Throughout the 20th century, each decade had its own unique set of inventions that left their mark on history. Curious about ...

Innatera adopts Synopsys simulation technology to help design neuromorphic chips that enable low-power AI for wearables, ...

Enabling scalable power for AI computing and next-generation robotics Our new GaN integrated circuits enable more ...

Recent decades have witnessed rapid advancements in high-intensity laser technology. The combination of laser irradiation and novel materials is opening exciting avenues for the design of functional ...

AI optimists envision a future where artificial general intelligence (AGI) surpasses human intelligence, but the path remains riddled with scientific and logistical hurdles.

Over periods up to 10 years, tech doesn’t reliably outperform coal, gas and oil – and over longer terms tech usually underperforms energy.

Once the design is complete, testing usually happens on an FPGA (Field Programmable Gate Array). For anyone who has not encountered the term yet, an FPGA is a reprogrammable chip that you can program ...

A single breakthrough won’t define the future of electronic devices. Trailblazers must combine innovative engineering and ...

AI’s march toward the singularity is hitting a hard limit: Moore’s Law is slowing, energy is scarce, and star-powered dreams remain science fiction.

Researchers demonstrate that femtosecond laser-induced transient Pauli blocking can achieve ultrafast, broadband optical ...

The startup Taalas wants to deliver a hardwired Llama 3.1 8B with almost 17,000 tokens/s with the HC1 – almost 10 times faster than previous solutions.

The industry’s response is to split compute, memory, and I/O across dies, XPU chiplets are pushing toward the reticle limit, and stitch it all together with high‑bandwidth, energy‑efficient die‑to‑die ...