MIT Researchers Unveil âSEALâ: A New Step Towards Self
The concept of AI self-improvement has been a hot topic in recent research circles, with a flurry of papers emerging and prominent figures like OpenAI CEO Sam Altman weighing in on the future of self-evolving intelligent systems. Now, a new paper from MIT, titled âSelf-Adapting Language Models,â introduces SEAL (Self-Adapting LLMs), a novel framework that allows large language models (LLMs) to update their own weights. This development is seen as another significant step towards the realization of truly self-evolving AI.
The research paper, published yesterday, has already ignited considerable discussion, including on Hacker News. SEAL proposes a method where an LLM can generate its own training data through âself-editingâ and subsequently update its weights based on new inputs. Crucially, this self-editing process is learned via reinforcement learning, with the reward mechanism tied to the updated modelâs downstream performance.
The timing of this paper is particularly notable given the recent surge in interest surrounding AI self-evolution. Earlier this month, several other research efforts garnered attention, including Sakana AI and the University of British Columbiaâs âDarwin-GĂśdel Machine (DGM),â CMUâs âSelf-Rewarding Training (SRT),â Shanghai Jiao Tong Universityâs âMM-UPTâ framework for continuous self-improvement in multimodal large models, and the âUI-Genieâ self-improvement framework from The Chinese University of Hong Kong in collaboration with vivo.
Adding to the buzz, OpenAI CEO Sam Altman recently shared his vision of a future with self-improving AI and robots in his blog post, âThe Gentle Singularity.â He posited that while the initial millions of humanoid robots would need traditional manufacturing, they would then be able to âoperate the entire supply chain to build more robots, which can in turn build more chip fabrication facilities, data centers, and so on.â This was quickly followed by a tweet from @VraserX, claiming an OpenAI insider revealed the company was already running recursively self-improving AI internally, a claim that sparked widespread debate about its veracity.
Regardless of the specifics of internal OpenAI developments, the MIT paper on SEAL provides concrete evidence of AIâs progression towards self-evolution.
Understanding SEAL: Self-Adapting Language Models
The core idea behind SEAL is to enable language models to improve themselves when encountering new data by generating their own synthetic data and optimizing their parameters through self-editing. The modelâs training objective is to directly generate these self-edits (SEs) using data provided within the modelâs context.
The generation of these self-edits is learned through reinforcement learning. The model is rewarded when the generated self-edits, once applied, lead to improved performance on the target task. Therefore, SEAL can be conceptualized as an algorithm with two nested loops: an outer reinforcement learning (RL) loop that optimizes the generation of self-edits, and an inner update loop that uses the generated self-edits to update the model via gradient descent.
This method can be viewed as an instance of meta-learning, where the focus is on how to generate effective self-edits in a meta-learning fashion.
A General Framework
SEAL operates on a single task instance (C,Ď), where C is context information relevant to the task, and Ď defines the downstream evaluation for assessing the modelâs adaptation. For example, in a knowledge integration task, C might be a passage to be integrated into the modelâs internal knowledge, and Ď a set of questions about that passage.
Given C, the model generates a self-edit SE, which then updates its parameters through supervised fine-tuning: θâ˛âSFT(θ,SE). Reinforcement learning is used to optimize this self-edit generation: the model performs an action (generates SE), receives a reward r based on LMθâ˛âs performance on Ď, and updates its policy to maximize the expected reward.
The researchers found that traditional online policy methods like GRPO and PPO led to unstable training. They ultimately opted for ReST^EM, a simpler, filtering-based behavioral cloning approach from a DeepMind paper. This method can be viewed as an Expectation-Maximization (EM) process, where the E-step samples candidate outputs from the current model policy, and the M-step reinforces only those samples that yield a positive reward through supervised fine-tuning.
The paper also notes that while the current implementation uses a single model to generate and learn from self-edits, these roles could be separated in a âteacher-studentâ setup.
Instantiating SEAL in Specific Domains
The MIT team instantiated SEAL in two specific domains: knowledge integration and few-shot learning.
- Knowledge Integration: The goal here is to effectively integrate information from articles into the modelâs weights.
- Few-Shot Learning: This involves the model adapting to new tasks with very few examples.
Experimental Results
The experimental results for both few-shot learning and knowledge integration demonstrate the effectiveness of the SEAL framework.
In few-shot learning, using a Llama-3.2-1B-Instruct model, SEAL significantly improved adaptation success rates, achieving 72.5% compared to 20% for models using basic self-edits without RL training, and 0% without adaptation. While still below âOracle TTTâ (an idealized baseline), this indicates substantial progress.
For knowledge integration, using a larger Qwen2.5-7B model to integrate new facts from SQuAD articles, SEAL consistently outperformed baseline methods. Training with synthetically generated data from the base Qwen-2.5-7B model already showed notable improvements, and subsequent reinforcement learning further boosted performance. The accuracy also showed rapid improvement over external RL iterations, often surpassing setups using GPT-4.1 generated data within just two iterations.
Qualitative examples from the paper illustrate how reinforcement learning leads to the generation of more detailed self-edits, resulting in improved performance.
While promising, the researchers also acknowledge some limitations of the SEAL framework, including aspects related to catastrophic forgetting, computational overhead, and context-dependent evaluation. These are discussed in detail in the original paper.
Original Paper: https://arxiv.org/pdf/2506.10943
Project Site: https://jyopari.github.io/posts/seal
Github Repo: https://github.com/Continual-Intelligence/SEAL
Pingback: TOPINDIATOURS Update ai: Eric Trump Pouring Funding Into âLow Cost-Per-Killâ Drone Corpora â TOPINDIATOURS
Pingback: TOPINDIATOURS Hot ai: Listen Labs raises $69M after viral billboard hiring stunt to scale â TOPINDIATOURS
Pingback: MAROKO133 Breaking ai: Which Agent Causes Task Failures and When?Researchers from PSU and - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
Pingback: TOPINDIATOURS Eksklusif ai: Evidence Grows That One of the Largest Known Stars Is Poised t â TOPINDIATOURS
Pingback: MAROKO133 Hot ai: Railway secures $100 million to challenge AWS with AI-native cloud infra - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
Pingback: MAROKO133 Breaking ai: Researchers from PSU and Duke introduce âMulti-Agent Systems Automa - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
Pingback: MAROKO133 Update ai: People Really, Really Despise AI â Even More Than ICE, Poll Finds Edi - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
Fascinating research on self-improving AI systems! The implications for creative AI are massive too. At MemoTune, weâre applying similar AI advancements to music generation â turning personal stories into songs and enabling voice covers with preserved melodies.
Pingback: MAROKO133 Breaking ai: Salesforce rolls out new Slackbot AI agent as it battles Microsoft - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
Pingback: MAROKO133 Hot ai: Claude Code costs up to $200 a month. Goose does the same thing for free - Maroko133 : Akses Mudah Ke Pusat Hiburan Digital Terpercaya
How it works
Once you click Generate, Ollama reads this article and crafts 5 comprehension questions. Your answers are graded against the article content â general knowledge won't be enough. Score 70+ to count toward your certificate.
Questions are cached â you'll always get the same 5 for this article.