Gigabit to Exbibit

1 Gbps (gigabit) broadband delivers up to 125 MB/s, which is more than sufficient for most households. It supports dozens of simultaneous 4K streams, fast game downloads, and video conferencing with headroom to spare. The limiting factor is usually the Wi-Fi router (Wi-Fi 5 maxes out around 400–600 Mbps in practice) or the speed of the remote server you're downloading from.

10 Gbps networking is standard in data centers, server interconnects, and high-performance workstations doing large file transfers (video editing, database backups). It is increasingly available in prosumer home networking equipment. At 10 Gbps, a 1 TB file transfer takes about 13 minutes under ideal conditions.

One terabit equals 1,000 gigabits (SI). Terabit-per-second (Tbps) speeds are used in long-haul fiber optic cables and internet backbone infrastructure. A single transatlantic fiber cable typically carries hundreds of terabits per second across many multiplexed channels.

Wi-Fi 5 (802.11ac) delivers up to 3.5 Gbps theoretical, but typically 400–600 Mbps real-world on a single device. Wi-Fi 6 (802.11ax) reaches 9.6 Gbps theoretical and 600–900 Mbps practical per device, with better multi-device handling via OFDMA. Wi-Fi 6E extends the same technology into the uncongested 6 GHz band, improving real-world speeds to 1–2 Gbps. Wi-Fi 7 (802.11be) pushes the theoretical maximum to 46 Gbps using 320 MHz channels and 4096-QAM, with real-world single-device speeds expected around 2–5 Gbps — the first Wi-Fi standard to reliably exceed gigabit in practice.

Modern data centers handle enormous simultaneous traffic between thousands of servers — cloud computing, video streaming, and AI training all require massive internal bandwidth. 100 Gbps links between switches are now standard; 400 Gbps is increasingly deployed for spine connections. At these speeds, a single link can move 50 GB of data per second, keeping pace with NVMe storage arrays and GPU memory transfer rates.

An exabit (Ebit) = 10¹⁸ bits (SI decimal). An exbibit (Eibit) = 2⁶⁰ bits ≈ 1.1529 × 10¹⁸ bits (IEC binary). Exbibit is 15.29% larger — the cumulative product of using 1,024 instead of 1,000 at each of six prefix steps. This is the largest practically relevant SI vs IEC gap for bit units in current storage contexts.

Exbibit is used in: computer science academic literature on exascale computing, theoretical storage system design papers, and formal IEC/IEEE standards. No commercial product, OS, or consumer application currently displays exbibits. It is primarily a unit for academic and standards consistency — ensuring the IEC prefix family extends uniformly from kibi- to exbi- (and beyond to zebi- and yobi-).

After exbibit (Eibit, 2⁶⁰ bits) come: zebibit (Zibit, 2⁷⁰ bits) and yobibit (Yibit, 2⁸⁰ bits). These are defined in the IEC 80000-13 standard but have no current practical applications. The IEC binary prefix family deliberately mirrors the SI prefix family, ensuring consistent naming as computing scale continues to grow.

Frontier (Oak Ridge, 2022) achieved 1.194 exaFLOPS, with its Slingshot-11 fabric moving data at aggregate rates measurable in exbibits per second across 9,408 nodes. Aurora (Argonne, 2024) targets similar throughput with over 63,000 GPUs. At these scales, a single checkpoint of a full-system simulation can exceed 1 Eibit of state data, making exbibit a natural unit for describing I/O bandwidth requirements.

The IEC currently defines up to yobibit (Yibit, 2⁸⁰ bits). In 2022, the SI system added ronna- (10²⁷) and quetta- (10³⁰), but the IEC has not yet created matching binary prefixes (ronnibit? quettibit?). With global data creation projected to exceed 1 yottabit annually by the 2030s, pressure is mounting for the IEC to extend the binary prefix family — though the naming convention ("ronnibi-"?) remains an open question.