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How Far Are We From Human-level Intelligence in AI? by@kseniase
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How Far Are We From Human-level Intelligence in AI?

by Ksenia SeMarch 14th, 2024
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This edition explores the quest for AGI, highlighting research on AI's challenges in visual deductive reasoning and front-end automation. While AI struggles with abstract patterns and uncertainty, advancements in Design2Code show potential. Stephen Wolfram's insights on AI in science suggest its role as a tool rather than a solver, emphasizing human-AI collaboration for future discoveries. The focus shifts from achieving AGI to enhancing this partnership, underlining the indispensable role of human creativity.
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In today's edition:

  • What does research say about how far we are from AGI?
  • News from the usual subjects: Anthropic, Cohere, OpenAI, etc.
  • The freshest AI&ML research papers from the week of Mar 4 — Mar 10

Though the question, “How far are we from achieving human-level intelligence in machines (or AGI, or ASI)?” predates the term “artificial intelligence” itself, it saw a significant resurgence on Twitter last week, prompted by the Musk vs. OpenAI lawsuit (Musk accuses OpenAI of abandoning open-source principles and prioritizing profit over safety, hindering the safe development of AGI.) But far more interesting were the papers and an article that came out last week tackling this question. Today, we will discuss “How Far Are We from Intelligent Visual Deductive Reasoning?” “How Far Are We From Automating Front-End Engineering?” and Stephen Wolfram’s article “Can AI Solve Science?” These papers offer fascinating explorations of the differences between human and artificial intelligence.

Intelligent Visual Deductive Reasoning

In “How Far Are We from Intelligent Visual Deductive Reasoning?”, researchers from Apple explore Vision-Language Models (VLMs), like GPT-4V, in visual-based deductive reasoning, a complex yet less studied area, using Raven’s Progressive Matrices (RPMs)*.


*Raven’s Progressive Matrices is a nonverbal intelligence test measuring abstract reasoning, using patterns to assess cognitive functioning without language.


What caught my attention was the finding that AI systems like VLMs struggle with tasks requiring abstract pattern recognition and deduction. The paper notes, “VLMs struggle to solve these tasks mainly because they are unable to perceive and comprehend multiple, confounding abstract patterns in RPM examples.” This inability to deal with abstract concepts marks a fundamental difference between computational processing and human cognitive abilities. Being a sophisticated pattern recognizer doesn’t equate to sentience.


Another intriguing point was the models’ overconfidence. The observation that “all the tested models never express any level of uncertainty” highlights the importance of doubt and uncertainty in human cognition, suggesting a nuanced aspect of intelligence that current AI lacks.

Automating Front-End Engineers

In “”, researchers from Stanford University, Georgia Tech, Microsoft, and Google DeepMind have developed a benchmark for Design2Code, aiming to evaluate how well multimodal LLMs convert visual designs into code. Here, the replacement of humans came closer. Despite some limitations, there were considerable advancements in using generative AI to convert designs into front-end code. It’s remarkable that “annotators think GPT-4V generated webpages can replace the original reference webpages in 49% of cases in terms of visual appearance and content; and in 64% of cases, GPT-4V generated webpages are considered better.” This finding challenges traditional notions of artistic and creative value, questioning whether creativity is uniquely human or can be algorithmically reproduced — or even surpassed.


However, significant limitations persist. VLMs struggle with “recalling visual elements from the input webpages and generating correct layout designs.” posing questions about understanding and interpretation.


So, the important question is actually not how far we are from AGI (whatever it is), but how we embrace human-AI collaboration most effectively.

AI Solving Science

In that sense, Stephen Wolfram’s blog post “” serves as an excellent example. In the very beginning, he plainly states that AI cannot solve all scientific questions. However, there is significant value in AI assisting scientific progress. He discusses how LLMs can serve as a new kind of linguistic interface to computational capabilities, providing high-level “autocomplete” for scientific work. As he usually does, he emphasizes the transformative potential of representing the world computationally and suggests that pockets of computational reducibility* can be found by AI as well.


*A pocket of computational reducibility — a fascinating concept introduced by Wolfram — is a situation or problem within a complex system where, despite the system’s overall unpredictability, predictable patterns or simplified behaviors emerge, allowing for easier understanding or calculation.


Wolfram argues that AI can significantly aid scientific discovery by providing new tools for analysis and exploration, but its ability to completely “solve” science is limited by fundamental principles such as computational irreducibility. The future of AI in science lies in its integration with human creativity and understanding, leveraging its strengths to uncover new knowledge within the constraints of what is computationally possible.


We might be able to survive without front-end developers (no offense intended), but scientists remain indispensable!

To summarize:

News from The Usual Suspects ©

Cohere and its commitment to the research community

Hugging Face

  • Starting an ambitious open robotics project and hiring , a former Tesla scientist, to expand beyond software into robotics, including work on humanoid robots like Tesla’s Optimus.
  • Offers an amazing tool:

Russia’s talent is invisible

  • According to  “The Global AI Talent Tracker 2.0”, Russia has no chance in the AI race:

Inflection enhances its Pi

  • Inflection , enhancing its personal AI, Pi, with IQ capabilities alongside its empathetic EQ. They claim to compete with GPT-4, achieving significant efficiency and performance improvements, especially in STEM areas, with less computational resource usage.

Chips

  • TSMC (based in Taiwan), the world’s largest contract chipmaker, is  for an Arizona chip plant. This funding, part of the CHIPS and Science Act of 2022, aims to boost domestic semiconductor production. TSMC’s $40 billion investment in the plant marks one of the largest foreign investments in U.S. history.

OpenAI: new members on the board

  • Sam Altman is reinstated as a member of the OpenAI board.  Sue Desmond-Hellmann, with a rich history as the CEO of the Bill and Melinda Gates Foundation, brings extensive experience in healthcare and philanthropy. Nicole Seligman, a seasoned executive with roles at Sony Entertainment and as a lawyer, offers legal and entertainment industry insights. Fidji Simo, leading Instacart and with a background at Meta Platforms, including as head of Facebook, contributes expertise in technology and e-commerce. This diverse trio enhances OpenAI’s governance with their wide-ranging expertise and perspectives.

Elon’s Grok

Anthropic

  • Offers a great collection of prompts in its 

Enjoyed This Story?

I write a weekly analysis of the AI world in the  newsletter. We aim to equip you with comprehensive knowledge and historical insights, so you can make informed decisions about AI and ML.

Turing Post newsletter


🎁 Bonus: The freshest research papers, categorized for your convenience

Enhancements in Language Models and Multimodal Understanding

  • ChatMusician: Showcases an LLM’s intrinsic ability to understand and generate music, expanding LLMs’ applications beyond text. 
  • Gemini 1.5: Demonstrates advanced multimodal understanding by processing extensive contexts of text, video, and audio. 
  • NaturalSpeech 3: Enhances TTS synthesis with a factorized diffusion model for zero-shot natural speech generation. 
  • Finetuned Multimodal Language Models Are High-Quality Image-Text Data Filters: Utilizes fine-tuned MLMs for superior image-text data filtering, improving dataset quality for MLM training. 
  • SaulLM-7B: Introduces the first LLM designed for the legal domain, demonstrating proficiency in legal text understanding and generation. 

Novel Training and Evaluation Techniques

  • MathScale: Proposes a method for scaling instruction tuning in mathematical reasoning, significantly enhancing LLMs’ problem-solving abilities. 
  • ShortGPT: Reveals redundancy in LLM layers and proposes a pruning strategy, maintaining performance while reducing model size. 
  • GaLore: Enhances memory efficiency in LLM training without sacrificing performance by applying gradient low-rank projection. 
  • Learning to Decode Collaboratively with Multiple Language Models: Develops a method for collaborative decoding among multiple LLMs, improving performance across various tasks. 
  • Stop Regressing: Advocates for training RL value functions through classification instead of regression, boosting performance and scalability. 

Advances in Generative Models and Data Synthesis

  • MAGID: Introduces a framework for generating synthetic multimodal datasets, overcoming limitations in data privacy and diversity. 
  • Genie: Trains a generative model to create interactive virtual worlds from text, images, or sketches, advancing interactive environment simulation. Read the paper

Scalability and Efficiency in AI Systems

  • MegaScale: Details a system for training LLMs on over 10,000 GPUs, tackling challenges in training efficiency and stability at large scales. 
  • DenseMamba: Improves State Space Models with dense hidden connections for efficient large language models, enhancing performance with minimal parameter increase. 

Exploring New Frontiers in AI and Machine Learning

  • Inference via Interpolation: Illustrates that planning and prediction in time series can be simplified through learned contrastive representations. 
  • LLMs in the Imaginarium: Employs simulated trial and error for tool learning, significantly enhancing LLMs’ practical application capabilities. 
  • Resonance RoPE: Aims to improve context length generalization in LLMs by refining interpolation techniques for out-of-distribution token positions. 
  • AtP: Enhances the localization of behaviors in LLMs to specific components, improving diagnostic capabilities and model understanding. 
  • Learning and Leveraging World Models in Visual Representation Learning: Investigates using world models for enhancing visual representation learning, beyond reinforcement learning applications. 

Platforms and Tools for Model Evaluation and Interaction

  • Chatbot Arena: Provides a platform for evaluating LLMs based on human preferences, offering insights into model rankings through pairwise comparisons. 
  • Teaching Large Language Models to Reason with Reinforcement Learning: Explores enhancing LLMs’ reasoning capabilities using RLHF, comparing different algorithms and reward strategies. 

Also published .


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