Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity Solution

STEP 0: Pre-Calculation Summary
Formula Used
Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly)))
rh = hh^2/([GM.Earth]*(1+eh*cos(θ)))
This formula uses 1 Constants, 1 Functions, 4 Variables
Constants Used
[GM.Earth] - Earth’s Geocentric Gravitational Constant Value Taken As 3.986004418E+14
Functions Used
cos - Cosine of an angle is the ratio of the side adjacent to the angle to the hypotenuse of the triangle., cos(Angle)
Variables Used
Radial Position in Hyperbolic Orbit - (Measured in Meter) - Radial Position in Hyperbolic Orbit refers to the distance of the satellite along the radial or straight-line direction connecting the satellite and the center of the body.
Angular Momentum of Hyperbolic Orbit - (Measured in Squaer Meter per Second) - Angular Momentum of Hyperbolic Orbit is a fundamental physical quantity that characterizes the rotational motion of an object in orbit around a celestial body, such as a planet or a star.
Eccentricity of Hyperbolic Orbit - Eccentricity of Hyperbolic Orbit describes how much the orbit differs from a perfect circle, and this value typically falls between 1 and infinity.
True Anomaly - (Measured in Radian) - True Anomaly measures the angle between the object's current position and the perigee (the point of closest approach to the central body) when viewed from the focus of the orbit.
STEP 1: Convert Input(s) to Base Unit
Angular Momentum of Hyperbolic Orbit: 65700 Square Kilometer per Second --> 65700000000 Squaer Meter per Second (Check conversion ​here)
Eccentricity of Hyperbolic Orbit: 1.339 --> No Conversion Required
True Anomaly: 109 Degree --> 1.90240888467346 Radian (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
rh = hh^2/([GM.Earth]*(1+eh*cos(θ))) --> 65700000000^2/([GM.Earth]*(1+1.339*cos(1.90240888467346)))
Evaluating ... ...
rh = 19198371.6585885
STEP 3: Convert Result to Output's Unit
19198371.6585885 Meter -->19198.3716585885 Kilometer (Check conversion ​here)
FINAL ANSWER
19198.3716585885 19198.37 Kilometer <-- Radial Position in Hyperbolic Orbit
(Calculation completed in 00.020 seconds)

Credits

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Created by Harsh Raj
Indian Institute of Technology, Kharagpur (IIT KGP), West Bengal
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Verified by Kartikay Pandit
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Hperbolic Orbit Parameters Calculators

Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity
​ LaTeX ​ Go Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly)))
Semi-Major Axis of Hyperbolic Orbit given Angular Momentum and Eccentricity
​ LaTeX ​ Go Semi Major Axis of Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(Eccentricity of Hyperbolic Orbit^2-1))
Perigee Radius of Hyperbolic Orbit given Angular Momentum and Eccentricity
​ LaTeX ​ Go Perigee Radius = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit))
Turn Angle given Eccentricity
​ LaTeX ​ Go Turn Angle = 2*asin(1/Eccentricity of Hyperbolic Orbit)

Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity Formula

​LaTeX ​Go
Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly)))
rh = hh^2/([GM.Earth]*(1+eh*cos(θ)))

What is True Anomaly ?


True anomaly is a concept used in orbital mechanics to describe the position of an object in an elliptical orbit relative to its primary focus, typically a celestial body like a planet or a star. In simpler terms, true anomaly measures the angle between the current position of the orbiting object (usually a satellite or a planet) and the point of periapsis (closest approach to the primary body) as observed from the primary body.

How to Calculate Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity?

Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity calculator uses Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly))) to calculate the Radial Position in Hyperbolic Orbit, The Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity formula is defined as distance from the center of the central body to the current location of the object within the hyperbolic orbit, tformulahis formula allows for the calculation of the radial position based on three essential parameters: angular momentum, true anomaly, and eccentricity. Radial Position in Hyperbolic Orbit is denoted by rh symbol.

How to calculate Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity using this online calculator? To use this online calculator for Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity, enter Angular Momentum of Hyperbolic Orbit (hh), Eccentricity of Hyperbolic Orbit (eh) & True Anomaly (θ) and hit the calculate button. Here is how the Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity calculation can be explained with given input values -> 19.19837 = 65700000000^2/([GM.Earth]*(1+1.339*cos(1.90240888467346))).

FAQ

What is Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity?
The Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity formula is defined as distance from the center of the central body to the current location of the object within the hyperbolic orbit, tformulahis formula allows for the calculation of the radial position based on three essential parameters: angular momentum, true anomaly, and eccentricity and is represented as rh = hh^2/([GM.Earth]*(1+eh*cos(θ))) or Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly))). Angular Momentum of Hyperbolic Orbit is a fundamental physical quantity that characterizes the rotational motion of an object in orbit around a celestial body, such as a planet or a star, Eccentricity of Hyperbolic Orbit describes how much the orbit differs from a perfect circle, and this value typically falls between 1 and infinity & True Anomaly measures the angle between the object's current position and the perigee (the point of closest approach to the central body) when viewed from the focus of the orbit.
How to calculate Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity?
The Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity formula is defined as distance from the center of the central body to the current location of the object within the hyperbolic orbit, tformulahis formula allows for the calculation of the radial position based on three essential parameters: angular momentum, true anomaly, and eccentricity is calculated using Radial Position in Hyperbolic Orbit = Angular Momentum of Hyperbolic Orbit^2/([GM.Earth]*(1+Eccentricity of Hyperbolic Orbit*cos(True Anomaly))). To calculate Radial Position in Hyperbolic Orbit given Angular Momentum, True Anomaly, and Eccentricity, you need Angular Momentum of Hyperbolic Orbit (hh), Eccentricity of Hyperbolic Orbit (eh) & True Anomaly (θ). With our tool, you need to enter the respective value for Angular Momentum of Hyperbolic Orbit, Eccentricity of Hyperbolic Orbit & True Anomaly and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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