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Travel Time between Coordinates

vCalc Reviewed
`t = (f(( lat_2 - lat_1 ) and ( lon_2 - lon_1 ))) / "v" `
`(lat_1)"Starting Latitude"`
`(lon_1)"Stating Longitude"`
`(lat_2)"Ending Latitude"`
`(lon_2)"Ending Longitude"`
`(V) "Average Speed"`

The Haversine Travel Time between Coordinates calculator computes the time to travel between to points on the globe in a great circle arc at an average velocity. 

INSTRUCTIONS: Enter the following:

  • (Lat 1) Starting latitude
  • (Lon 1) Stating Longitude
  • (Lat 2) Ending Latitude
  • (Lon 2) Ending Longitude
  • (V) Average Speed

Travel Time (t): The calculator returns the time required to travel between the points in days, hours and minutes (dd:hh:mm).  The results include the distance traveled in kilometers, miles (statute) and nautical miles.

The Math / Science

The Haversine Travel Time calculator uses the Haversine equation to compute the distance between two points (x and y) on the Earth.  It then uses a mean velocity (speed) to calculate the time necessary to travel between the two points on the globe.
The time of travel is calculated by dividing the distance traveled by the average velocity.  This formula allows the user to enter two points on the globe in latitude and longitude, and a speed.  This formula uses the Haversine formula to approximate the distance between the two points.  The Haversine formula is based on a spherical earth model employing the Earths mean radius.  

Example

This formula will provide a fairly accurate estimate on the amount of time it would take a tsunami to travel between two points.  The velocity of a tsunami is reported to be 500 miles per hours when in deep water (See U.S. Gov Report).

Navigation Calculators:

Great Circle Calculators

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  • Haversine - DistanceComputes the distance between two points on a spherical model of the Earth along a great circle arc.  This also includes the rhumb line distance and azimuth for the rhumb line.
  • Travel Time between CoordinatesComputes the time to travel between to points on the globe in a great circle arc at an average velocity. 
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