Warning: Monster post ahead! Contains dangerous Mathematics/Physics!
Abstract: Starting the bridge on 50% of final gravity will prevent it from overshooting the final settling position, thus keeping member stress below the final settled stress. Gravity can then be increased to 75%, 88%, 94% etc.
Further down there is physics engine talk, including an attempt to explain the forces that make some constructions rip themselves apart (explode) on being born.
baggio and mendel discussing damping and gravity via icq (edited, edit approved by Baggio)
mendel: anyway, I don't have a graph plotting prog handy, but what function would describe damping? k * sin (t) bounces (k damping factor), and some others would tend to zero with varying speeds. That behaviour might depend on the specific bridge, so a general solution would be difficult to find.
Potential energy is converted to kinetic energy at the rate of speed; if you dampen speed to (next to) nothing, no potential energy gets converted, and the mechanisms "sticks". Maybe I am mislead because I think of the way brakes work (Coulomb damping)
Baggio: Ok... the general solution for an underdamped system is....
x(t) = x(0) * e(-Z*w.n*t) * ( (Z/(sqrt(1-Z^2)))*sin(w.d*t) + cos(w.d*t) )
w.n is the undamped natural frequency
w.d is the damped natural frequency
Z is the damping ratio
This is only true if v(0) is 0 though. In our case it is.
mendel: ok so it's basically e(-t) for the amplitude of the wave. that never reaches zero.
Baggio: Yes... Ae(s*t)... the sine and cosine provide your overshoot and osilation.
mendel: so if Z=1, we have critical damping, and Z>1 overdamping?
Baggio: Yes, that is correct. With the bridge, it is Z<1, underdamped.
mathematical damping models: http://mail.bris.ac.uk/~aemtak/damp/damping.html[/i]
mendel: Pontifex *ought* to implement material damping.. :-) as the bridge is not under water
Baggio: Water, Air.. it's still a fluid, maybe not as viscous. Coulomb damping is also used to model joint damping mechanisms. Joint damping is found in highly assembled structures. Sounds like what is needed for some parts of P*.
mendel: hmmm.. I think lowering gravity won't even reduce the amplitude. It will lower the frequency. So if the bridge bounces 3 times before settling then reducing gravity to lower the frequency might mean only one bounce.
Baggio: Ok... think of it this way, if I just barely introduce gravity, the deflection of the bridge will be ever so slight. I wait.... Then I increase gravity ever so slightly, the bridge will deflect again, ever so slightly. As G->9.81 m/s^2, the "bounce" will have been reduced to nothing.
mendel: Lowering gravity will lower the amount of potential energy energy the bridge has when it "comes into being", and the structure thus doesn't have to dissipate as much energy in the settling phase. An undamped bridge will still bounce at the same amplitude no matter what the gravity is (ok g=0 excepted).
Baggio: Yup... there isn't anything to stop it from bouncing.... That senario would never happen in real life though.
mendel: yes, but your "ever so slightly" is just not there.
Baggio: how do you mean "is just not there"?
mendel: with v depending on g and damping depending on v , the spatial movements will be the same at any gravity.
Baggio: It is dependant on g, but only the acceleration portion... only x double dot is used, but then the mass is divided through.
Baggio: This is a bit hard to convey in text form.. 
mendel: Insight: "ever so slightly" is correct because beam internal energy does NOT scale with g. If you look at a settled bridge it has internal energy stored in the beams that it is equal to the potential energy in the bridge in start configuration at final gravity. Lowering gravity at the start does not reduce that final figure. It will just serve to eliminate high kinetic energies in the process. correct?
Baggio: Yes... that is what I've been trying to convey on the message board. The final outcome would be the same, but those peak kinetic energies could fail the bridge before it is ever tested by the train. In levels where few cars are used, this means that the bridge may be failing because it can't settle nicely, and might have been able to support the train.
mendel: but I knew that before (and posted on it). So at 0.5 g the bridge would probably not overshoot because the energy is not (yet) in the system - it would need to get at least 0.5 * final internal energy in kinetic energy to overshoot, because at 0.5g the bridge settles to internal energy levels of 0.5 full; when kinetic state passes this, deceleration sets in, so kinetic energy must be 0.5 full at this time to reach 1 full at peak displacement. But peak kinetic cannot be 0.5 full because potential energy is just that much, and kinetic can't be higher than that :-) So we'd ramp up to 050% 75% 88% 94% etc.
Baggio: Well, it will still overshoot, meaning it will still have bounce, but that bounce may not exceed the final resting position of the bridge.
--> this means the internal stress is less than in the final position, too!
I've been thinking about it, and I think you are right about the frequency though. I think the frequency will be less, and perhaps the time constant will be to.
Interesting... it is kinda hard to visualize this because there is no place on earth that I've been able to observe .5g.
here is where the physics engine part starts
mendel: Pontifex physics are not of this earth.
Baggio: Don't I know it... if they'd change the k of the steel though, I'd be happy. That is really causing some odd behaviors.
mendel: Having less bouncy cables alone would make sus bridges easier (and the physics engine more unstable).
Baggio: More unstable by being less bouncy?
mendel: more unstable as in - likely to generate huge forces out of nowhere (see rip-apart tower)
Baggio: Ahh... I see your point.
mendel: physics engines watch that members joined stay joined, and when they drift apart they apply a force ex machina to get them to stay together. this can cause explosion.
Baggio: I think that is also in part to the k not scaling with length. I guess that is a problem with the joints trying to stay at the same verticies.
mendel: That's what I meant.
Baggio: Yup... I'm in agreement. That matches what I've observed... in a way this is kinda neat. We are pioneers, not unlike Newton before us, trying to discover what makes the "world" work the way it does.
talk about open source physics engines and project bcon deleted - contact me for details
Baggio: Before I turn in, did you see this slide? http://www.q12.org/ode/slides/slide13.html Is that the short link bug or what?
mendel: yes. gamasutra had a review of physics engines a while back (1998) and some of these commercial examples showed exploding, too.
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[no changes in this edit except to state that the log is now approved by Baggio]
(Edited by mendel at 3:07 am on Nov. 5, 2001)
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