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The basic definition of speed is: speed = distance / time Solve this equation for distance, or solve it for time, to get two additional versions of the equation.
Speed=distance/time. Speed is in meters per second if distance is in meters, and time is in seconds. Using simple algebra, the equation can be rearranged to solve for a missing variable (speed, distance, or time). therefore: distance=speed x time time= distance/speed
speed = distance ÷ time
speed = distance/time
Speed*Time = Distance
The basic definition of speed is: speed = distance / time Solve this equation for distance, or solve it for time, to get two additional versions of the equation.
Use the equation, speed = distance / time, substitute in the given information from the problem and solve it.
Mass and force are directly proportional, therefore: more mass = greater force (Equation: F = ma). Mass and speed are inversely proportional, so: more mass = lesser speed (Equation: p = mv).
it is just the same equation for average speed v=d/t, unless the object is accelerating. Then the formula is v(instant) = v(initial) + at.
The speed of the satellite is dependant on its distance from the surface of the planet. the greater the altitude, the greater the speed, or velocity. I would think that Velocity Equation would be a simple linear equation of the form; y=kx, where k is a constant. What that constant is for Mars, I do not know as I did not do Astronomy at Uni, only Physics subjects.
Speed=distance/time. Speed is in meters per second if distance is in meters, and time is in seconds. Using simple algebra, the equation can be rearranged to solve for a missing variable (speed, distance, or time). therefore: distance=speed x time time= distance/speed
Speed= Distance/Time
The Speed Hoff Solve. The Speed Hoff Solve.
Dimensional analysis allows you to convert between non-alike units of measure. Set up your given measurements as a proportion, and solve for the location that is standing in for the missing value.
speed = distance/time
The speed of sound in water is greater than the speed of sound in air . For example, at 20 °C and 1 ATM pressure, the speed of sound in air is 343 m/s, and its speed in water is 1482 m/s. In general, the speed of sound in a medium = (bulk modulus of the medium/ its density)^0.5 where the bulk modulus indicates how compressible the medium is; the greater the bulk modulus, the more incompressible the medium is. So, although water has a density much greater than that of air, water is also much more incompressible than air. When you solve for the speed of sound for both water and air using the above formula, you will find that it is greater in water.
speed = distance/time