Elliptical Motion: Formulating Object Motion & Finding Theta

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In summary, the conversation discusses how to formulate the elliptical motion of an object observed while moving linearly in front of an observer. This is done by considering the velocity (v) and perpendicular distance (x) from the observer, and finding the rate of change of theta with respect to the observer. The equation of motion for an ellipse is then used to determine the lateral component as a function of time, assuming the observer is far away. The position angle (theta) is also discussed, and the general equation for an observer at a position angle (theta_o) is given.
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vaishakh
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How can we formulate the elliptical motion of an object apparently observed by us when it moves linearly infront of us. The position vector with respect to us makes an elliptical motion at that time. To start with let's take the velocity as v, the perpendicular distance of the line of motion from observer as x and now find the rate of change of theta with respect to us.
 
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One could right the equation of motion for an ellipse, and then determine the lateral component as a function of time with respect to the line of the observer. Assume that the observer is far way. If [itex]\theta[/itex] is the position angle with respect of the object from some reference, say the major axis, then one could write the general equation for an observer at [itex]\theta_o[/itex]
 
  • #3


I would first like to clarify that elliptical motion refers to the path followed by an object with a constant speed, where the distance from a fixed point (the focus) to the object is always proportional to the distance from the object to a fixed line (the directrix). This type of motion is commonly seen in celestial bodies, such as planets orbiting around a star.

To formulate the elliptical motion of an object observed by us when it moves linearly in front of us, we need to consider the position vector of the object with respect to us. This position vector will describe the location of the object at any given time, and it will change as the object moves.

If we consider the velocity of the object as v and the perpendicular distance of the line of motion from the observer as x, we can use trigonometric functions to describe the position vector and its relationship to the angle theta. The position vector can be represented as a function of theta, which will give us the distance of the object from the observer at any given angle.

To find the rate of change of theta with respect to us, we can use the chain rule of differentiation. This will give us the angular velocity of the object, which describes how quickly the angle theta changes with respect to time. This angular velocity will be constant for an object moving in an elliptical motion.

In conclusion, by considering the position vector, velocity, and angle theta, we can formulate the elliptical motion of an object observed by us when it moves linearly in front of us. This type of motion can be described using mathematical equations and can be used to accurately predict the path of the object in the future.
 

1. What is elliptical motion?

Elliptical motion is a type of circular motion in which an object follows a path that forms an ellipse. This means that the object moves in a curved path, but the distance between the object and a fixed point (known as the focus) changes constantly.

2. How is elliptical motion formulated?

Elliptical motion can be formulated using mathematical equations such as Kepler's laws of planetary motion. These laws describe the relationship between the distance of an object from the focus and the time it takes to complete one orbit. This helps us understand the motion of objects in our solar system, such as planets and comets.

3. What is the significance of theta in elliptical motion?

Theta (θ) is the angle between the position of an object and the focus in an elliptical orbit. It is used to determine the position of the object at any given time and is an important factor in calculating the speed and direction of the object's motion.

4. How is theta calculated in elliptical motion?

Theta can be calculated using trigonometric functions such as sine, cosine, and tangent. The specific formulas used depend on the type of elliptical orbit and the position of the object in the orbit. These calculations are essential for accurately predicting the motion of objects in space.

5. What are some real-life examples of elliptical motion?

Elliptical motion can be observed in many natural phenomena, such as the orbit of the Earth around the Sun, the motion of the Moon around the Earth, and the path of comets in our solar system. It is also used in man-made objects, such as satellites and spacecraft, which follow elliptical orbits around the Earth.

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