Realistically pretty unlikely. Either an engine dyno and a lot of time, or I’d need to daily that setup and iterate for several months. Sorry!

Modeled the e46 for fun, now I can do a real analysis of camber, toe and track changes at some point

Well. I'll. Be. Damned.

All this time I've been calculating the roll center height of the rear as something astronomical and offensive at ~12" versus a nicer 4-6". After re-running the analysis, I'm calculating a rear roll center height of about 130mm or just over 5" - just about where it should be.

Turns out I'm the fool and I've got egg on my face for making a bad assumption. The roll center height is *just fine*. The front seems to be about 40mm high, so you might argue that a rear roll center closer to 100mm might be better, but you'd be splitting hairs.

Now, the toe control and ride comfort balance still sucks, and the suspension is still heavy and high inertia so there are still gains to be had from the e39 suspension, but the geometry isn't likely to be one of them...

Is there a book you'd recommend to those who are not engineers who want to learn more about vehicle dynamics and how all these factors (roll axis, CG, multi link vs trailing, frequency response etc) that affect how a car feels and handles?

Race Car Vehicle Dynamics by Milliken and Milliken is my favorite: https://www.amazon.com/Vehicle-Dynam.../dp/1560915269

These days there are also lots of great YouTube videos. More recently, the Suspensions Explained Channel has put out a few great videos.

Ultimately the best way for me to understand is to experiment on my own cars by isolating and changing one variable at a time (you see lots of that in this thread, despite the effort of doing jobs twice or even more times). I had an e31 850i manual that I turned into a corner carving monster that used to clean up e46 M3s at autocross after reading the book above and incrementally experimenting until it was great.

What changed in the way you were calculating roll center?

Thank you! Instant buy. There's also a guy building a cybertruck vehicle of sorts (channel Project66). He did a phenomenal video talking about building optimal suspension setups, but I feel what's optimal depends on your weight distribution and where your CG is. Another great guy talks about building suspension but leaves the details out - still a great watch (channel XF Motorsports). He's absolutely unhinged and lets his dreams steer his engineering. Very cool stuff

Pulling what I wrote in from the sister e46f thread:
So instead of just projecting the upper and lower control arms to a point and assuming that’s roughly where the IC is, I’m projecting those arms to a point, and using that point to define a line that extends outward to define the IC (and in turn, roll center). Very hard to describe in words, I can show you with a model open some time.

Worth noting that jacking is still an issue with the suspension design due to that lower control arm angle, and with the added fore/aft angle I’d been ignoring, jacking looks like it’s even worse. So the butt isn’t lying but it’s not from the roll center itself, just the placement of the members.
​

Definitely will be pulling up some of those channels, thanks!

Aah I see. Think I got it, but down to peek at your models sometime.

No worries. The same general concept applies, correct? Datalog and make iterative changes to the appropriate maps. I purchased a HTE tune so should be able to adjust part throttle response from there if i’m on the right track.

Mike

Kinda - you really need an engine dyno to get the cam angles correct with custom cams unfortunately. There’s really no replacement for that. More thorough than what I’ve been doing for sure.

Okay, jacking. Let's do some quick math.

Let's assume that the car weighs 3400lb with 50/50 weight distribution and for the sake of simplicity, it's cornering with 1G and 100% of the load on the outside tires. So 1700lb load on each of the two tires. We'll also assume bushings behave like ball joints, which is close enough for this analysis. Also for this analysis, we're going to assume that the suspension isn't moving, which isn't accurate but again, close enough for a first order approximation.

For axes, x will be left-right, y will be forward-aft and z will be up-down.
The lower control arm is 11.2 degrees from horizon
The upper control arm is 6.4 degrees from horizon
Both control arms are ~25 degrees looking down
Lower outer ball joint is 162mm high
Upper outer ball joint is 404mm high
​
Given that the angle of the rear control arms are in 3 dimensions, and each link can only take force along its axis we need to break this into a couple trigonometry calculations.

First, sum moments about lower link:

(404-162)*upper reaction_x = 162*Load
Upper reaction_x = 162/242*1700lb
Upper reaction_x  = 1,138.0165 lb tension

Sum moments about upper link:

Lower reaction_x =404/242*1700lb
Lower reaction_x  = 2,838.0165 lb compression

Check your math with som of forces in x:

2838 - 1138 = 1700 - check

Now we convert the loads from x to loads in xy. These are all increasing because math.

cos(25) = 2838/Lower_reaction_xy
Lower_reaction_xy = 3131lb
Upper_reaction_xy = 1256lb

Then we add the vertical component of the loads:

Lower reaction_xyz = 3131/cos(11.2)
Lower reaction_xyz = 3192lb
Upper reaction_xyz = 1256/cos(6.4)
Upper reaction_xyz = 1264lb

Now let’s make it easier to understand and normalize the forces for every 100lb of cornering force on the tire:

Lower/100lb = 188lb compression
Upper/100lb = 74lb tension

Now, finally, let’s perform jacking calculations. Both numbers add to jacking because of the angle from horizontal of each arm. Nice.

Jacking_lower/100lb = 188*sin(11.2)
Jacking_lower/100lb = 36.5lb
Jacking_upper/100lb = 74*sin(6.4)
Jacking_upper/100lb = 8.2lb

And sum them together:

Jacking/100lb = 44.7lb

So for every 100lb of cornering load on the outside tire, the e46 suspension is applying 45lb of jacking force to the chassis. That’s kinda nuts.

And now let’s turn this into displacement. Stock springs are 380lb/in (there are two of them)

Displacement/100lb = Jacking/100lb / Spring Rate = .06in

So finally, for every 100lb of cornering load on the tire (this is not much), the outside tire will increase rear ride height by 1/16”

We’ve ignored the opposing force from the inside tire, which counteracts some of the jacking, but its effect is much smaller because the load on that tire is much lower.

If you do some other hand wavy math that I’ll skip, a first order approximation of rear suspension lift due to jacking in the rear is .5-.75” at about 1G, which is about what you can expect from your tires. Yep, you’ll feel that. Twinkle toes rear suspension.

Ok screw it, let’s just cover the hand wavy math:

Maximum G of 21.5” (546mm) CG before 100% load on outside tire. Sum moments about the tire:
0 = 1G * track width/2 - xG * CG height
xG = (1G*1525mm/2)/(546mm)
= 1.4G

Outside tire load is then, let’s assume it’s linear for simplicity:
50% @ 0G, 100% @ 1.4G

Let’s now assume that the tire cornering force relationship is linear with its vertical force, which is close enough for a first order approximation. Let’s now calculate the lift for 1G of cornering load using all the numbers:

1G = 86% load on outside tire, 24% on inside tire (total is 1700)
Outside cornering load = 1462lb
Inside cornering load = 408lb
Outside jacking = .855"
Inside jacking = -0.24"
Total jacking = 0.62"

And contrast this with the front, where at 1G we’ll see almost no jacking given the same load. If you’re lowered, you’re actually likely to be jacking DOWN! The worst of all.

And we have our first scan of the e39 touring rear suspension on the ground: https://s.digital3dcloud.com/space/f...lang=en&loop=1

I managed to get the full LCA, both diff output flange locations, lower shock mount location, sway bar position, and spring pad location. Packaging in the touring was unfortunately too tight for me to get the upper control arms completely in the scan - I think I'll need to scan a subframe removed from a car to really get it.