It would seem the literature has it that L1 is the lowest, just as these diagrams indicate.Integral said:
I'll give you that. However L2 should be ignorantly higher then all. That is not what I see on that plot. It is barely higher then L1. And is lost in the shadows of L4 and 5.DaveC426913 said:
The wiki page has a much higher rez diagram. I tried to post it here but its too large and I can't do much about that on my phone.Integral said:
You add the gravitational and centrifugal potential.Integral said:
It is the total effective potential in the rotating reference frame, where both massive bodies and the L-points are at rest. That is the reference frame where you have a time independent effective potential, so you can visualize the initial acceleration of bodies released at rest in that frame based on the slope of that potential. But as soon they start moving the Coriolis force kicks in, so the objects will circle around on plateaus, instead of directly sliding off them.Integral said:
L points are the stationary points of the effective potential (gravitational + centrifugal) in the rotating frameIntegral said:
The gravitational potential alone is only relevant in the inertial (non-rotating) frame, where the two massive bodies are moving. In this frame you don't have a static potential, but one that is rotating all the time, and the L points are not the stationary points of that potential, because they are moving in circles, so they must lie on slopes of the rotating gravitational potential to provide centripetal acceleration.Integral said:
No it doesn't. L2 is clearly a stationary point (saddle).Integral said:
In the rotating frame that is what happens.Integral said:
The correct pseudo potential has Earth and sun on "mountain tops" because of the centrifugal barrier. The blue arrows point uphill the red downhill visDaveC426913 said:
Perhaps for you,certainly not for me !Integral said:
And this all seems pretty straightforward to me once you get the signs right. Am I missing something?Fromthe Wikipedia arA.T. said:
You are confusing two types of "effective potential":hutchphd said:
As in: you think it's inverted?hutchphd said:
They are equivalent. You are misinterpreting the Wikipedia diagram:hutchphd said:
All arrows (blue & red) point downhill. I think the different colors are just used to emphasize the difference between maxima and saddle points.hutchphd said:
Which effective potential are you referring to?hutchphd said:
A.T. said:
This one. Isn't this the one depicted in the Wiki diagram? Won't you get the nice pseudopotential with a trough at the orbital radius and the sun behind the centrifugal barrier?A.T. said:
A.T. said:
Yes.hutchphd said:
No. As already explained, the "centrifugal barrier" occurs only for type 1) effective potential, where the angular velocity of the reference frame increases with decreasing distance of the test body to the massive body. So the centrifugal potential field in that frame changes.hutchphd said:
The halo orbit cannot be easily/directly explained in terms of 2D potentials alone, as it goes out of the orbital plane of the Earth. Additionally you have the Coriolis force (in the rotating frame), and orbital dynamics (in the inertial frame).Integral said:
I am still woefully confused here. The potential I wish to examine is in a frame fixed by the rotational speed of Earth about the sun which is roughly fixed at 1 rev per year. The "test" mass is the JWST and we look for "very slow" motion wrt that rotating frame. So in this frame I am looking at static equilibria. The frame I want has constant angular velocity with origin ~at the sun. The Earth is stationary and the Langrange points also.A.T. said:
Yes, and in this potential there is no "centrifugal barrier". Look at the video I linked above. The centrifugal potential slope decreases when you get closer to the frame rotation center (within the Sun), while the gravitational potential slope increases when you get closer to the Sun's surface. Combined you still have an increasing slope towards the Sun, when you get closer to it.hutchphd said:
Here is a more detailed explanation of the halo orbit based on vectors.Integral said:
Yes. Thank you, it finally sank in...don't know why that was so hard. And at my age I can always blame a small cerebral event. Thanks again !A.T. said:
I have seen them. They don't show the real situation, though. What counts is the Net Orbital Energy, including the Kinetic Energy because, with all orbits, the position and velocity of the object is a function of both. There is no 'explanation' for L2's existence if you don't include the velocity. Without the appropriate velocity, the gravitational forces are all towards the Sun.Integral said:
It's a maximum along the radial line, but a saddle in general. And the "near" part is important. The actual L1 with orbital motion is on the sunward slope near the saddle of the purely gravitational potential, to provide centripetal acceleration towards the Sun. Only the combined potential (gravitational + centrifugal) has the saddle at L1.sophiecentaur said:
That is totally correct but does it really add anything to my statement about how the situation is perceived, first time through, by the uninitiated? I find it interesting how the process of learning Science takes place and the concepts in that post come in well after the initial appreciation of a trip to the Moon.A.T. said: