China’s AI Breakthrough: Synthetic-Data Model Runs on Nvidia H20 & H200 Chips

Forget scraping the internet—China's latest AI model learned everything from lab-grown data. It's running on Nvidia's cutting-edge H20 and H200 hardware, proving you don't need the real world to build a powerful brain.

The Synthetic Advantage

This approach bypasses messy copyright issues and biased datasets. The model trains on perfectly curated, algorithmically generated information—clean, controlled, and entirely artificial. It cuts out the noise to focus purely on pattern recognition.

Hardware Handshake

Deploying on Nvidia's latest H20 and H200 chips isn't just a flex; it's a necessity. The computational heft required to process purely synthetic training cycles demands top-tier silicon. This partnership shows synthetic AI isn't a lightweight experiment—it's a resource-intensive frontier.

The Finance Angle (With a Jab)

While VCs pour billions into data-hungry AI startups, this model quietly proves you might not need all that expensive, real-world data in the first place. It's enough to make a hedge fund manager question their entire due diligence checklist—if they had one.

The bottom line? The rules of AI training are being rewritten. If you can build intelligence from scratch, what else in the tech stack is just legacy baggage?

Researchers use Nvidia chips to skip real-world data entirely

The training setup leaned hard on Nvidia hardware. For supervised fine-tuning, they used 128 Nvidia H20 chips for 220 hours straight. After that, they switched to 32 H200 chips for another seven full days to handle the reinforcement learning phase. These weren’t random choices. The H20 is tuned for inference, and the H200 is built for high-end training. These are the most powerful chips available to Chinese firms right now, thanks to export control exemptions the TRUMP administration approved after Nvidia lobbied hard to make them available in China.

The researchers said the pipeline itself wasn’t the problem when it came to scaling. It was all about compute power.

Wu Jie, the lead author and a master’s student at Tsinghua, said the real reason they hadn’t taken the pipeline to 100 billion or trillion-parameter models was simply, “computational constraints, rather than limitations of the pipeline itself.”

By releasing the code publicly, they hope others can build on the project without needing to pay massive training costs. The paper also points out a trend in AI.

Models are now expected to “think” over longer timeframes and handle complex reasoning, which has pushed the need for way more compute during inference, not just training.

Chinese team builds faster chip using old fabrication tech

Separately, a new chip called ACCEL was built by Chinese scientists using light particles, not electricity. The chip (short for All-Analogue Chip Combining Electronics and Light) was tested in a lab and hit 4.6 PFLOPS.

That’s 3,000 times faster than Nvidia’s A100, and the Chinese chip used 4 million times less energy. This makes it one of the most efficient AI chips ever made for specific tasks like image recognition or autonomous driving.

It won’t replace CPUs or smartphone chips yet, but the team thinks it could work in wearables, electric vehicles, or smart factories.

The chip was built using a 20-year-old process by Semiconductor Manufacturing International Corporation. It avoided the need for advanced lithography machines that China still can’t access.

“Deployment of photonic computing systems used to be a challenge due to complicated structural design and vulnerability to noise and system errors,” Tsinghua said in an article.

The chip avoids this by combining photonic and analog electronics in a new framework. It doesn’t handle general computing tasks like file compression, but it’s great for AI vision and low-light sensing.

One crazy detail: the energy it takes to run modern chips for an hour could keep ACCEL running for 500 years. That low power demand also makes it easier to deal with heat issues, which limit how small chips can get.

The chip’s functions include traffic identification, lowlight imaging, and real-time vision, using ambient light directly in the sensing process. The team said it’s not a general-purpose chip, but it fills a very specific need.

Funding came from the National Key R&D Programme and the National Natural Science Foundation of China. A Beijing chip company called MakeSens, co-founded by one of the researchers, was involved and recently launched a low-power analog chip too.

Tsinghua’s DAI Qionghai, one of the project leads, said building a new computing architecture was just the first step.

“The more important challenge is to bring this new architecture to practical applications, solving major national and public needs, which is our responsibility.”

The team hasn’t said anything about when this chip might hit the market.

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