Data is at the heart of today’s advanced AI systems, but it’s costing more and more — making it out of reach for all but the wealthiest tech businesses.
Last year, James Betker, a researcher at OpenAI, penned a post on his personal blog about the nature of generative AI models and the datasets on which they’re trained. In it, Betker claimed that training data — not a model’s design, architecture or any other characteristic — was the key to increasingly sophisticated, capable AI systems.
“Trained on the same data set for long enough, pretty much every model converges to the same point,” Betker wrote.
Is Betker right? Is training data the biggest determiner of what a model can do, whether it’s answer a question, draw human hands, or generate a realistic cityscape?
It’s certainly plausible.
Statistical machines
Generative AI systems are basically probabilistic models — a huge pile of statistics. They guess based on vast amounts of examples which data makes the most “sense” to place where (e.g., the word “go” before “to the market” in the sentence “I go to the market”). It seems intuitive, then, that the more examples a model has to go on, the better the performance of models trained on those examples.
“It does seem like the performance gains are coming from data,” Kyle Lo, a senior applied research scientist at the Allen Institute for AI (AI2), a AI research nonprofit, told TechCrunch, “at least once you have a stable training setup.”
Lo gave the example of Meta’s Llama 3, a text-generating model released earlier this year, which outperforms AI2’s own OLMo model despite being architecturally very similar. Llama 3 was trained on significantly more data than OLMo, which Lo believes explains its superiority on many popular AI benchmarks.
(I’ll point out here that the benchmarks in wide use in the AI industry today aren’t necessarily the greatest gauge of a model’s performance, but outside of qualitative tests like our own, they’re one of the few measures we have to go on.)
That’s not to suggest that training on exponentially larger datasets is a sure-fire path to exponentially better models. Models operate on a “garbage in, garbage out” paradigm, Lo notes, and so data curation and quality matter a great deal, perhaps more than sheer quantity.
“It is possible that a small model with carefully designed data outperforms a large model,” he added. “For example, Falcon 180B, a large model, is ranked 63rd on the LMSYS benchmark, while Llama 2 13B, a much smaller model, is ranked 56th.”
In an interview with TechCrunch last October, OpenAI researcher Gabriel Goh said that higher-quality annotations contributed enormously to the enhanced image quality in DALL-E 3, OpenAI’s text-to-image model, over its predecessor DALL-E 2. “I think this is the main source of the improvements,” he said. “The text annotations are a lot better than they were [with DALL-E 2] — it’s not even comparable.”
Many AI models, including DALL-E 3 and DALL-E 2, are trained by having human annotators label data so that a model can learn to associate those labels with other, observed characteristics of that data. For example, a model that’s fed lots of cat pictures with annotations for each breed will eventually “learn” to associate terms like bobtail and shorthair with their distinctive visual traits.
Bad behavior
Experts like Lo worry that the growing emphasis on large, high-quality training datasets will centralize AI development into the few players with billion-dollar budgets that can afford to acquire these sets. Major innovation in synthetic data or fundamental architecture could disrupt the status quo, but neither appear to be on the near horizon.
“Overall, entities governing content that’s potentially useful for AI development are incentivized to lock up their materials,” Lo said. “And as access to data closes up, we’re basically blessing a few early movers on data acquisition and pulling up the ladder so nobody else can get access to data to catch up.”
Indeed, where the race to scoop up more training data hasn’t led to unethical (and perhaps even illegal) behavior like secretly aggregating copyrighted content, it has rewarded tech giants with deep pockets to spend on data licensing.
Generative AI models such as OpenAI’s are trained mostly on images, text, audio, videos and other data — some copyrighted — sourced from public web pages (including, problematically, AI-generated ones). The OpenAIs of the world assert that fair use shields them from legal reprisal. Many rights holders disagree — but, at least for now, they can’t do much to prevent this practice.
There are many, many examples of generative AI vendors acquiring massive datasets through questionable means in order to train their models. OpenAI reportedly transcribed more than a million hours of YouTube videos without YouTube’s blessing — or the blessing of creators — to feed to its flagship model GPT-4. Google recently broadened its terms of service in part to be able to tap public Google Docs, restaurant reviews on Google Maps and other online material for its AI products. And Meta is said to have considered risking lawsuits to train its models on IP-protected content.
Meanwhile, businesses large and small are relying on workers in third-world countries paid only a few dollars per hour to create annotations for training sets. Some of these annotators — employed by mammoth startups like Scale AI — work literal days on end to complete tasks that expose them to graphic depictions of violence and bloodshed without any benefits or guarantees of future gigs.
Growing cost
In other words, even the more aboveboard data deals aren’t exactly fostering an open and equitable generative AI ecosystem.
OpenAI has spent hundreds of millions of dollars licensing content from news publishers, stock media libraries and more to train its AI models — a budget far beyond that of most academic research groups, nonprofits and startups. Meta has gone so far as to weigh acquiring the publisher Simon & Schuster for the rights to e-book excerpts (ultimately, Simon & Schuster sold to private equity firm KKR for $1.62 billion in 2023).
With the market for AI training data expected to grow from roughly $2.5 billion now to close to $30 billion within a decade, data brokers and platforms are rushing to charge top dollar — in some cases over the objections of their user bases.
Stock media library Shutterstock has inked deals with AI vendors ranging from $25 million to $50 million, while Reddit claims to have made hundreds of millions from licensing data to orgs such as Google and OpenAI. Few platforms with abundant data accumulated organically over the years haven’t signed agreements with generative AI developers, it seems — from Photobucket to Tumblr to Q&A site Stack Overflow.
It’s the platforms’ data to sell — at least depending on which legal arguments you believe. But in most cases, users aren’t seeing a dime of the profits. And it’s harming the wider AI research community.
“Smaller players won’t be able to afford these data licenses, and therefore won’t be able to develop or study AI models,” Lo said. “I worry this could lead to a lack of independent scrutiny of AI development practices.”
Independent efforts
If there’s a ray of sunshine through the gloom, it’s the few independent, not-for-profit efforts to create massive datasets anyone can use to train a generative AI model.
EleutherAI, a grassroots nonprofit research group that had began as a loose-knit Discord collective in 2020, is working with the University of Toronto, AI2 and independent researchers to create The Pile v2, a set of billions of text passages primarily sourced from the public domain.
In April, AI startup Hugging Face released FineWeb, a filtered version of the Common Crawl — the eponymous dataset maintained by the nonprofit Common Crawl, composed of billions upon billions of web pages — that Hugging Face claims improves model performance on many benchmarks.
A few efforts to release open training datasets, like the group LAION’s image sets, have run up against copyright, data privacy and other, equally serious ethical and legal challenges. But some of the more dedicated data curators have pledged to do better. The Pile v2, for example, removes problematic copyrighted material found in its progenitor dataset, The Pile.
The question is whether any of these open efforts can hope to maintain pace with Big Tech. As long as data collection and curation remains a matter of resources, the answer is likely no — at least not until some research breakthrough levels the playing field.