If f is a frequency in Hertz (Hz), then the corresponding MIDI note number N_MIDI is given by the formula

${\displaystyle N_{\mathsf {MIDI}}=69+12\cdot \log _{2}\left({\frac {f}{\ 440\ \mathrm {Hz} \ }}\right)=69+{\frac {12}{\ \log 2\ }}\log \left({\frac {f}{\ 440\ \mathrm {Hz} \ }}\right)\ ,}$ 

where "log" in the second expression is any logarithm (e.g. either the common logarithm log₁₀ , the natural logarithm ln ≡ log_e , or any other).

The quantity log₂(  f / 440 Hz  ) is the number of octaves above the 440 Hz concert A, or A₄, or a′ . Multiplying it by 12 gives the number of semitones above 440 Hz (the value is negative if the frequency f is lower in pitch than 440 Hz). Adding 69 (decimal, or 0x45 hexadecimal) gives the number of semitones above the C five octaves below middle C.

Not only is 440 Hz the standard central pitch for MIDI, it is also widely used as the "concert A" standard pitch (A₄ e.g. USA, UK), and since that is represented in MIDI signals by the integer 69 (nine semitones above middle C (C₄, c′), which is 60 decimal or 0x3C hexadecimal), this gives a real number which expresses pitch in a manner consistent with MIDI and integer notation, known as the MIDI note number, N_MIDI .

Converting from MIDI note number (N_MIDI) to frequency (f) is given by the following formula:

${\displaystyle \ f=440\ {\mathsf {Hz}}\cdot 2^{\left[\ \left(\ N_{\mathsf {MIDI}}\ -\ 69\ \right)/12\ \right]}\ =440\ {\mathsf {Hz}}\cdot \exp \left[\ {\frac {\ \ln 2\ }{12}}\left(\ N_{\mathsf {MIDI}}\ -\ 69\ \right)\ \right]~.}$ 

The frequency data format allows for the precise notation of frequencies that differ from equal temperament.

"Frequency data shall be defined in [units] which are fractions of a semitone. The frequency range starts at MIDI note 0, C = 8.1758 Hz, and extends above MIDI note 127, G = 12543.854 Hz. The first byte of the frequency data word specifies the highest equal-tempered semitone not exceeding the frequency. The next two bytes (14 bits) specify the fraction of 100 cents above the semitone at which the frequency lies. Effective resolution = 100 cents / 2¹⁴ = .0061 cents."^[1]

This higher resolution allows a logarithmic representation of pitch in which the semitone is divided into 128² = 2¹⁴ = 16384 parts, which means the octave is divided into 196608 (logarithmically) equal parts. These parts are exactly 100/16384 cents (approximately 0.0061 cents) in size, which is far below the threshold of human pitch perception and which therefore allows a very accurate representation of pitch.

The precision pitch values may be used in microtonal music, just intonation, meantone temperament, or other alternative tunings.

Software which supports MTS includes Scala, TiMidity++, ZynAddSubFX and FluidSynth.

Software plugin instruments which support MTS include Native Instruments FM8, Synthogy Ivory, and Xen-Arts' various xenharmonic VSTi plugins, including the FMTS FM synthesizer, Ivor virtual analog synthesizer, and XenFont SoundFont sample player.

Hardware instruments in current production which support MTS include: Dave Smith Instruments (DSI) Rev-2, Prophet-12, Prophet-6, Oberheim OB-6, Moog Sub37, Minitaur, Novation Bass Station II, Peak, Sonoclast Plastic Pitch Plus, and the Waldorf Kyra.

• Microtonal music
• Microtuner
• Musical tuning

MTS specification edit

• MTS specification

Microtonal music software supporting MTS edit

• Scala (Windows, Linux, Mac)
• Custom Scale Editor (Windows, Mac)
• microsynth (Windows, Mac)
• alt-tuner (Windows, Linux, Mac)
• TiMidity++ (Windows, Linux, Mac)
• FluidSynth (Windows, Linux, Mac)
• Tune Smithy (Windows)
• Xen-Arts Microtonal MIDI Software (Windows VSTi)
• Relayer (Windows, Mac)
• L'il Miss' Scale Oven (Mac)
• Gervill (Windows, Linux, Mac)