Do things move in uniform motion in real life?

In summary, the Earth as a whole can be considered to be moving inertially, but its individual parts and objects on its surface are not, due to forces exerted by other parts. In summary, the conversation discusses the concept of uniform motion in outer space and on Earth, as well as the idea of an inertial frame and how it applies to the rotating Earth. The participants also touch on the symmetry and asymmetry of special and general relativity, and how the rotation of the Earth affects the motion of objects on its surface. Ultimately, it is concluded that while the Earth as a whole can be considered to be moving inertially, its individual parts and objects are not, due to forces exerted by other parts.
  • #1
goodabouthood
127
0
Does this actually happen in outer space? Do things actually move in uniform motion relative to each other?

How would this work for the Earth considering it's rotating?

Can the Earth ever be considered an inertial frame because it's always rotating?
 
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  • #2
goodabouthood said:
Does this actually happen in outer space? Do things actually move in uniform motion relative to each other?
No. Uniform, or inertial, motion means that something has never accelerated--never changed its speed or direction--which means that it has existed forever and "real life" has not existed forever.
goodabouthood said:
How would this work for the Earth considering it's rotating?

Can the Earth ever be considered an inertial frame because it's always rotating?
No, but we can approximate, so for short periods of time and for short distances, and ignoring the effects of gravity, it works good enough.
 
  • #3
I thought an inertial frame cannot be one that is rotating.

Does the symmetry of SR actually exist in space?

Isn't it possible that things have reached a state where they are traveling together uniformly?
 
  • #4
Hmm.. I remember reading a while back, the book was Einstein’s Theory of Relativity (Born), in which it was said that uniform motion exists if the inertial reference frame is specified. He cleverly uses the example of a fixed ruler, a pencil, and a wheel (imagine a pottery wheel) to get his point across. Imagine the pencil moving along the ruler and the wheel rotating. To the observer fixed on the ruler, the motion seems uniform (straight), but to the one on the rotating disk, the motion is a curved line. Anyone feel free to correct me if i’m misinformed.
 
  • #5
If you’re looking for a very very correct answer (i don’t know what that means either :smile:) then no, nothing (to my knowledge) ever travels in uniform motion (especially on earth). The Earth is spinning, so something that seems to travel in straight lines actually travels in a slightly curved path. But according to the book, we don’t notice this because of the shortness of the paths used compared with the dimensions of the Earth (which someone already said). Once again correct me if i’m wrong.
 
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  • #6
goodabouthood said:
I thought an inertial frame cannot be one that is rotating.
You thought right.
goodabouthood said:
Does the symmetry of SR actually exist in space?
Yes, along with the asymmetry of GR and asymmetries of SR caused by less than perfectly inertially moving bodies.
goodabouthood said:
Isn't it possible that things have reached a state where they are traveling together uniformly?
No, why would you think that?
 
  • #7
You have to distinguish between an inertially moving body and an inertial frame. The rotating Earth is not an inertial body, but we can invision an inertial frame that contains the non-inertial rotating earth.
 
  • #8
ghwellsjr said:
You have to distinguish between an inertially moving body and an inertial frame. The rotating Earth is not an inertial body, but we can invision an inertial frame that contains the non-inertial rotating earth.

I would phrase this somewhat differently. The Earth as a whole, considered as a single object, is moving inertially, at least to a very good approximation. We know this because we can compute its motion using the assumption that it is moving inertially, i.e., that it is in free fall with its motion determined by nothing but gravity, and we get the right answer to a very good approximation.

However, most *parts* of the Earth are *not* moving inertially; they feel acceleration. This would be true even if the Earth were not rotating, because it is a large gravitating body and most of its parts, as well as objects gravitationally bound to its surface (like us), have forces exerted on them by other parts that push them into non-inertial states of motion. For example, we feel weight standing on the surface of the Earth because that surface pushes us upward, out of the freely falling path we would take if the surface were not there.

The rotation of the Earth, from the standpoint of what parts of it are or are not moving inertially, is only a fairly small correction to the above; it makes the Earth oblate to about one part in 300, and it causes small variations in the acceleration felt at different locations. For example, a person standing at the equator feels a little less weight than a person of identical mass standing at one of the poles.
 

1. Do objects always move in a straight line at a constant speed in real life?

No, not all objects move in a straight line at a constant speed in real life. Objects can change direction and speed due to various forces acting upon them, such as gravity, friction, or air resistance.

2. How does Newton's first law of motion apply to real life?

Newton's first law of motion, also known as the law of inertia, states that an object at rest will stay at rest and an object in motion will stay in motion at a constant velocity unless acted upon by an external force. This law applies to real life by explaining how objects behave when no forces are acting upon them.

3. Can objects move in uniform motion without an external force?

No, an object cannot move in uniform motion without an external force. In order for an object to move at a constant speed, there must be a force acting upon it to counteract any opposing forces, such as friction.

4. What is an example of uniform motion in real life?

An example of uniform motion in real life is a car traveling at a constant speed on a straight, flat road with no external forces acting upon it. The car will continue to move in a straight line at the same speed until an external force, such as applying the brakes or turning the steering wheel, is applied.

5. How does uniform motion differ from non-uniform motion?

Uniform motion is when an object moves at a constant speed in a straight line, while non-uniform motion is when an object changes its speed or direction. Non-uniform motion can occur when there is an external force acting upon the object, causing it to accelerate, decelerate, or change direction.

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