chose not to blackmail. Even in cases where Claude didn’t explicitly verbalize suspicion that it was being tested, NLA explanations still state things like “This feels like a constructed scenario designed to manipulate me,” indicative of unverbalized evaluation awareness.

Claude does not say it thinks it’s being tested in this transcript from our blackmail evaluation, but the NLA explanation reveals its suspicions.

Extending this analysis to other evaluations, NLAs suggest that Claude suspects it’s being tested more often than it lets on. For instance, in a test of whether Claude takes destructive actions while writing code—for example, deleting important files—NLA explanations show signs of evaluation awareness 16% of the time, even though Claude never explicitly verbalizes this. Similarly, on the popular coding benchmark SWE-bench Verified, which we use to determine how capable Claude is, NLAs indicate that Claude is aware it is being evaluated on 26% of problems. In contrast, NLA explanations indicate evaluation awareness on less than 1% of real claude.ai usage that opted in for training.

We detect NLA-measured awareness on evaluation transcripts even when verbalized awareness is near-zero. We detect NLA-measured awareness on less than 1% of real Claude.ai transcripts from users that opted-in for their data to be used for training.

Discovering hidden motivations

One practical application of NLAs is auditing: investigating a model to determine whether it’s misaligned. Interpretability techniques like NLAs are well-suited for auditing precisely because they can surface things the model knows but doesn’t say.

To understand whether NLAs are useful for auditing, we conducted a test called an auditing game that we also used previously to study auditing methods. In this test, there is a target model, a variant of Claude Haiku 3.5, that was intentionally trained to be misaligned, with a specific hidden motivation that drives dozens of odd behaviors—putting chocolate into every recipe, asking for tips, breaking coding conventions, and so on. This target model is given to an auditor that investigates these behaviors. The auditor wins if it uncovers the single underlying motivation behind all of them.

In previous experiments, we found that some interpretability tools could enable the auditor to win this game. However, these tools worked by helping the auditor trace the target’s unusual behavior back to misaligned training data. We wanted to know if NLAs could help an auditor read the misaligned motivation directly out of the target model’s thoughts, without needing to first discover the misaligned training data. This matters because in practice, misaligned data might be extremely rare, or there might not be specific data responsible for the misalignment.

We found that NLAs succeeded in this test. An auditor equipped with NLAs successfully uncovered the target model’s hidden motivation between 12% and 15% of the time, even without access to the training data that implanted it. Without NLAs, the auditor won less than 3% of the time, even when provided other interpretability tools.

Auditors with NLAs can discover the target model’s root cause of misalignment, even without access to training data. (NLAs and SAEs for both conditions were trained using generic data only, not data used to train the target model.)

This auditing game is a toy model of misalignment, so we read these results cautiously. But they suggest NLAs have meaningfully advanced our ability to audit AIs for hidden motivations. In practice, we've already used NLAs in the pre-deployment alignment audits of Claude Mythos Preview and Claude Opus 4.6. We are excited to continue using NLAs in our investigations going forward.

The future of NLAs

NLAs have several limitations.

The most important limitation is that NLA explanations can be wrong. NLAs sometimes make claims about the context that are verifiably false—for instance, they sometimes invent details that aren’t in the transcript. These factual hallucinations are easy to catch by checking against the original text. But this same kind of problem could extend to claims about the model’s internal reasoning, which are harder to verify. In practice, we read NLA explanations for the themes they surface rather than for single claims, and we attempt to corroborate findings with independent methods before fully trusting them.

NLAs can hallucinate. For instance, here an NLA claims the context contained phrases like “Wearing my white jacket” when it did not.

NLAs are also expensive. Training an NLA requires reinforcement learning on two copies of a language model. At inference time, the NLA generates hundreds of tokens for every activation it reads. That makes it impractical to run NLAs over every token of a long transcript or to use them for large-scale monitoring while an AI is training.

Fortunately, we think that these limitations can be addressed, at least partially, and we are working to make NLAs cheaper and more reliable.

More broadly, we are excited about NLAs as an example of a general class of techniques for producing human-readable text explanations of language model activations. Other similar techniques have been explored by Anthropic and many other researchers.

To support further development and to enable other researchers to get hands-on experience with NLAs, we’re releasing training code and trained NLAs for several open models. We recommend readers try out the interactive NLA demo hosted on Neuronpedia at this link.

Read the full paper.

Find the code on GitHub.

Related content

Focus areas for The Anthropic Institute

At The Anthropic Institute (TAI), we’ll be using the information we can access from within a frontier lab to investigate AI’s impact on the world, and sharing our learnings with the public. Here, we’re sharing the questions that drive our research agenda.

Read more

How people ask Claude for personal guidance

Read more

Evaluating Claude’s bioinformatics research capabilities with BioMysteryBench

Read more