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  "path": "/article/4162206/how-ai-is-changing-copper-fiber-networking.html",
  "publishedAt": "2026-04-22T20:15:32.000Z",
  "site": "https://www.networkworld.com",
  "tags": [
    "Artificial Intelligence, Networking, Networking Devices",
    "Nvidia GTC conference",
    "cabling, copper and fiber optics",
    "Gilad Shainer, senior vice president of networking at Nvidia.",
    "Point2",
    "co‑packaged optics",
    "CPO dramatically",
    "fiber and copper"
  ],
  "textContent": "The advent of artificial intelligence — and in particular dedicated AI data centers — has meant that data movement over the network is more important than ever, as processing of inference and large language model training consumes terabytes of data stored in data centers the size of a football stadium.\n\nNot only that, but there is now an increasing effort to tie together distant data centers into clusters to share data. Data movement that was once commonly measured in feet is now measured in yards and even miles.\n\nOne of the many subjects discussed at the recently completed Nvidia GTC conference was network connectivity particularly using copper and fiber together moving forward. There are two forms of network cabling, copper and fiber optics. The two technologies are very different and have different use cases, but their coexistence is undeniable. Businesses will need both to operate data centers at maximum efficiency.\n\nAt its core, the distinction is simple. Copper cables transmit data using electrical signals, while fiber uses light. Copper remains the dominant option for short connections because it is inexpensive, extremely reliable, and consumes virtually no power.\n\nFiber, meanwhile, is indispensable for long‑distance, high‑capacity links—but at a significant energy cost, says Gilad Shainer, senior vice president of networking at Nvidia.\n\n“Copper doesn’t consume much power, it’s nearly zero, and it’s very reliable. It’s hard to break copper cables,” he said. “So you want to use copper, especially when the limiting factor on how much compute you can bring into their factory depends on the power that you have available to you.”\n\nIn a side-by-side comparison using 1.6 Tb/s ports, optical cables can consume up to 20 watts of power, vs. virtually none for copper.\n\nThat gap has major implications at scale. In massive AI installations with thousands of connections, optical power draw can quickly add up to a meaningful share of a facility’s total energy usage.\n\nDespite its efficiency, copper has a hard physical limitation: distance. As data rates increase, the maximum length of passive copper cables shrinks dramatically.\n\nAt common speeds—such as 1Gb/s—copper Ethernet cables can span long distances without issue. But at the speeds used inside AI systems, the story changes. At roughly 200 Gb/s per lane, passive copper connections are limited to only a few meters, typically around two to three meters. Beyond that, signal integrity breaks down and fiber becomes inevitable, said Shainer.\n\nThis constraint shapes how modern data centers are built. Copper is ideal for scale‑up networking, such as connecting GPUs within the same rack, where distances are short. Scale‑out networking—linking racks across rows, halls, or entire buildings—requires fiber optics.\n\nFiber also matches copper in raw speed potential. Both media can support extremely high data rates, but fiber maintains those speeds over vastly longer distances. The tradeoff is higher cost, greater fragility, and significantly higher power consumption. Copper cables are physically tough and difficult to damage. Fiber cables contain delicate glass strands that can break if bent or mishandled.\n\nTo reduce the energy penalty of fiber, chip and networking designers are rethinking how optical components are integrated. A newer approach being taken by companies like Point2 and others is co‑packaged optics, which places the optical engine directly next to the switch ASIC.\n\nCPO dramatically shortens the electrical path, reducing power consumption. In this configuration, the same 1.6 Tb/s port can consume about five watts instead of 20, according to Shainer.\n\nSo fiber and copper are not in either/or solution, they must coexist, with copper covering short distances and fiber covering long distance. “I don’t see that there’s one versus the other. I see them as two elements that you use when you design or build an AI factory. I cannot imagine someone that will say, I can use copper, but I choose not to, because it doesn’t really make sense,” he said.",
  "title": "How AI is changing copper, fiber networking"
}