Megabit to Exbibyte

Divide Mbps by 8 to get megabytes per second (MB/s). A 100 Mbps connection = 12.5 MB/s. A 1 Gbps connection = 125 MB/s. This conversion is essential when comparing advertised internet speeds (always in Mbps) to actual file download speeds (shown in MB/s by browsers and download managers).

Netflix recommends 25 Mbps for 4K Ultra HD. Disney+ and Apple TV+ recommend 25 Mbps; YouTube recommends 20 Mbps for 4K. These are per-stream figures — a household streaming two 4K sources simultaneously needs roughly 50 Mbps of reliable throughput, plus headroom for other devices.

ISP speed ratings are theoretical maximums under ideal conditions. Real-world factors include network congestion, router quality, Wi-Fi interference, the server's upload speed, and protocol overhead. Additionally, browsers and download managers report speeds in MB/s (bytes), which is 8× smaller than the Mbps figure — a 100 Mbps plan showing 11 MB/s in a browser is performing normally.

One gigabit equals 1,000 megabits (SI decimal system). Gigabit broadband (1 Gbps) = 1,000 Mbps = 125 MB/s theoretical download speed. In the binary IEC system, one gibibit = 1,024 mebibits — but for internet speeds the SI decimal values are always used.

Fiber-to-the-home (FTTH) delivers symmetric speeds of 100–10,000 Mbps with consistent performance regardless of distance from the exchange. Cable (DOCSIS 3.1) offers 100–1,200 Mbps download but typically 10–50 Mbps upload, and throughput degrades during neighborhood peak hours due to shared bandwidth. DSL (VDSL2) maxes out at 50–100 Mbps download and drops sharply beyond 500 meters from the DSLAM cabinet. In practice, most cable users see 60–80% of advertised speeds; DSL users at distance may see under 50%. Fiber is the only technology that reliably delivers its rated megabit throughput.

EB (exabyte) = 10¹⁸ bytes (SI decimal). EiB (exbibyte) = 2⁶⁰ bytes = 1,152,921,504,606,846,976 bytes (IEC binary). EiB is 15.29% larger. This is the largest practically significant SI vs IEC discrepancy: per exbibyte, the binary value exceeds the decimal value by approximately 152,921,504,606,846,976 bytes — about 152.9 petabytes.

One exbibyte (EiB) ≈ 1.153 × 10¹⁸ bytes = 1,073,741,824 GiB = 1,048,576 TiB. In practical terms: enough to store approximately 230 billion JPEG photos at 5 MB each, or 288,230,376 copies of a 4 GB HD movie, or the entire text content of the English internet many thousands of times over.

In theory, yes — and with astonishing density. DNA can encode about 215 PiB per gram of material, meaning a single EiB could fit in roughly 4.7 grams of synthetic DNA. Researchers at Microsoft and the University of Washington have demonstrated writing and reading megabytes of data in DNA strands. The challenges are speed and cost: current DNA synthesis writes about 400 bytes per second and costs around $3,500 per megabyte. At that rate, writing 1 EiB would take billions of years and cost more than global GDP. However, enzymatic synthesis breakthroughs could reduce costs by 6–8 orders of magnitude within decades.

Storing 1 EiB on modern HDDs would require roughly 57,000 drives of 20 TB each, consuming about 400–500 kW of power just for the drives — plus 200–300 kW for cooling, networking, and overhead. That totals roughly 6 GWh per year, equivalent to powering about 550 US homes. At typical US grid carbon intensity, this produces around 2,500 tonnes of CO₂ annually. Hyperscale operators reduce this via renewable energy and immersion cooling, but the fundamental physics of spinning magnetic platters or maintaining NAND charge states sets a floor on energy consumption that no software optimisation can eliminate.

After exbibyte (EiB, 2⁶⁰ bytes) come: zebibyte (ZiB, 2⁷⁰ bytes) and yobibyte (YiB, 2⁸⁰ bytes), as defined in IEC 80000-13. These are recognized standard units but have no current practical applications. The entire global internet's estimated stored data (hundreds of EB) is still in the low hundreds of EiB range — well short of one ZiB.