Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion Solution

STEP 0: Pre-Calculation Summary
Formula Used
Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)*(Mean Radius of the Earth^2/Distance from center of Earth to center of Moon^3)*Harmonic Polynomial Expansion Terms for Moon
VM = (f*M)*(RM^2/rm^3)*PM
This formula uses 6 Variables
Variables Used
Attractive Force Potentials for Moon - Attractive Force Potentials for Moon refers to the gravitational force exerted by the Moon on other objects, such as the Earth or objects on the Earth's surface.
Universal Constant - Universal Constant is a physical constant that is thought to be universal in its application in terms of Radius of the Earth and Acceleration of Gravity.
Mass of the Moon - (Measured in Kilogram) - Mass of the Moon refers to the total quantity of matter contained in the Moon, which is a measure of its inertia and gravitational influence [7.34767309 × 10^22 kilograms].
Mean Radius of the Earth - (Measured in Meter) - Mean Radius of the Earth is defined as the arithmetic average of the Earth's equatorial and polar radii.
Distance from center of Earth to center of Moon - (Measured in Meter) - Distance from center of Earth to center of Moon referred to the average distance from the center of Earth to the center of the moon is 238,897 miles (384,467 kilometers).
Harmonic Polynomial Expansion Terms for Moon - Harmonic Polynomial Expansion Terms for Moon refers to the expansions take into account the deviations from a perfect sphere by considering the gravitational field as a series of spherical harmonics.
STEP 1: Convert Input(s) to Base Unit
Universal Constant: 2 --> No Conversion Required
Mass of the Moon: 7.35E+22 Kilogram --> 7.35E+22 Kilogram No Conversion Required
Mean Radius of the Earth: 6371 Kilometer --> 6371000 Meter (Check conversion ​here)
Distance from center of Earth to center of Moon: 384467 Kilometer --> 384467000 Meter (Check conversion ​here)
Harmonic Polynomial Expansion Terms for Moon: 4900000 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
VM = (f*M)*(RM^2/rm^3)*PM --> (2*7.35E+22)*(6371000^2/384467000^3)*4900000
Evaluating ... ...
VM = 5.144597688615E+17
STEP 3: Convert Result to Output's Unit
5.144597688615E+17 --> No Conversion Required
FINAL ANSWER
5.144597688615E+17 5.1E+17 <-- Attractive Force Potentials for Moon
(Calculation completed in 00.020 seconds)

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Created by Mithila Muthamma PA
Coorg Institute of Technology (CIT), Coorg
Mithila Muthamma PA has created this Calculator and 2000+ more calculators!
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​ LaTeX ​ Go Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)/Distance of Point
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Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion Formula

​LaTeX ​Go
Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)*(Mean Radius of the Earth^2/Distance from center of Earth to center of Moon^3)*Harmonic Polynomial Expansion Terms for Moon
VM = (f*M)*(RM^2/rm^3)*PM

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The Tidal Force is a gravitational effect that stretches a body along the line towards the center of mass of another body due to a gradient (difference in strength) in gravitational field from the other body; it is responsible for diverse phenomena, including tides, tidal locking, breaking apart of celestial bodies.

How to Calculate Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion?

Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion calculator uses Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)*(Mean Radius of the Earth^2/Distance from center of Earth to center of Moon^3)*Harmonic Polynomial Expansion Terms for Moon to calculate the Attractive Force Potentials for Moon, The Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion formula is defined as to make the potential energy of the system decrease. As the atoms first begin to interact, the attractive force is stronger than the repulsive force and so the potential energy of the system decreases. Attractive Force Potentials for Moon is denoted by VM symbol.

How to calculate Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion using this online calculator? To use this online calculator for Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion, enter Universal Constant (f), Mass of the Moon (M), Mean Radius of the Earth (RM), Distance from center of Earth to center of Moon (rm) & Harmonic Polynomial Expansion Terms for Moon (PM) and hit the calculate button. Here is how the Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion calculation can be explained with given input values -> 5.1E+17 = (2*7.35E+22)*(6371000^2/384467000^3)*4900000.

FAQ

What is Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion?
The Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion formula is defined as to make the potential energy of the system decrease. As the atoms first begin to interact, the attractive force is stronger than the repulsive force and so the potential energy of the system decreases and is represented as VM = (f*M)*(RM^2/rm^3)*PM or Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)*(Mean Radius of the Earth^2/Distance from center of Earth to center of Moon^3)*Harmonic Polynomial Expansion Terms for Moon. Universal Constant is a physical constant that is thought to be universal in its application in terms of Radius of the Earth and Acceleration of Gravity, Mass of the Moon refers to the total quantity of matter contained in the Moon, which is a measure of its inertia and gravitational influence [7.34767309 × 10^22 kilograms], Mean Radius of the Earth is defined as the arithmetic average of the Earth's equatorial and polar radii, Distance from center of Earth to center of Moon referred to the average distance from the center of Earth to the center of the moon is 238,897 miles (384,467 kilometers) & Harmonic Polynomial Expansion Terms for Moon refers to the expansions take into account the deviations from a perfect sphere by considering the gravitational field as a series of spherical harmonics.
How to calculate Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion?
The Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion formula is defined as to make the potential energy of the system decrease. As the atoms first begin to interact, the attractive force is stronger than the repulsive force and so the potential energy of the system decreases is calculated using Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)*(Mean Radius of the Earth^2/Distance from center of Earth to center of Moon^3)*Harmonic Polynomial Expansion Terms for Moon. To calculate Attractive Force Potentials per unit Mass for Moon given Harmonic Polynomial Expansion, you need Universal Constant (f), Mass of the Moon (M), Mean Radius of the Earth (RM), Distance from center of Earth to center of Moon (rm) & Harmonic Polynomial Expansion Terms for Moon (PM). With our tool, you need to enter the respective value for Universal Constant, Mass of the Moon, Mean Radius of the Earth, Distance from center of Earth to center of Moon & Harmonic Polynomial Expansion Terms for Moon and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Attractive Force Potentials for Moon?
In this formula, Attractive Force Potentials for Moon uses Universal Constant, Mass of the Moon, Mean Radius of the Earth, Distance from center of Earth to center of Moon & Harmonic Polynomial Expansion Terms for Moon. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Attractive Force Potentials for Moon = (Universal Constant*Mass of the Moon)/Distance of Point
  • Attractive Force Potentials for Moon = Universal Constant*Mass of the Moon*((1/Distance of Point)-(1/Distance from center of Earth to center of Moon)-([Earth-R]*cos(Angle made by the Distance of Point)/Distance from center of Earth to center of Moon^2))
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