Convert wavelength in hectometres to dekahertz [daHz] Online | Free frequency-wavelength Converter

Describing Very Low Frequency Radio Waves

A hectometre (hm) is a unit of length equal to 100 metres, and it is used to describe very long wavelengths in the Very Low Frequency (VLF) and Low Frequency (LF) bands of the electromagnetic spectrum. Wavelengths in the hectometre range correspond to frequencies between approximately 3 kHz and 3 MHz. These long wavelengths are typically used for maritime navigation, military submarine communication, AM radio broadcasting, and time signal transmissions.

For example, a signal at 300 kHz has a wavelength of 1 kilometre, or 10 hectometres, and a signal at 1 MHz corresponds to 3 hectometres. These long wavelengths have the unique ability to travel long distances and penetrate water and the ground, which is why they are used in submarine communications and emergency broadcast systems.

Using hectometres to express wavelength offers a practical scale for understanding wave propagation over great distances. It also aids in antenna design, where very large antennas—often hundreds of metres long—are needed to efficiently transmit or receive these frequencies. Understanding wavelength in hectometres is important in geophysics, radio astronomy, and large-scale communications infrastructure.

Frequencies in the Tens of Hertz

The dekahertz (daHz) is a unit of frequency equal to 10 hertz (10¹ Hz), meaning there are 10 cycles per second. This frequency range is significant in many fields, including acoustics, electronics, and communications, where oscillations occur in the lower audio and signal processing bands.

In acoustics, frequencies around dekahertz values fall within the lower range of human hearing, which spans roughly from 20 Hz to 20,000 Hz. Sounds at 10 Hz, though below typical hearing thresholds, can be felt as vibrations, especially in certain environments like heavy machinery or seismic activity.

In electronics and signal processing, dekahertz frequencies are important for analyzing signals such as low-frequency radio transmissions, audio signals, and mechanical vibrations. These frequencies are relevant for technologies like sonar, medical ultrasound imaging, and certain communication systems.

In addition, dekahertz frequencies play a role in studying natural phenomena, such as seismic waves and biological rhythms, where oscillations occur on the order of tenths of a second.

Understanding and utilizing dekahertz frequencies enables engineers and scientists to design devices and systems that interact with signals in the low-frequency audio and vibration ranges, bridging the gap between infrasonic and audible frequencies.