Nanohertz to Megahertz

It sounds absurd, but nanohertz signals are real — they just unfold on geological or cosmic timescales. Pulsar timing arrays detect them by recording tiny shifts in pulsar pulse arrivals over decades. The signal is there the whole time; you simply need a clock patient enough (and stable enough) to notice it. Think of it like tracking the slow wobble of a spinning top filmed over years.

In 2023 NANOGrav announced strong evidence for a gravitational-wave background at roughly 1–100 nHz. The likely source is thousands of supermassive black-hole pairs spiralling toward merger across the universe. Each pair radiates gravitational waves so low-pitched that one full wave cycle can take years to pass through our solar system.

Any conventional oscillator drifts far more than a nanohertz over the time needed to observe one cycle. Millisecond pulsars serve as nature's most stable clocks — their spin is predictable to parts in 10¹⁵. By comparing dozens of these cosmic clocks scattered across the sky, astronomers tease out correlated timing shifts smaller than 100 nanoseconds spread over 15+ years.

The Chandler wobble is a small, slow oscillation of Earth's rotational axis around its figure axis, with a period of about 433 days — roughly 27 nHz. It was discovered by Seth Carlo Chandler in 1891 and is thought to be sustained by pressure fluctuations on the ocean floor. Without it, Earth's axis would settle to a fixed orientation within about 70 years.

Not intentionally. No engineered oscillator is designed to cycle once per decade. However, economic cycles, climate oscillations like El Niño (~50–80 nHz), and solar magnetic-field reversals (~1 nHz) are naturally recurring processes that scientists analyse in the nanohertz band using spectral methods borrowed from signal processing.

IBM needed a clock that could derive both the CPU timing and the NTSC color-burst frequency (3.579545 MHz) for the built-in composite video output. Multiplying the color-burst frequency by 4/3 gave 4.77 MHz — a convenient compromise that let one crystal oscillator serve two purposes. The weird number was pure engineering pragmatism, not performance targeting.

The 433.05–434.79 MHz range is an ISM (Industrial, Scientific, Medical) band that is license-free in most of Europe. Cheap remote-control key fobs, weather stations, garage door openers, and IoT sensors all crowd into it because you can legally transmit at low power without a radio license. In the US, the equivalent unlicensed band is 315 MHz, which is why European and American car key fobs are not interchangeable.

AM encodes audio by varying the wave's amplitude, which is vulnerable to electrical interference (lightning, motors). FM varies the frequency instead, making it inherently noise-resistant. FM also has a wider channel bandwidth (200 kHz vs. AM's 10 kHz), allowing it to carry the full 20–15,000 Hz audio spectrum in stereo. The MHz carrier frequency itself isn't what improves quality — it's the modulation method and bandwidth.

Intel and AMD marketed processors by clock speed — 500 MHz, 1 GHz, 2 GHz — implying faster was always better. By 2004, Intel's Pentium 4 hit 3.8 GHz but ran so hot and consumed so much power that performance-per-watt cratered. The industry pivoted to multi-core designs: instead of one core at 4 GHz, you got two or four cores at 2 GHz each, doing more total work with less heat. Raw megahertz stopped being a useful buying metric.

Bluetooth operates in the 2.4 GHz ISM band (2,400–2,483.5 MHz), which is reserved globally for unlicensed use. This avoids the need for regulatory approval in each country. The trade-off is sharing the band with Wi-Fi, microwaves, and baby monitors. Bluetooth mitigates interference by hopping between 79 channels 1,600 times per second — if one frequency is jammed, it has already moved on.