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

D
Docker
Simon Willison's Weblog
Simon Willison's Weblog
H
Help Net Security
F
Fortinet All Blogs
H
Heimdal Security Blog
S
Schneier on Security
L
LangChain Blog
博客园 - Franky
酷 壳 – CoolShell
酷 壳 – CoolShell
NISL@THU
NISL@THU
P
Palo Alto Networks Blog
J
Java Code Geeks
博客园 - 【当耐特】
The Last Watchdog
The Last Watchdog
W
WeLiveSecurity
www.infosecurity-magazine.com
www.infosecurity-magazine.com
OSCHINA 社区最新新闻
OSCHINA 社区最新新闻
V
Vulnerabilities – Threatpost
I
InfoQ
Recorded Future
Recorded Future
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
C
CERT Recently Published Vulnerability Notes
T
Tenable Blog
腾讯CDC
C
Check Point Blog
量子位
M
MIT News - Artificial intelligence
GbyAI
GbyAI
罗磊的独立博客
Threat Intelligence Blog | Flashpoint
Threat Intelligence Blog | Flashpoint
B
Blog
小众软件
小众软件
cs.AI updates on arXiv.org
cs.AI updates on arXiv.org
奇客Solidot–传递最新科技情报
奇客Solidot–传递最新科技情报
C
CXSECURITY Database RSS Feed - CXSecurity.com
Stack Overflow Blog
Stack Overflow Blog
P
Proofpoint News Feed
P
Privacy & Cybersecurity Law Blog
V2EX - 技术
V2EX - 技术
T
Threatpost
Engineering at Meta
Engineering at Meta
Attack and Defense Labs
Attack and Defense Labs
T
Tailwind CSS Blog
S
Securelist
The Cloudflare Blog
博客园 - 叶小钗
L
LINUX DO - 最新话题
T
Troy Hunt's Blog
C
Cyber Attacks, Cyber Crime and Cyber Security
爱范儿
爱范儿

OpenAI News

Using custom GPTs ChatGPT for customer success teams Applications of AI at OpenAI Research with ChatGPT Analyzing data with ChatGPT Financial services Responsible and safe use of AI Writing with ChatGPT ChatGPT for research Creating images with ChatGPT Personalizing ChatGPT ChatGPT for finance teams Getting started with ChatGPT Working with files in ChatGPT ChatGPT for sales teams Prompting fundamentals ChatGPT for managers Using projects in ChatGPT ChatGPT for marketing teams Brainstorming with ChatGPT AI fundamentals ChatGPT for operations teams Healthcare Our response to the Axios developer tool compromise Using skills OpenAI Full Fan Mode Contest: Terms & Conditions CyberAgent moves faster with ChatGPT Enterprise and Codex The next phase of enterprise AI Introducing the Child Safety Blueprint Introducing the OpenAI Safety Fellowship Industrial policy for the Intelligence Age OpenAI acquires TBPN Codex now offers more flexible pricing for teams Gradient Labs gives every bank customer an AI account manager OpenAI raises $122 billion to accelerate the next phase of AI Helping disaster response teams turn AI into action across Asia STADLER reshapes knowledge work at a 230-year-old company Inside our approach to the Model Spec Introducing the OpenAI Safety Bug Bounty program Helping developers build safer AI experiences for teens Update on the OpenAI Foundation Powering Product Discovery in ChatGPT Creating with Sora Safely How we monitor internal coding agents for misalignment OpenAI to acquire Astral Introducing GPT-5.4 mini and nano OpenAI Japan announces Japan Teen Safety Blueprint to put teen safety first Equipping workers with insights about compensation Why Codex Security Doesn’t Include a SAST Report Designing AI agents to resist prompt injection From model to agent: Equipping the Responses API with a computer environment Rakuten fixes issues twice as fast with Codex Wayfair boosts catalog accuracy and support speed with OpenAI Improving instruction hierarchy in frontier LLMs New ways to learn math and science in ChatGPT OpenAI to acquire Promptfoo Codex Security: now in research preview How Descript engineers multilingual video dubbing at scale How Balyasny Asset Management built an AI research engine Reasoning models struggle to control their chains of thought, and that’s good Introducing GPT-5.4 GPT-5.4 Thinking System Card Ensuring AI use in education leads to opportunity VfL Wolfsburg turns ChatGPT into a club-wide capability OpenAI and NORAD team up to bring new magic to “NORAD Tracks Santa” Accenture and OpenAI accelerate enterprise AI success OpenAI takes an ownership stake in Thrive Holdings to accelerate enterprise AI adoption What to know about a recent Mixpanel security incident Expanding data residency access to business customers worldwide Our approach to mental health-related litigation Inside JetBrains—the company reshaping how the world writes code Introducing shopping research in ChatGPT How GPT-5 helped mathematician Ernest Ryu solve a 40-year-old open problem OpenAI and Foxconn collaborate to strengthen U.S. manufacturing across the AI supply chain Disrupting malicious uses of AI: June 2025 Creating websites in minutes with AI Website Builder Addendum to OpenAI o3 and o4-mini system card: OpenAI o3 Operator OpenAI Deutschland Shipping code faster with o3, o4-mini, and GPT-4.1 Introducing Stargate UAE New tools and features in the Responses API Introducing Codex Addendum to o3 and o4-mini system card: Codex AI powers Expedia’s marketing evolution Strengthening America’s AI leadership with the U.S. National Laboratories Introducing ChatGPT Gov Operator System Card Computer-Using Agent Introducing Operator Bertelsmann powers creativity and productivity with OpenAI Trading Inference-Time Compute for Adversarial Robustness Announcing The Stargate Project Stargate Infrastructure The power of personalized AI Delivering LLM-powered health solutions Increasing accuracy of pediatric visit notes Practices for Governing Agentic AI Systems Superalignment Fast Grants Weak-to-strong generalization Partnership with Axel Springer to deepen beneficial use of AI in journalism
Evolved Policy Gradients
2018-04-18 · via OpenAI News

The intuition behind EPG comes from something we are all familiar with: trying to pick up a new skill and experiencing the alternating frustration and joy involved in that process. Suppose you are just starting out learning to play the violin. Even without instruction, you will immediately have a feel for what to try, and, listening to the sounds you produce, you will have a sense of whether or not you are making progress – that’s because you effectively have access to very well shaped internal reward functions(opens in a new window), derived from prior experience on other motor tasks, and through the course of biological evolution. In contrast, most reinforcement learning (RL) agents approach each new task without using prior knowledge. Instead they rely entirely on external reward signals to guide their initial behavior. Coming from such a blank slate, it is no surprise that current RL agents take far longer(opens in a new window) than humans to learn simple skills. EPG takes a step toward agents that are not blank slates but instead know what it means to make progress on a new task, by having experienced making progress on similar tasks in the past.

There has been a flurry of recent work(opens in a new window) on(opens in a new window) metalearning(opens in a new window) policies(opens in a new window), and it’s worth asking why learn a loss function as opposed to directly learning a policy? Learning recurrent policies tends to overfit the task at hand, while learning policy initializations has limited expressivity when it comes to exploration. Our motivation is that we expect loss functions to be the kind of object that may generalize very well across substantially different tasks. This is certainly true of hand-engineered loss functions: a well-designed RL loss function, such as that in PPO(opens in a new window), can be very generically applicable, finding use in problems ranging from playing Atari games to controlling robots.

To test the generalization ability of EPG, we conducted a simple experiment. We evolved the EPG loss to be effective at getting “ants” to walk to randomly located targets on the right half of an arena. Then, we froze the loss, and gave the ants a new target, this time on the left half of the arena. Surprisingly, the ants learned to walk to the left! Here is how their learning curves looked (red lines on graphs):

This result is exciting to us because it demonstrates generalization to a task outside the training distribution. This kind of generalization can be quite hard to achieve. We compared EPG to an alternative metalearning algorithm, called RL2(opens in a new window), which tries to directly learn a policy that can adapt to novel tasks. In our experiment, RL2 was indeed successful at getting agents to walk to targets on the right half of the screen. However, when given a test time target on the left half of the screen, it qualitatively failed, and just kept walking to the right. In a sense, it “overfit” to the set of tasks on which it was trained (i.e. walking to the right).

As do all metalearning approaches, our method still has many limitations. Right now, we can train an EPG loss to be effective for one small family of tasks at a time, e.g., getting an ant to walk left and right. However, the EPG loss for this family of tasks is unlikely to be at all effective on a wildly different kind of task, like playing Space Invaders. In contrast, standard RL losses do have this level of generality—the same loss function can be used to learn a huge variety of skills. EPG gains on performance by losing on generality. There is a long road ahead toward metalearning methods that both outperform standard RL methods and have the same level of generality.