Curvature of the Mind

Thoughts from a Recreational Physicist

Gravitational slingshots

In my last few posts, I’ve been trying to characterize different potentials through the shapes of their orbits (gravitational, harmonic, lorentz). In the middle of it, I came across a post on bad astronomy about gravitational slingshots. I figured it would be a perfect opportunity to use these images to show the effect in a different way.

To start, I’m sending a beam of particles directly towards the planet in question, just like my previous demos. This time I slowly increase the speed of the planet and the orbit shapes change accordingly. It was pretty hard to see what was going on with the first few renderings, so I started by increasing the intensity and color of the orbit with the speed of the particle. Things were starting to look better, but they didn’t really start to illuminate the dynamics until I subtracted off the initial velocity of the test particles and only showed particles that were moving faster than their initial speed.

This one shows the default case of a stationary target. The particles accelerate as they get close and then slow down to their initial speed as they move a way.

moving target

This is the first shot of a moving target. You can see there are now a few particles that are being shot back at a higher speed, extending past the first line of acceleration from the last image.

There are a few more features visible now as the speed picks up. Since these are lorentz potentials, you can see a more pronounced central core of paths that pass right by the target and are only slightly deflected. The same thing happens with particles further out, but there is a sweet spot that generates two beams. The faster the target moves, the less deflection is seen. With a slow target, the final trajectory is almost a 180, but the angle decreases more and more as the target speed increases, though the final boost in speed increases as well.

I wanted to finish up with one image that captured the gravitational result. There are many similarities, but some significant differences. The infinity at dead center means that there isn’t a max deflection angle like there is in the lorentz case. As you you approach dead center, there will always be a set of bound states. This leads to simpler images, and really those trajectories aren’t all that interesting as far as the slingshot goes. Hyperbolic orbits are the only ones that get launched somewhere.

Anyway I hope these images illustrate some of the features of this process. I’ve learned a lot putting them together, both about these processes, and how to illustrate them in a way that makes the physics visible to the naked eye.

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A less idealized central force

This is the 3rd in a series that started with the gravitational potential, and then the harmonic. While those are the two biggies, what we are looking at next behaves more like something you would see in real life, and doesn’t have solutions that can be written down with simple formulas.

For this entry in our series, I reached into my hat and pulled out the lorentz distribution from basic physics. It it finite in all ranges from the very small, all the way out to infinity, and dare I say beyond.

These images range from a stream of slow particles which converge directly to the center of the force field, through a range of velocities, until the force is just a blip to be zoomed over, producing just a slight deflection.

Some features to note. The intermediate images have more features and details than either the harmonic or gravitational wells. That is directly related to the cut offs in the force. Only the harmonic and gravitational potentials have elliptical orbits, all other potentials have more complicated and complex shapes.

Eventually, however the streams get fast enough that there are no major deflections and no bound orbits. That just shows up as a narrow beam of deflected particles.

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Central force images #2

This is the second in a series profiling the solutions to common central force fields from physics. Check out the the first one on the Newtonian gravitational force field.

These are even more plain than the gravitational well. That’s because these are for the harmonic potential. One of the things that distinguishes this potential is that all orbits are bound and elliptical in shape.

Contrasting that with the gravitational potential, there are 3 orbit shapes for that force: elliptical, parabolic, and hyperbolic. You can see the effects in the image. There is a relatively dark area bounded by the parabolic orbit, with a diffuse bright spot near the tip of the parabola. This is due to the tightly curved hyperbolic orbits nearby. The bright spot fades out into a dim patch further out as the trajectories become straighter the further they are from the center of the field.

Both of these fields have infinities which means that they valid only as approximations to actual forces. The harmonic field has the most severe, it extends out to infinity and no particle can escape from it’s pull. It doesn’t matter how fast our test particles are moving, they will never escape the grasp of the central pull.

Newtonian gravity has the opposite problem. The force becomes infinitely strong as you approach the central point. This causes problems for the differential equation solver and leads to the lower two images with kinked up trajectories and the rays radiating from the central point.

In our next installment I’ll be showing a field without those infinities and see how it stacks up.

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These aren’t all that pretty

Any guesses as to what these are?

Rather than focus on chaotic dynamics I wanted to see how I could explore the differences between the classical central forces. This one is newtonian gravity.

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Got the math right with this one

Here is a fish eye view of the inside of the Earth from the north pole

It’s starting to come together. Just really slow with everything at work and home, plus we’ve all been sick this week.

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Big day tomorrow.

Tomorrow morning I’m doing a tough mudder. It’s going to be fun and hard, and I’m planning to have a great time.

I just thought I’d put up an image in somewhat nervous anticipation of the race. Good luck to all the mudders!

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The other side of the world

I’ve been messing around with my new htc evo 3d. I’m currently calling my current project Hollow World. It shows a map of the Earth projected onto the inside of a sphere. Pointing the phone at a particular location shows a direct view of that part of the Earth. This is the view straight down from Austin TX.

It’s kinda neat to be able to point at a spot on the floor and see what part of the world is under there. It’s also giving me a new perspective on the continents and the way everything fits together that regular maps and globes never have.

My plans include adding internal structures of the Earth like the core and mantle, along with representations of earthquake epicenters. More to share later.

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Spiral

Work in progress…

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