Calculate wavelength from frequency or frequency from wavelength. Supports all EM spectrum bands, refractive index, photon energy, wave number. Includes spectrum visual and reference table.
The wavelength of an electromagnetic wave is the distance between successive crests, related to frequency by λ = c/f, where c is the speed of light (299,792,458 m/s in vacuum). This fundamental relationship spans the entire electromagnetic spectrum — from radio waves kilometers long to gamma rays smaller than atomic nuclei.
In a medium with refractive index n, the speed of light slows to v = c/n, and the wavelength shortens to λ = c/(nf). The frequency does not change when entering a medium; only the wavelength and speed change. This is why light bends (refracts) at material boundaries.
This calculator converts between frequency and wavelength for any part of the EM spectrum. It computes photon energy (E = hf), wave number, and period. It identifies which frequency band your signal falls in (from ELF to UV) and displays it on a color-coded spectrum visual. A reference table lists common applications from AM radio to visible light with their frequencies and wavelengths.
Antenna design, optical engineering, RF planning, and spectroscopy all require converting between frequency and wavelength. A half-wave dipole antenna for WiFi at 2.4 GHz needs to be about 6.25 cm long. Knowing the photon energy tells you whether radiation can ionize atoms or trigger certain chemical reactions. This calculator handles all the conversions plus medium effects.
λ = v / f = c / (n × f) f = v / λ = c / (n × λ) Where: c = 299,792,458 m/s (speed of light) n = refractive index of medium v = c/n (phase velocity) Photon energy: E = h × f = hc/λ h = 6.626 × 10⁻³⁴ J·s Wave number: k = 1/λ (m⁻¹) or 2π/λ (rad/m)
Result: λ = 12.49 cm
At 2.4 GHz: λ = 299,792,458 / 2,400,000,000 = 0.1249 m = 12.49 cm. This is why WiFi antennas are typically 5-6 cm (quarter-wave). The photon energy is 9.93 μeV — far too low to ionize anything.
We swim in electromagnetic waves. FM radio (88-108 MHz, 2.8-3.4 m), cell phones (700 MHz-39 GHz), WiFi (2.4/5/6 GHz), Bluetooth (2.4 GHz), GPS (1.2/1.6 GHz), and microwave ovens (2.45 GHz) all use specific wavelengths chosen for propagation, bandwidth, and regulatory reasons. Understanding wavelength helps explain why 5G mmWave (28 GHz, λ=11 mm) has trouble penetrating buildings while FM radio (λ=3 m) propagates around obstacles.
The visible spectrum runs from violet (~380 nm) through blue, green, yellow, orange to red (~700 nm). Beyond red lies infrared (used for thermal cameras and fiber optics at 850/1310/1550 nm), and beyond violet is ultraviolet (used for sterilization at 254 nm). Lasers are specified by their precise wavelength: red HeNe at 632.8 nm, green DPSS at 532 nm, blue at 445 nm.
When light enters a material, it slows by the refractive index factor. In optical fiber (n ≈ 1.467 for silica at 1550 nm), the wavelength inside the fiber is 1550/1.467 ≈ 1057 nm, even though we label it "1550 nm" (the vacuum wavelength). This distinction matters for interference effects: thin film coatings, fiber Bragg gratings, and antireflection layers all depend on the wavelength inside the material, not the vacuum wavelength.
Exactly 299,792,458 m/s in vacuum (defined since 1983). In air it is 0.03% slower. In water it is 25% slower (n=1.33). In glass, about 33% slower (n=1.5). In diamond, 59% slower (n=2.42).
No. When light enters a denser medium, the wavelength shortens and the speed decreases, but the frequency remains the same. This is why refraction occurs — the wavefronts slow down and bend.
The continuum of all EM radiation ordered by frequency/wavelength: radio, microwave, infrared, visible, ultraviolet, X-ray, gamma ray. They are all the same phenomenon (oscillating electric and magnetic fields) at different frequencies. Only visible light (380-700 nm) is detectable by human eyes.
Convention and practicality. Visible light wavelengths (nm) are more intuitive than frequencies (hundreds of THz). Radio frequencies (kHz to GHz) are more practical than wavelengths (km to mm). Microwave engineers use both. The physics is identical.
Shorter wavelength = higher frequency = higher energy. E = hc/λ. A 400 nm violet photon has twice the energy of an 800 nm infrared photon. This is why UV causes sunburn but radio waves do not.
Antenna dimensions are proportional to wavelength. A half-wave dipole is λ/2 long. At 100 MHz (FM): λ = 3 m, half-wave = 1.5 m. At 5 GHz (WiFi): λ = 6 cm, half-wave = 3 cm. Higher frequencies allow smaller antennas but suffer greater attenuation.