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

Cyberwarzone
Cyberwarzone
V
Vulnerabilities – Threatpost
T
Tenable Blog
Forbes - Security
Forbes - Security
Simon Willison's Weblog
Simon Willison's Weblog
AWS News Blog
AWS News Blog
G
GRAHAM CLULEY
Know Your Adversary
Know Your Adversary
S
Securelist
C
Cybersecurity and Infrastructure Security Agency CISA
Project Zero
Project Zero
C
CXSECURITY Database RSS Feed - CXSecurity.com
V
Visual Studio Blog
WordPress大学
WordPress大学
Latest news
Latest news
K
Kaspersky official blog
T
Tailwind CSS Blog
T
Threat Research - Cisco Blogs
B
Blog RSS Feed
C
Cisco Blogs
博客园 - 聂微东
Martin Fowler
Martin Fowler
T
The Blog of Author Tim Ferriss
小众软件
小众软件
L
LangChain Blog
阮一峰的网络日志
阮一峰的网络日志
L
LINUX DO - 热门话题
Stack Overflow Blog
Stack Overflow Blog
罗磊的独立博客
P
Proofpoint News Feed
CTFtime.org: upcoming CTF events
CTFtime.org: upcoming CTF events
P
Privacy International News Feed
Cyber Security Advisories - MS-ISAC
Cyber Security Advisories - MS-ISAC
C
CERT Recently Published Vulnerability Notes
Cisco Talos Blog
Cisco Talos Blog
S
SegmentFault 最新的问题
Security Latest
Security Latest
Y
Y Combinator Blog
爱范儿
爱范儿
aimingoo的专栏
aimingoo的专栏
P
Privacy & Cybersecurity Law Blog
L
LINUX DO - 最新话题
月光博客
月光博客
The GitHub Blog
The GitHub Blog
博客园 - 三生石上(FineUI控件)
S
Security Affairs
P
Proofpoint News Feed
D
DataBreaches.Net
有赞技术团队
有赞技术团队
云风的 BLOG
云风的 BLOG

Google DeepMind News

Strengthening Singapore’s AI Future: A New National Partnership Simulate real-world places with Project Genie and Street View Introducing Gemini Omni Gemini for Science: AI experiments and tools for a new era of discovery Making it easier to understand how content was created and edited Gemini 3.5: frontier intelligence with action Co-Scientist: A multi-agent AI partner to accelerate research How WeatherNext helped the National Hurricane Center better predict Hurricane Melissa’s historic landfall in Jamaica Fast-tracking genetic leads to reverse cellular aging Finding the molecular switches behind new infectious diseases Opening new paths in aging research Accelerating discovery of liver disease mechanisms Uniting biological toolkits for a new approach to ALS Uncovering repurposed medicines to fight liver fibrosis Google Antigravity We’re launching the Google DeepMind Accelerator program in Asia Pacific to tackle environmental risks. AlphaEvolve: How our Gemini-powered coding agent is scaling impact across fields Enabling a new model for healthcare with AI co-clinician Announcing our partnership with the Republic of Korea Decoupled DiLoCo: A new frontier for resilient, distributed AI training Partnering with industry leaders to accelerate AI transformation Gemini 3.1 Flash TTS: the next generation of expressive AI speech Gemini Robotics-ER 1.6: Powering real-world robotics tasks through enhanced embodied reasoning Protecting people from harmful manipulation From games to biology and beyond: 10 years of AlphaGo’s impact A new way to express yourself: Gemini can now create music Accelerating discovery in India through AI-powered science and education Accelerating Mathematical and Scientific Discovery with Gemini Deep Think D4RT: Teaching AI to see the world in four dimensions Veo 3.1 Ingredients to Video: More consistency, creativity and control Gemma Scope 2: helping the AI safety community deepen understanding of complex language model behavior Google DeepMind supports U.S. Department of Energy on Genesis: a national mission to accelerate innovation and scientific discovery Gemini 3 Flash: frontier intelligence built for speed Improved Gemini audio models for powerful voice interactions Deepening our partnership with the UK AI Security Institute Strengthening our partnership with the UK government to support prosperity and security in the AI era FACTS Benchmark Suite: Systematically evaluating the factuality of large language models Engineering more resilient crops for a warming climate AlphaFold: Five years of impact Revealing a key protein behind heart disease How we’re bringing AI image verification to the Gemini app Build with Nano Banana Pro, our Gemini 3 Pro Image model Introducing Nano Banana Pro We’re expanding our presence in Singapore to advance AI in the Asia-Pacific region Start building with Gemini 3 A new era of intelligence with Gemini 3 Google Antigravity WeatherNext 2: Our most advanced weather forecasting model SIMA 2: An Agent that Plays, Reasons, and Learns With You in Virtual 3D Worlds How AI is giving Northern Ireland teachers time back Mapping, modeling, and understanding nature with AI Accelerating discovery with the AI for Math Initiative MedGemma: Our most capable open models for health AI development VaultGemma: The world's most capable differentially private LLM Bringing AI to the next generation of fusion energy Introducing Veo 3.1 and advanced capabilities in Flow Introducing the Gemini 2.5 Computer Use model Introducing CodeMender: an AI agent for code security Gemini Robotics 1.5 brings AI agents into the physical world Strengthening our Frontier Safety Framework Discovering new solutions to century-old problems in fluid dynamics Gemini achieves gold-medal level at the International Collegiate Programming Contest World Finals Using AI to perceive the universe in greater depth Image editing in Gemini just got a major upgrade Introducing Gemma 3 270M: The compact model for hyper-efficient AI How AI is helping advance the science of bioacoustics to save endangered species Genie 3: A new frontier for world models Rethinking how we measure AI intelligence Try Deep Think in the Gemini app AlphaEarth Foundations helps map our planet in unprecedented detail Aeneas transforms how historians connect the past Gemini 2.5 Flash-Lite is now stable and generally available Exploring the context of online images with Backstory Advanced version of Gemini with Deep Think officially achieves gold-medal standard at the International Mathematical Olympiad T5Gemma: A new collection of encoder-decoder Gemma models Introducing Gemma 3n: The developer guide AlphaGenome: AI for better understanding the genome Gemini Robotics On-Device brings AI to local robotic devices We’re expanding our Gemini 2.5 family of models Gemini 2.5: Updates to our family of thinking models Behind “ANCESTRA”: combining Veo with live-action filmmaking How we're supporting better tropical cyclone prediction with AI Advanced audio dialog and generation with Gemini 2.5 Gemini 2.5: Our most intelligent models are getting even better SynthID Detector — a new portal to help identify AI-generated content Our vision for building a universal AI assistant Fuel your creativity with new generative media models and tools Announcing Gemma 3n preview: powerful, efficient, mobile-first AI Gemini 2.5 Pro Preview: even better coding performance Build rich, interactive web apps with an updated Gemini 2.5 Pro Start building with Gemini 2.5 Flash Generate videos in Gemini and Whisk with Veo 2 DolphinGemma: How Google AI is helping decode dolphin communication Gemini 2.5: Our most intelligent AI model Experiment with Gemini 2.0 Flash native image generation Introducing Gemma 3: The most capable model you can run on a single GPU or TPU Start building with Gemini 2.0 Flash and Flash-Lite Gemini 2.0 is now available to everyone State-of-the-art video and image generation with Veo 2 and Imagen 3 Introducing Gemini 2.0: our new AI model for the agentic era
Teaching AI to see the world more like we do
Andrew Lampinen, Klaus Greff · 2025-11-12 · via Google DeepMind News

November 11, 2025 Research

Your browser does not support the audio element.

Listen to article 10 minutes

New research shows that reorganizing a model’s visual representations can make it more helpful, robust and reliable

“Visual” artificial intelligence (AI) is everywhere. We use it to sort our photos, identify unknown flowers and steer our cars. But these powerful systems do not always “see” the world as we do, and they sometimes behave in surprising ways. For example, an AI system that can identify hundreds of car manufacturers and models might still fail to capture the commonalities between a car and an airplane, i.e. both are large vehicles made primarily of metal.

To better understand these differences, today we’re publishing a new paper in Nature analyzing the important ways AI systems organize the visual world differently from humans. We present a method for better aligning these systems with human knowledge, and show that addressing these discrepancies improves their robustness and ability to generalize.

This work is a step towards building more intuitive and trustworthy AI systems.

Why AI struggles with the “odd one out”

When you see a cat, your brain creates a mental representation that captures everything about the cat, from basic concepts like its color and furriness to high-level concepts like its "cat-ness." AI vision models also produce representations, by mapping images to points in a high-dimensional space where similar items (like two sheep) are placed close together, and different ones (a sheep and a cake) are far apart.

To understand the differences in how human and model representations are organized, we used the classic "odd-one-out" task from cognitive science, asking both humans and models to pick which of three given images does not fit in with the others. This test reveals which two items they "see" as most similar.

Sometimes, everyone agrees. Given a tapir, a sheep, and a birthday cake, both humans and models reliably pick the cake as the odd one out. Other times, the right answer is unclear, and people and models disagree.

Interestingly, we also found many cases where humans strongly agree on an answer, but the AI models get it wrong. For the third example below, most people agree the starfish is the odd one out. But most vision models focus more on superficial features like background color and texture, and choose the cat instead.

Three examples of the "odd one out" task. Three images of subjects in the natural world are shown in three rows. The first row shows an easy task where humans and models align. The second row shows an example where humans and AI models disagree. The third row shows an example where humans tend to agree, but models make a different choice.

This example illustrates a systematic misalignment between humans and AI, which we observed across many different vision models, from image classifiers to unsupervised models.

The overall problem can be seen in a two-dimensional projection (PCA) of an AI’s internal map.

Below, on the left, we show a vision model's internal map which appears unstructured, with representations for different categories like animals, food, and furniture all mixed together. The structure on the right is the improved representation map after we applied our alignment method where categories are clearly organized.

Two maps showing a vision model’s representations of many different categories of objects. Before alignment (left) there is no visible organization. After alignment (right) the representations are meaningfully organized by category.

A multi-step alignment method

Cognitive scientists have collected the THINGS dataset containing millions of human odd-one-out judgements, which we could have used to help solve the visual alignment problem. Unfortunately, this dataset only uses a few thousand images — not enough information to directly fine tune powerful vision models, which immediately overfit on this small set of images and forget many of their prior skills.

To address this, we proposed a three-step method:

  1. We started with a powerful pretrained vision model (SigLIP-SO400M) and carefully trained a small adapter on top of it, using the THINGS dataset. By freezing the main model and carefully regularizing the adapter training, we created a teacher model that doesn’t forget its prior training.
  2. This teacher model then acts as a stand-in for human-like judgments, which we used to generate a massive new dataset, called AligNet, of millions of human-like odd-one-out decisions using a million different images — far more than we could collect from real people.
  3. Finally, we used this new dataset to fine tune other AI models (the "students"). Because of the diversity of our dataset, overfitting is no longer an issue and the students can be trained fully and can more deeply restructure their internal maps.

As shown in the diagram below, the student’s representations change from an unstructured jumble to a clearly-structured organization where high-level concepts such as animals (blue) and food items (green) are separated from other types of objects.

Diagram of our three-step model-alignment method.

Human knowledge is organized according to different levels of similarity. When we align models with human knowledge, the model’s representations change according to these levels of similarity. This reorganization follows the hierarchical structure of human knowledge known from cognitive science.

During alignment, we see that representations move apart or together in proportion to their ”conceptual distance” in the human-category hierarchy. For example, two dogs (same subordinate category) will move closer together (decrease in distance), while an owl and a truck (different superordinate categories) will move further apart (increase in distance).

A line graph shows the change in relative distances between human and AI representations. The representations of very similar categories tend to get closer together, while representations of less similar pairs of objects tend to move further apart.

We can conclude that our method organizes the representational map of the AI student according to human conceptual hierarchies, without being explicitly supervised to do so.

Testing our aligned models

We tested our aligned models on many cognitive science tasks — including tasks like multi-arrangement, arranging many images by their similarity — and a new odd-one-out dataset, called Levels, that we collected. In every case, our aligned models showed dramatically improved human-alignment, agreeing substantially more often with human judgments across a range of visual tasks.

Our models even learned a form of ‘human-like’ uncertainty. In testing, model-decision-uncertainty strongly correlated with how long it took humans to make a choice – a common proxy measure for uncertainty.

We also found that making models more human-aligned also makes them better vision models overall. Our aligned models performed much better at various challenging tasks, such as learning a new category from a single image (“few-shot learning”), or making reliable decisions, even when the type of images being tested changed (the “distribution shift”).

Two bar graphs showing that our aligned models (dark blue) outperform the original ones (light gray) at cognitive science tasks involving odd-one-out and multi-arrangement (top) and AI tasks involving few-shot learning and distribution shift (bottom).

Toward more human-aligned, reliable models

Many existing vision models fail to capture the higher-level structure of human knowledge. This research presents a possible method for addressing this issue, and shows that models can be aligned better with human judgments and perform more reliably on various standard AI tasks.

While more alignment work remains to be done, our work illustrates a step towards more robust and reliable AI systems.

Learn more about our work

Acknowledgements

We’d like to thank the paper’s lead author Lukas Muttenthaler, and our collaborators Frieda Born, Bernhard Spitzer, Simon Kornblith, Michael C. Mozer, Klaus-Robert Müller and Thomas Unterthiner.

Gemini Robotics: 1.5 brings AI agents into the physical world

Image editing in Gemini just got a major upgrade