Enter wavelength, select a medium, get omega fast. See frequency, period, and wavenumber together now. Download a report and compare sample calculations quickly here.
| # | Wavelength (λ) | Known input | Wave speed (v) | Frequency (f) | Angular frequency (ω) |
|---|---|---|---|---|---|
| 1 | 0.50 m | Light in vacuum | 2.9979×108 m/s | 5.9958×108 Hz | 3.7673×109 rad/s |
| 2 | 3.40 m | Sound in air (20 °C) | 343.4 m/s | 101.0 Hz | 634.6 rad/s |
| 3 | 532 nm | Refractive index n = 1.33 | 2.2548×108 m/s | 4.2385×1014 Hz | 2.6630×1015 rad/s |
Angular frequency (ω) describes how fast a wave’s phase rotates, measured in rad/s. It links directly to oscillators, resonators, motors, and electromagnetic signals, where phase is often more useful than cycles per second. In RF design, ω simplifies impedance formulas, and in mechanics it matches differential equations of springs, shafts, and beams.
This tool turns wavelength (λ) into frequency (f) and then ω using ω = 2πf. Because λ alone cannot define f, you also provide wave speed (v) or frequency. The calculator reports ω, f, period (T), and wavenumber (k).
For light in vacuum it uses c = 299,792,458 m/s. For light in a medium, it applies v = c/n. Typical n values: water ≈ 1.33, common glass ≈ 1.50, and acrylic ≈ 1.49, producing proportionally lower speeds and frequencies.
For acoustics the calculator can estimate v with v = 331.3 + 0.606·T (T in °C). At 0 °C, v ≈ 331.3 m/s; at 20 °C, v ≈ 343.4 m/s; at 40 °C, v ≈ 355.5 m/s, changing ω for the same λ.
Wavelength unit choices range from km to pm, plus Å for atomic scales. Halving λ doubles f and doubles ω when v is fixed. That scaling is helpful when checking results for antennas, lasers, and vibration problems. Scientific notation helps when results exceed typical display ranges.
The period T = 1/f gives time per cycle, useful for timing and sampling. The wavenumber k = 2π/λ gives phase change per meter and supports dispersion analysis. Together, ω and k describe traveling waves compactly.
After calculating, download CSV to archive values in spreadsheets or QA logs. Download PDF to attach a simple report to lab notes. For repeatability, record λ, the selected medium or speed mode, and the displayed precision.
You must enter wavelength and either wave speed or frequency. Wavelength alone cannot determine ω because the wave could travel at many different speeds in different media.
Use it for electromagnetic waves in materials like water, glass, or acrylic. The calculator applies v = c/n, so higher n reduces speed, frequency, and ω for the same wavelength.
It is an engineering approximation for dry air near normal pressure. It works well for quick estimates, but humidity, pressure, and gas composition can shift the true speed of sound.
The physics does not change, but numeric values do until units are converted consistently. The calculator converts your chosen unit to meters before computing f, ω, T, and k.
k = 2π/λ gives phase change per meter. It is useful in wave equations, interference, and dispersion work, and pairs naturally with ω when describing traveling waves.
High-frequency light and tiny wavelengths can produce very large ω values. Scientific notation keeps results readable and helps you copy consistent numbers into reports, CSV files, or calculations.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.