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JohnDeere

A better way out of line twist!

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I guess it's a different technique. It doesn't really untwist anything, it just moves the linetwists from the lines to the risers where they come out much more easily. You can see that after I stop twisting them, I start spinning out quickly with no effort.

It has worked well for me every time I've used it, but I hesitate to recommend it since I learned it from a video on skydivingmovies.com by a random person with unknown experience. I'm pretty sure that's the only emergency procedure I've learned by watching a video on the internet, and I'm not proud of it. :)
I'd say it's very important that your toggles and excess brake lines are stowed securely for that, since your hands are all over them ready to either snag on something or get stuck between your risers. It's entirely possible that this will be proven a very bad idea at some point.

Dave

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It's entirely possible that this will be proven a very bad idea at some point.


It seems to me that when you push the risers apart, you are increasing the tension in the lines and opposing any increase in the number of line twists.

If your canopy is still winding up then pushing the risers apart seems to be the most sensible course of action. Pushing the risers together when the canopy is still spinning relative to your body makes it easier for the relative spinning to continue and it moves the twists closer to the risers and your hands/body.

OTOH, if the canopy is stationary relative to your body, i.e. it is no longer spinning up, then pushing the risers together seems like it might be a good idea.
The difference between stupidity and genius is that genius has its limits." -- Albert Einstein

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It works - and i haven't even tested it on a jump yet.

My 2-year-old loves to have me spin her up in her swing and then send her swinging so she's zooming along two axes at the same time.

So after reading about this, I tested it on her as I stood there winding up the swing before I swung her - and wowsers, it really works.

For any skeptics out there, try it out at your local park if you don't have a kid and swingset of your own. i know for sure I'd have two less cutawats in my logbook if I'd heard about this a little sooner (one about a month ago!).
SCR-6933 / SCS-3463 / D-5533 / BASE 44 / CCS-37 / 82d Airborne (Ret.)

"The beginning of wisdom is to first call things by their right names."

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No offense but if you leave your parachute for packing with a stepthrough ,don't be surprise if you get it this way. No entanglement,half brakes,slider and PC done is your job.;)

blue skies'

Any packer who intentionally packs a stepthrough, collapsed slider, unstowed brakes, etc. is an asshole that needs a punch in the nose. >:(

If you're a packer and want all that stuff done for you, fine, either educate your customers or charge them extra. But if you recklessly endanger me with a bad pack job to "teach me a lesson", I will get Medieval on your ass. :|

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The way I get it is that = spreading is not only obsolete
.. spreading risers in linetwist is potential spin inductor,
higher wingload - by riser spreading - higher spinning danger



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If your canopy is still winding up then pushing the risers apart seems to be the most sensible course of action. Pushing the risers together when the canopy is still spinning relative to your body makes it easier for the relative spinning to continue and it moves the twists closer to the risers and your hands/body.

Not necessarily. The sudden move of the twists to the bottom, will cause a rapid deceleration of the spin-up, because the sudden addition of the anti-spin force outweigh the force you're describing.

Try it at a playground swing, squeeze together while it's still spinning up. You'll see what I mean. It's still beneficial to squeeze together while it's spinning up.

That said, it's a complex interaction between the tension of the twist, the number of twists, the angle of lines going into the twist both at the top and bottom, the amount of spin momentum you already have in whichever direction, etc. So given some specific variables at specific values, you might be right. But for the vast majority of situations, I think you'd be wrong, based on swing-set observations, there's enough massive margin of beneficial untwist force massively "outweighing" the danger you describe. I'd wager to say the same would apply under a parachute, too.

That said, I disclaim all responsibility for any mistakes in this post -- try it at your absollute peril if you're under spinning linetwists under harddeck. :o

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A view from an inexperienced, outside observer on this issue:

When we were taught to spread the risers during AFF, it immediately struck me as an odd, counter-intuitive idea.

Think about it as if you just have a weight hanging from two strings. You don't pull the strings apart at the bottom, shuffling the twists upwards - that just makes the system tighter. You pull the strings apart above the twists - that gets the weight spinning quickly and easily.

I also suspect that kicking does nothing - you have nothing to kick against, which means your displacement at the end of the action should be 0. You can't contort yourself in such a way as to cause translation or change in momentum unless you're in a heavily curved section of space-time, such as near a black hole for an object human-sized. :)


Moreover, I've had two linetwists severe enough to need work, and neither time did I feel that my actions did anything to speed up the natural progression of the twist - and I typically have a extremely good feel for that sort of thing.


EDIT: also, sorry about the apparent necropost - I've actually had a couple conversations about this issue recently and wanted to throw my $.02 in.

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I also suspect that kicking does nothing - you have nothing to kick against, which means your displacement at the end of the action should be 0. You can't contort yourself in such a way as to cause translation unless you're in a heavily curved section of space-time, such as near a black hole for an object human-sized. :).



Not correct. If you kick appropriately you generate angular momentum in your legs which has to be balanced by opposite angular momentum in your torso.

According to your theory a highboard diver could never generate a twisting dive, and a cat not could turn over and land on its feet if dropped upside down.
...

The only sure way to survive a canopy collision is not to have one.

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If you kick appropriately you generate angular momentum in your legs which has to be balanced by opposite angular momentum in your torso.



Right, which means you don't actually end up spinning at all, you just contort in an amusing manner.

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According to your theory a highboard diver could never generate a twisting dive, and a cat not could turn over and land on its feet if dropped upside down.



A diver (and a cat) can only change the direction and speed of the rotation they have upon leaving the diving board. At all times (assuming they aren't going fast enough to use the wind) they must conserve angular momentum. If dropped with no rotation whatsoever, the most skilled diver in the world would be powerless to rotate until they caught some wind. Likewise, if you dropped a cat perfectly evenly with its back to the ground, it would not land on its feet.

In the diver's case, the appropriate rotation is gained from the diving platform, and the cat relies on the complex, chaotic nature of the universe to insure that it will have some angular momentum to work with when it falls off things. :)





Now, if you had a fast canopy, you might be able to help yourself by sticking alternating arms out, much like doing a barrel roll in freefall.

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A diver (and a cat) can only change the direction and speed of the rotation they have upon leaving the diving board.




Then how does a diver increase his speed, stop the twist, go from a tuck to a pike position? How does a gymnast do all the movement during a floor exercise?
I think you might want to reconsider John’s explanation of angular momentum, he might know something about physics.

Sparky
My idea of a fair fight is clubbing baby seals

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A diver (and a cat) can only change the direction and speed of the rotation they have upon leaving the diving board.




Then how does a diver increase his speed, stop the twist, go from a tuck to a pike position? How does a gymnast do all the movement during a floor exercise?
I think you might want to reconsider John’s explanation of angular momentum, he might know something about physics.

Sparky


That was so much better worded, than how I was going to bitch slap them!:ph34r:

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Then how does a diver increase his speed,



By reducing the average distance of his mass from the axis of rotation, the speed of his rotation increases. This is a cool little demonstration:
http://www.youtube.com/watch?v=yAWLLo5cyfE

Another excellent visual is the ice skater:
http://www.youtube.com/watch?v=AQLtcEAG9v0

EDIT: it's due to the conservation of angular momentum, basically the same as "an object at rest tends to stay at rest, and an object in motion tends to stay in motion, unless acted upon by an outside force."

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stop the twist, go from a tuck to a pike position?



Like I said, the direction can be changed, but not the magnitude. So a diver can translate a twist into a flip and vice verse (to a large extent), and even slow rotation down enough (by spreading out) to appear stopped - usually just before entry into the water. Starting a dive with a good amount of angular momentum gives the diver a lot of freedom to perform a great deal of spinning.

That said, it *is* actually possible to do a torqueless, zero angular momentum twist or flip (i was wrong about the cat being dropped perfectly above), but it requires a significantly more complicated motion than kicking, since you are forced to maintain 0 angular momentum throughout the move. Moreover, once you've done it, you stop. You can't start a spin that continues on its own from a state of rest with nothing to push off.

Maybe there is a maneuver which could untwist a line twist slightly, however i think your time could be better spent getting into a position which allows the canopy to do the work.



Here's a good read: http://docs.google.com/viewer?a=v&q=cache:2kcSiyZlrG0J:www.physics.princeton.edu/~mcdonald/examples/mechanics/frohlich_ajp_47_583_79.pdf+conservation+of+angular+momentum+diving&hl=en&gl=us&pid=bl&srcid=ADGEESizuxBm6G5gZlEWXaXgvzRbmC3IuHichDOoPB6soC71Jmby_4McbIjfojI8IvWjTVWM6ao_egPNg-SCXVkG8APoVYY7cyWTi8umvMAd4ZrJkCJ4JTJsJJ9bWEQCaQmrLZAm-m0R&sig=AHIEtbRkYXpryv9CzaL7l7gUYDiE97xjbg





EDIT: since I can't put an addendum on my first post above: The post states that it's not possible to rotate or translate on flat space-time. This is apparently not *entirely* correct. You can apparently reposition yourself, however you still cannot introduce a sustained spin, nor can you translate.


You can still swim through curved space, though, if you're interested in getting up close and personal with a black hole. :)

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>Likewise, if you dropped a cat perfectly evenly with its back to the ground,
>it would not land on its feet.

Actually it would. It 'spins' its hindquarters to generate torque and uses that torque to rotate itself. Cats pretty much always land on their feet as long as they have time to rotate around (i.e. they need a half a second or so to get their feet under them.) It's the same basic way that reaction wheels work on spacecraft.

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I totally agree with you that kicking alone doesn’t do much help for untwisting. What usually happens is that when you start kicking you grab the risers and exert a counteracting torque on them with your body. This is what undoes the twist. Although the parachute has a relatively low mass it is flying and this flight gives it a lot of “dynamic” inertia (it resists to changes in motion).
Try this experiment: sit in an office chair (spin type with good bearings) and lift your feet off the floor. Now try to rotate yourself kicking your legs, arms, whatever you want, you’ll remain facing the same direction. Now put one finger on the desk and push (apply torque). The desk is the parachute, you need this link to create torque and have something happening. Also, to create torque you need a lever and this is probably why untwisting the risers works well. In the above video you can see that when the twists reach the links the risers are allowed to separate. At this moment you have a lever arm (spread risers) and it is exactly when the parachute spins the jumper.
When you don’t bring the twists down you don’t have a good lever to create torque and untwisting takes longer.
It is also interesting to see that the parachute keeps flying in the same direction, it is the jumper that spins which means that although the jumper has a higher mass the parachute has a much higher overall inertia (at this axis).
Who doesn’t love Physics?:D

Engineering Law #5: The most vital dimension on any plan drawing stands the most chance of being omitted

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billvon: Yes - this was something I didn't realize until reading the paper I posted above (which is a super interesting study on torqueless, 0 angular momentum gymnastic moves). Redacted my statement in my last post. However, I still don't think kicking out of linetwist is really the right type of motion to accomplish anything significant. Like I said way earlier in the thread, I've never felt like I accomplished anything by it.

I am going to have to spend some time on a trampoline experimenting with these fancy maneuvers, though.



Ronaldo: I totally agree. The video trevor posted was very impressive, and makes me want to try that technique. I would *love* to find something which I feel actually works to speed the naturally progression of the line twist.

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That's a very cool clip. Thanks!

I wonder how much torque you can apply to something that way. I mean, you have to expend some energy to do it, so presumably you could apply some torque, even if it's not much.

For the apparent he achieved, I can only assume he was swimming. :)

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By adding energy to an object in motion, you can, in fact, change its angular momentum.



Not without an external force. It is not possible to change the angular momentum of a free body by applying only internal stresses. Read the paper[link] I posted up there on the topic.

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Kicking adds energy.


Technically kicking would remove energy from the system, by converting some stored energy into heat which would then be radiated away. You could use that heat to power a radio or something, but without any mass to eject (or something to kick against) it would just be squandered as you cool down. You might even be able to move a tiny bit by the directed emission of electromagnetic radiation from said radio, but you can rest assured the effect would be minuscule.



My last post was supposed to say "For the apparent translation he achieved". I assume he's swimming through the air he's breathing, since again it's impossible to translate without ejecting mass or suffering an external force.




There is the caveat to those that it is possible in curved space time[link], which technically the spacemonkey in the video is in, however the effectiveness is determined by the *amount* of curvature. You can tell it's not curved very much because you don't feel like gravity is constantly attempting to pull your arms off.


A quote from the paper I just linked: " The curvature of space-time is very slight, so the ability to swim in space-time is unlikely to lead to new propulsion devices. For a meter sized object performing meter sized deformations at the surface of the earth the displacement is of the order 10^-23 meters. "

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