How did they even capture it? There's no mention of it.AR3-GP wrote: ↑12 Apr 2022, 18:45I have no idea how well the data has been captured. https://www.formula1.com/en/latest/arti ... dlwQE.html
It would have to be from GPS data otherwise these results are impossible to get.mzso wrote: ↑17 Apr 2022, 14:33How did they even capture it? There's no mention of it.AR3-GP wrote: ↑12 Apr 2022, 18:45I have no idea how well the data has been captured. https://www.formula1.com/en/latest/arti ... dlwQE.html
This is far more to do with the frequency at which they are driving over big bumps and ramps than anything else. If they hit the bumps at maximum travel its going to be impossible to damp correctly.vorticism wrote: ↑20 Apr 2022, 05:19Some of these trucks porpoise, others do not.
https://www.youtube.com/watch?v=PK0lTgmz0rY
Sometimes the porpoising is not strictly vertical, more of a pitching movement; eventually the front and rear suspension can create a feedback loop causing steep approach angles right into a road incline, lead to flips:
You've actually described F1 porpoising fairly well there. The principals are largely the same. Variable downforce acting upon suspension and tires, with some suspensions able to cope with the variable vertical loads, and other not. Just like the modern F1 cars. Notice the majority of the content of the first vid is vehicle bodies hovering over intense suspension articulation i.e. floating over instances which would otherwise cause more severe vertical load variations.SiLo wrote: ↑20 Apr 2022, 13:17This is far more to do with the frequency at which they are driving over big bumps and ramps than anything else. If they hit the bumps at maximum travel its going to be impossible to damp correctly.vorticism wrote: ↑20 Apr 2022, 05:19Some of these trucks porpoise, others do not.
https://www.youtube.com/watch?v=PK0lTgmz0rY
Sometimes the porpoising is not strictly vertical, more of a pitching movement; eventually the front and rear suspension can create a feedback loop causing steep approach angles right into a road incline, lead to flips:
It has a flat floor and a diffuser. Any CART and Group C or LMP (etc.) with a third spring from the past thirty years would have been equally relevant. Venturi typically means to imply and hourglass profile beneath the car. The silhouette Tacoma is a ground effect vehicle in so far as any car with ground proximal aero devices is a ground effect vehicle; in the classic F1 sense it doesn't fit the description; no skirts, no venturi tunnels, no known instances of porpoising (on the mountain).
Well that's only part of the problem really, they can still try and solve it aerodynamically as well.vorticism wrote: ↑20 Apr 2022, 15:18You've actually described F1 porpoising fairly well there. The principals are largely the same. Variable downforce acting upon suspension and tires, with some suspensions able to cope with the variable vertical loads, and other not. Just like the modern F1 cars. Notice the majority of the content of the first vid is vehicle bodies hovering over intense suspension articulation i.e. floating over instances which would otherwise cause more severe vertical load variations.
The second vid is the 'bucking bronco', see-saw effect, which may be a component of some current F1 porpoising as well; yet to be confirmed or disproven. Mainly these videos were posted to get people to think about the underlying principals.
It has a flat floor and a diffuser. Any CART and Group C or LMP (etc.) with a third spring from the past thirty years would have been equally relevant. Venturi typically means to imply and hourglass profile beneath the car. The silhouette Tacoma is a ground effect vehicle in so far as any car with ground proximal aero devices is a ground effect vehicle; in the classic F1 sense it doesn't fit the description; no skirts, no venturi tunnels, no known instances of porpoising (on the mountain).
