#aerogollumturbof1 wrote: YOU SHALL NOT......STALLLLL!!!
I would say all the difference. Active Suspension is exactly that. Active. It is digital and adjusted by computers. FRIC is completely passive and mechanical.WaikeCU wrote:How much difference is there between Active Suspension and FRIC? Can you say that FRIC is part of Active Suspension, but FRIC isn't Active Suspension?
Mmm. Not sure about that.Pierce89 wrote:The inerter gains grip because it reduces oscillation of tire load. What this means is your minimum tire load will be higher so its harder to lose grip.
DaveW please help here. Your multimagic is needed for an explanation.
I think that is a given, although a system based on Frank Dernie's patent (see here) would probably work with the current SECU, I think.WilliamsF1 wrote:The new active suspension of 2017 is not going to be anything like the 1993 type.
Seriously, I don't think that idea is feasible, for all kinds of reasons. For example, a GP2 suspension is about as simple as it comes, and that certainly influences aero - and aero influences the suspension set-up.WilliamsF1 wrote:As per CW, it is going to be a system with simple suspension functions, with no active ride controls which influences aero...
I have listened to Dominic Harlow's interview (straight line tests), but can't really comment, except to say that there was no requirement to use the SECU... I guess that would also be true of the Ferrari system (however unlikely that is).WilliamsF1 wrote:I think it will be more along the lines of the ferrari electro magnetic suspension which were used some time in the last 10 years for finding the best mechanical set up.
Great bit of data.DaveW wrote: However, for what its worth, an inerter fitted (hypothetically) to the front axle of a race car (a GP2 in my example), will increase the minimum load at the front axle up to a point, hence increasing "grip". Here is my example.
The plot show the minimum, mean and maximum values of vertical load under the front wheels whilst the vehicle is being subjected to a swept frequency vertical input.
Apologies, I was not trying to hide anything. The horizontal axis is time. Here is an alternative plot of the same data showing the frequency response of CPL per unit road acceleration.bill shoe wrote:The horizontal axis is labeled "X-parameter". Is this frequency, time, or intentionally undisclosed? The numbers seem too high to be frequency in hertz, but I'm really not familiar with modern racecar setups.
Adding the equivalent mass to the front wheels produced this for the first (lowest inerter mass) case. Not the same thing at all....bill shoe wrote:For a shaker-rig vertical frequency sweep, would adding mass to the front corners (with no inerter) achieve a result that was similar to using an inerter?
An active system will driven by measurements, none of which is perfect. That reality has important consequences.SectorOne wrote:What sort of features can we expect that the suspension will do?
SectorOne wrote:What sort of features can we expect that the suspension will do?
Anti-dive during braking?
Lean into corners?
Always maintain a near perfect distance from the ground?
I think that this is the right question. They have many ways which they could go, but since it is supposed to be cheap, here's my guess / thoughts (leaning way out the window here, just trying to lure a statement from Dave hereSectorOne wrote:What sort of features can we expect that the suspension will do?
): SectorOne wrote:So the theorized system you guys think will be on the cars is more or less nothing like what the Williams was running?
(i can confess i don´t know anything about how the Williams system worked)
Cost has nothing to do with it.SectorOne wrote:And that is because of costs entirely or is there another reason?
