Mach Number Converter
Convert Mach number to speed in MPH, KPH, and m/s at different altitudes. Enter values for instant results with step-by-step formulas.
Formula
Speed = Mach x Speed of Sound; Speed of Sound = 20.05 x sqrt(T in Kelvin) m/s
The speed of sound varies with temperature. At sea level (15 C), it is approximately 340.3 m/s or 761.2 MPH. At cruise altitude (36,000+ ft, -56.5 C), it drops to about 295 m/s or 660 MPH. Multiply by Mach number to get actual speed.
Worked Examples
Example 1: Concorde Cruising Speed
Problem: The Concorde cruised at Mach 2.04 at 60,000 feet altitude. Calculate the actual speed in MPH, KPH, and knots.
Solution: Temperature at 60,000 ft (in stratosphere) = -56.5 C = 216.65 K\nSpeed of sound = 20.05 x sqrt(216.65) = 295.1 m/s = 660.1 MPH\nAircraft speed = 2.04 x 660.1 = 1,346.6 MPH\nIn KPH = 1,346.6 x 1.60934 = 2,167.6 KPH\nIn knots = 1,346.6 x 0.868976 = 1,170.0 knots\nMach cone half-angle = arcsin(1/2.04) = 29.3 degrees
Result: Mach 2.04 at 60,000 ft = 1,346.6 MPH = 2,167.6 KPH = 1,170.0 knots
Example 2: Fighter Jet at Low Altitude
Problem: A fighter jet reaches Mach 1.2 at sea level (15 C). What are the equivalent speeds?
Solution: Temperature = 15 C = 288.15 K\nSpeed of sound = 20.05 x sqrt(288.15) = 340.3 m/s = 761.2 MPH\nAircraft speed = 1.2 x 761.2 = 913.4 MPH\nIn KPH = 913.4 x 1.60934 = 1,470.3 KPH\nIn knots = 913.4 x 0.868976 = 793.8 knots\nRegime: Transonic (near boundary of supersonic)
Result: Mach 1.2 at sea level = 913.4 MPH = 1,470.3 KPH = 793.8 knots
Frequently Asked Questions
What is a Mach number and what does it represent?
The Mach number is a dimensionless quantity representing the ratio of an object speed to the local speed of sound. Named after Austrian physicist Ernst Mach, it is calculated by dividing the object velocity by the speed of sound at the current atmospheric conditions. A Mach number of 1.0 means the object is traveling exactly at the speed of sound, Mach 2.0 means twice the speed of sound, and Mach 0.5 means half the speed of sound. Unlike fixed speed units like MPH or KPH, the actual speed corresponding to a given Mach number changes with temperature and altitude because the speed of sound varies with atmospheric conditions. This makes Mach number particularly useful in aerodynamics because the behavior of airflow around an aircraft depends on the Mach number, not the absolute speed.
What are the different flight regimes defined by Mach number?
Aerodynamicists classify flight into four distinct regimes based on Mach number, each with fundamentally different airflow characteristics. Subsonic flight occurs below Mach 0.8, where airflow around the aircraft remains entirely below the speed of sound and conventional aerodynamic principles apply. The transonic regime spans Mach 0.8 to 1.2, where some regions of airflow around the aircraft exceed the speed of sound while others remain subsonic, creating complex shock wave interactions and buffeting. Supersonic flight ranges from Mach 1.2 to 5.0, where the entire airflow exceeds the speed of sound and well-defined shock waves form at predictable angles. Hypersonic flight begins above Mach 5.0, where aerodynamic heating becomes extreme and air molecules can dissociate and ionize, requiring entirely different design approaches.
What is a sonic boom and how does it relate to Mach number?
A sonic boom is the loud explosive sound heard on the ground when an aircraft flies faster than Mach 1.0 and the shock wave cone intersects the ground. As an aircraft approaches and exceeds the speed of sound, air molecules cannot move out of the way fast enough and pile up into a cone-shaped shock wave extending behind the aircraft. The half-angle of this Mach cone equals the arcsine of 1 divided by the Mach number, so at Mach 2.0 the cone has a 30-degree half-angle, and at Mach 3.0 it narrows to about 19.5 degrees. The boom is not a one-time event at the moment of breaking the sound barrier but a continuous phenomenon that follows the aircraft along its supersonic flight path. The intensity depends on aircraft size, altitude, and atmospheric conditions.
Why can commercial aircraft not fly faster than about Mach 0.85?
Commercial aircraft are designed to cruise in the high subsonic range, typically Mach 0.78 to 0.85, for several practical and economic reasons. As an aircraft approaches Mach 1.0, shock waves begin forming on the wings and fuselage in the transonic regime, dramatically increasing drag in a phenomenon called wave drag. This drag increase requires substantially more fuel to overcome, making speeds above Mach 0.85 economically impractical for conventional jet designs. The fuel consumption roughly doubles when going from Mach 0.85 to Mach 1.0. Additionally, the transonic shock waves cause buffeting, control difficulties, and structural stress that require specialized (and expensive) airframe designs. The Concorde achieved Mach 2.0 cruise but consumed three to four times more fuel per passenger-mile than subsonic jets, which ultimately made it commercially unviable.
How is Mach number measured on aircraft?
Aircraft measure Mach number using a Machmeter, which calculates the ratio between impact pressure and static pressure measured by the pitot-static system. The pitot tube, mounted on the nose or wing of the aircraft, measures total (ram) pressure as air is brought to rest at the tube opening. Static ports on the fuselage measure the undisturbed atmospheric pressure. The ratio of these pressures is directly related to Mach number through isentropic flow equations for subsonic speeds and normal shock relations for supersonic speeds. Modern aircraft use Air Data Computers that process the raw pressure measurements along with temperature data to calculate Mach number, true airspeed, altitude, and other parameters digitally. At supersonic speeds, specialized pitot probes must account for the normal shock wave that forms ahead of the tube.
What is the relationship between Mach number and aerodynamic heating?
Aerodynamic heating increases dramatically with Mach number because kinetic energy of the airstream converts to thermal energy when air is decelerated near the aircraft surface. The stagnation temperature, the maximum temperature at the point where air is brought completely to rest, follows the formula: stagnation temperature equals ambient temperature times (1 plus 0.2 times Mach squared) for air. At Mach 1.0, stagnation temperature is about 60 degrees Celsius above ambient. At Mach 2.0, it rises to about 240 degrees above ambient. At Mach 3.0, the increase is roughly 540 degrees above ambient. At Mach 5.0, stagnation temperatures exceed 1,200 degrees Celsius even in the cold upper atmosphere. This heating is the primary engineering challenge for high-speed flight and is why the Space Shuttle needed thermal protection tiles for re-entry at approximately Mach 25.