Couple things: Roll center height alone is not a metric, it's in relation to the CG height. Yes spings and anti-swaybars control roll rate as well but then you get into ride quality. Also, roll centers need to be looked at in pair with the rear, creating a roll axis. This will tell you where weight is transferred. If the front RC is high but the rear is low, you'd get weight transfer on the outside rear, potentially lifting inside front and vice versa. Most auto manufacturers design cars to understeer to get drivers to slow down. This can be done with roll rates (springs, swaybars), instant centers, or camber rates. So take those dimensions with a grain of salt and look more at the apsects of handling these cars have with what your going for and how the weight is balanced. Before you finalize control arm and mount geometry, you will need to figure out where to put the steering rack. You are limited by its mounting height, but more importantly its length, and you may have to compromise on camber gain or RC height to minimize bump steer.

You're one of the few posters that have started with the rack. But then you didn't continue with the why. It's my understanding that the distance between the centers of the inner tie rod ends sets the spacing of the lower control arm attachment points. If these points don't line up then you start introducing increasing amounts of bump steer into the design. But the rest of your discussion was spot on ! As you eluded the design of the suspension starts with the tire and rim combination which sets the track, the uprights which sets the distance between the lower ball joints then the rack length which sets the lower control arm length. Then adjust the length of the upper control arms to get the desired camber curves.

I have watched you working this project for a while now, and several reiterations on the front suspension. Your explanation is actually making sense. Thanks

Xf motorsports did great videos on suspension design a few years back. The guys are super responsive over there too and helped me with my trans adapter plate design. Ps they are also canadian

When I was in service, doing hundreds of maintenance and crash alignments over my 35 years, I kept an RC car with adjustable A-Arms, to demonstrate what you're showing. It had tiny bubble levels glued all over it. Great visual tool.

Really appreciate the detailed breakdown of suspension dynamics. I've run into the same problem while trying to learn this; every resource I found was far too basic. The order of operations when designing a suspension from scratch is a game-changer. Thanks!

This is incredible. You did a great job of explaining! I feel like anyone who is doing the same will save TONS of time and money by watching. Remember, if the women don't find ya handsome, they can at least find ya handy.

14-15 year old me (a third of a century ago, now...) designed a car, and I had that same wonky control arm setup like your C4 Corvette suspension on the bench. My single source for guidance (from the public library) wasn't clear enough to me, and I tilted the top arm so the pivot on the top of the knuckle was lower than the pivot on the frame. Anyone roughing this out -- this was all pre-internet, so I was lucky to have a small town library with just that ONE book at the time. Several years later, re-looking at my drawings in CAD, I mapped out the virtual center, and saw that camber curve: it was dished concave in, not convex out how we normally want for camber GAIN. That was my aha-moment to tilt the top arm the other way. We got stumped both by the camber curve. Thanks for putting me back on track! Your explanation did clear up some of the murky less understood design process past where I stopped in my teens. The visuals that Racing Aspirations provides helped backstop all the concepts better, as you explained. It probably helped that I had some, not all those concepts percolating in my head now for 30+ years after my first and only go at a suspension design, so as you explained it on video, I wasn't falling behind. Very interested to see what the next step holds, how the 3d-analysis is done. Onto the voodoo and dark arts of anti-dive, anti-squat, and more! And, thank you again, for taking us along for the ride. :D

Well that certainly explains why I’ve always felt I was spinning round and round in successively smaller circles when I’ve tried to understand suspension design. Reading the books made my eyes glaze over. Sometimes after giving up I would even head for the donut shop for a superior glazed solution. Unfortunately that never helped either. You’ve inspired me to give it a go. Definitely looking forward to the next episode. In the meantime I’ll be rewatching your previous episodes and reading all the comments to help drive this home. I’ll probably even pull those dusty books back off the shelf for another spin. Thanks so much Craig for slogging through this. 🙏🙏🙏🙏

Don't measure from the tip of a tape measure if you care for good accuracy, "burn an inch" or perhaps 10mm in your case and measure using the divisions and not the fairly approximate tip of the tape :) The effort you're going into for this is pretty impressive and your willingness to jump into areas where you know you need to learn is great! I will admit the suspension stuff is Greek to me although I've certainly heard many of the terms and have some vague understanding. Much appreciation for trying to explain it as you're learning! The feedback you'rew getting is also awesome and I cannto wait to see what you end up building and how you like driving it eventually afterwards. It's like you're building Tally Ho in automative form - I love it!

Talking about camber gain around 9min. Actually looks like you went from a half degree postitive camber to negative 1.5 with bump (i assume your angle gauge 's bumb feature should be same as a level bubble). Regardless of that, its still not enough static camber at ride height or enough gain through the travel. Such a low roll center is counter to where I'm going through with testing on my car. However yours is WAY lighter than mine. If you have the room don't be afraid to add chassis side adjustment for the lower arm that's higher up. Which will directly raise the roll center. Up and down adjustment for the upper arm is a good idea too. I was once told anything that can be made adjustable is a good move. The camber gain target you showed seems too little if you plan spirited driving. Super basic but i set mine by sitting on the fender and using the angle cube to measure body roll (2.4), then set the cube on the tire to check for gain or loss. I went with a degree more negative gain than body roll as a place to start. Best year I've had yet in tire longevity/wear doing street, autocross, and track days. I don't know what that gain is vs compression travel but it is definitely more than .6/inch. However a street only setup probably wint need the additional camber gain. In aggressive driving it does need more because you also have to compensate for tire deflection. Overall, good video! I also spent months researching just to start understanding what's all going on when everything moves.

Thank you Craig for doing what few have the patience for. Basics, camber gain; when you "bumped" the wheel up first 1" and then 3", you lost negative camber gain, you didn't gain camber. Maybe you just misspoke there but it's an important point when we're talking negative vs positive, losing vs gaining, concave vs convex bla bla. The upper control arm is obviously shorter than the lower, as both move through their respective arc ranges, the shorter arm has no choice but to result in offering "negative camber gain". The problem is the upper and lower arms are not parallel, causing some "loss" at different points through the range of travel, but ultimately will give negative camber gain. The geometry has no choice but to produce this result, the upper arm is shorter. In the Racing Aspirations software it is clearly set up differently to what you have on the bench in your garage, in the software version the arms are very nearly parallel, the Corvette is very clearly not parallel. Sorry if this sounds like I'm angry, really I'm not, I'm only wanting to clarify why you lost camber gain, the upper arm begins, lets call it drooped, the lower arm has some degrees of "rise" from the "at rest" starting positions of your experiment to see what the suspension was physically giving you. This is where the dark arts show up, bump steer, weight jacking, roll center, roll axis on and on, this is why this is all so difficult to master. Before you move on to the side view, you have more work to do from the front view. Ford went to an extreme to "correct" for roll center migration, they designed the infamous Twin Torsion bar suspension. This provided for a really smooth soft supple ride, but did nothing for handling or tire wear. It was a cheap solution or alternative to Chevy's double A arm suspension, which is as you are finding out, very complicated to mitigate all the negative compromises required for mass produced suspension. Remember the Corvair, lawsuits were abundant because the geometry/design was flawed from the beginning. As important as reading and studying the available printed material is, like another "commenter" said, an RC, radio controlled toy car can teach you as much as all those books combined. I highly recommend getting a RC car to test your theories/setup/geometry. Don't get me started on roll center, every race car mechanic has their own opinion of what is the optimal height and they have tested their theories on the track, go to a local circle track and talk to those guys, invaluable. Pavement or asphalt racers would be optimal as you want your car to run on the street. Oh, and potholes, don't forget our Alberta roads mostly suck.

4 am time to watch 40 minute video

Great video and a good attempt or start at solving your problems. I am not aware what tires you plan on running. If they have a larger side wall and will have significant contact patch migration under cornering load, then you may need to increase the scrub radius. You want to insure that the forces generated at the contact patch stay on the same side of your SIA as you load it up dynamically. You don’t want to have the forces at the contact patch go past the SIA, as when this happens any feedback your feeling in the steering wheel will also change direction, pulling the steering wheel in the opposite direction mid corner. Next thing, as the SIA increases, you get more / less camber gain as you turn the steering wheel. So if your benchmark cars were getting 0.6° camber gain, but had a lower SIA angle, you might need to design in more or less camber gain in your wishbone length ratios, to accomodate for the camber loss you get when turning the wheel with a high SIA angle. Looking forwards to the next video. Cheers. Ryan.

FDF RaceShop in Ontario makes angle kits for drift cars (aka a lot of experience with non-OEM front suspension geometry modification). I believe they have their own engineering department too. Might be worth trying to reach out to them… they’d probably be atleast a little interested in helping out upon hearing you built a 60’s Volvo body out of carbon fiber Great video. Really appreciate the visual representations! Probably a huge PIA to film and record

Well done, easy enough to follow. Thanks for putting in the weeks so we can put in the hours!

When poking around with suspension camber gain / loss, I've used a peg board and furring strips to simulate different A arm locations and lengths.

I love this project! And especially the approach you take to every part of it

Cool video! I use the C4 front suspension for my race car, and I did a few things to help (not solve) the issue that you observe. My first solution was to get a longer lower control arm ball joint from Howe. Does put the control arm close to wheel hoop though, but 18" wheels clear fine. I also chucked the upper control arm cross bar spacers in the lathe and cut them down to the absolute minimum in the back and enough in the front that I could run more caster than stock for camber gain under steering input. Still doesn't give more than bout 2 degrees maximum static camber and I am going to go to a custom shorter upper control arm to get that sorted. Lowering the upper arm inboard pickup points would help as well, but not sure how much fabrication I'm willing to undertake. Nice video, thanks for making it!

This is the suspension video I've been hunting for years

By far the most detailed instructional/educational on automotive suspension design video . Awesome!

Wow, I love your honesty and the way you explained your process. From my experience, I would say most will run in loops because of the lack of tyre data available, as most things are fundamentally linked to those characteristics. It is interesting to use existing vehicles to determine your foundation numbers; however, it would say you should make sure you have similar spec tyres to those vehicles and have similar weight and centre of gravity. So, the critical pieces of data characteristics you are missing are the following Slip angle Vertical load Horizontal load Alignment torque Rolling resistance Another factor would be the aero characteristics of the vehicle. I look forward to seeing more videos from you. When I was a student, my go-to was Race Vehicle Dynamics. I think everything I've stated is within that book. Essentially, they say that the suspension is designed for the tyres and keeping them in their ideal window

Nice job man… We are all counting on you.

Awesome work! Man, how in the hell do you get all that done in such a small space? Bravo!!!

What a fantastic explanation for how to establish a starting point on geometry! If i remember correctly, your steering inner pivot should now fall on the line drawn between the inner pivot points of the upper and lower control arm.

I’m only halfway through the video and I gotta say this is a tremendous amount of work. You’re right. I don’t want to do this. Thanks for doing this.

That was fun! Can't wait for the next installment!

I really need this. I am very reluctant to continue ‘trying’ to work with 40+ year old suspension parts and constraints, especially when it is well known that bump steer was an issue back then. I actually like the idea of starting from scratch on my mk7 Bolwell.

Great work, well done. Look forward to the next 'teaching' session.

Most of its above my head and I'll likely never put this info into action, but count me in for the ride. I'm always keen to learn and build on existing basic knowledge of all types of vehicle design.

Just discovered this channel and this is truly amazing and fascinating. I'm an engineer who first started before my degree, and had to ask what your background is because I am genuinely impressed at your ability to ally practical manipulations and theory.

I know you already replied that the level was not placed as expected on the hub, but I think it’s important to notice that you were reading the “bubble” level backwards. As you increased bump on the C4 suspension mock up, camber was going more negative. I watched a promo video for the tool to confirm. I don’t mean that this is the right setup for your car, but I don’t want you to be confused and frustrated in the future when using that tool. Also, you are embarking on a long journey if you plan to fabricate all the components. Mike Burrows from the channel Stance Works did something similar and re-did it a few times. He has some good videos to reference on the fab techniques and learnings. Good luck!

Great video and confirms what I had thought of the Corvette suspension design. It is surprising how many so called Sports Cars have understeer built into their suspension designs. When I was mocking up my Lotus chassis, I used PVC pipes to physically build the control arms that were cheep and super easy to modify. I found it helpful to see a physical model after reading books such as: (reading list sample for those interested in more) Race Car Vehicle Dynamics - Milliken & Milliken An Introduction to Race Car Engineering - Rowley Tune to Win - Smith Race Car Aerodynamics: Designing for Speed - Katz Automotive Aerodynamics - Howard Tyre and Vehicle Dynamics - Pacejka

Overall, this video is more in depth than than most suspension videos on KZbin. And for people who want to learn more, books are the best option. The book i referenced most is from Derek Seward when building my engineering college race car suspension. As mentioned in other comments, it is important to look at the front and rear suspension as a whole. This is how you control the under/oversteer. Ultimately, if you are looking for the most performance out of your tires, then you need good tire data. Unfortunately tire companies are usually reluctant to give out this information. And testing the tires yourself is a lot of work. But if you have $500 burning a hole in your wallet, then you can get tire data from Tire test Consortium. But if you are trying to save money, lowering the upper a-arm chassis mount point about an inch should fix the camber problem.

Awesome work and an unbelievable amount of time! Well done!

The explanation of front view design is great, start with the track width you need, add a few locations at the wheel, start from the center of the car then connect the dots. I'll be waiting for the side view and am hoping for a top view vid as well. Concerning top view, most if not all street cars ( use a 77 to 90 full sized GM ) have the lower control arm rotated so the front pivots are closer together. I'm not sure why this is done but I think it interacts with what I'm typing below. The upper is rotated as well but I'd have to look at a suspension to see what way. As for side view, the control arms pivots are tilted relative to each other , I'm pretty sure this has to do with anti dive where braking forces try to add spring rate to the front suspension. Think of it this way. If the brake was locked and you applied a torque in the direction of forward motion , how much torque would it take to move the suspension into droop? High torque = minimal anti dive = nose droops a lot under braking. Low torque = high anti dive = minimal nose droop = possibly too high of an effective spring rate leading to turn in problems.

Excellent info here!! Keep it coming!!

I love your channel. I've wanted to build a car forever and this way I can build it vicariously through you. (I have the "Engineering To Win" book too.) One other thing: Considering the care and detail you go through I don't understand why you only have 46k subscribers. Rebuilding cars is fine, but honestly wouldn't hot rodders rather build their cars from just a donor body on up?

Great episode!

Thanks for the details! I would love a litterature list!

Fantastic stuff...really impressive. I've got a similar project ('66 122 wagon) I'm just starting to sketch out for an engine swap. This suspension piece is one of the things holding me up.

I'm glad I found this video. I do want to do a swap as my car has a solid axle type and parts are becoming rarer. A custom suspension design would allow me to build it with easier to find parts.

Have been following along since you started this project. FYI, those moog ball joints may be a bit stiff. After going through the task of redesigning my 66 mustang suspension, I discovered the ball joints were binding causing all of my driving tests and the conclusions I came to, were invalid. Glad to see you choosing a low friction joint. Nothing like having to start all over, again.

Thanks Throttle Stop Garage ... very, very well thought through and articulated ... about the most helpful suspension geometry video I have seen. As I am building a GT40 your approach is highly applicable. I can you give you a mention on the (GT40) forum if you would like.

Thanks so much for sharing that hard earned information with us, sir. I'm just at the same stage with my build and wasn't confident with the direction I was going in. I'm utilising MX5 front and rear hubs on a scratch built Lotus 11 I,m currently building and was hoping use the same upper and lower control arms but with a different track width. I think I need to go downtrend route you've taken to haveany success...

I’ve been following you for a very…very long time, and I’ve got to say, this one so far is my favorite.

I would quote Einstein I believe, "If you can' texplain it simply then you don't understand it well enough. "I think you did a smashing job of explanation! Well done!

I used some cheap 350z front wheel bearings on a custom front suspension I built a few years ago, they lasted around 300 miles before they developed significant play. I replaced them witn SKF units. I took the easier option of basically copying MX5 front geometry & fabricated the uprights + wishbones to suit.

Great explanation looking forward to the next episode

Excellent work Craig!

Thinking the steering rack pivot width and steering arm pivot location should have been included in the discussion at this stage, for it’s coincidence with inner swing arm pivot points and steering rack location limitations. Great stuff and thanks for sharing.

Excellent work, I'm going to get stuck in on mine once I get my body mounts done (thanks for the idea on casting your own by the way) so I'm sure of the fender clearances. I have slightly less variables than you as I need to keep the lower control arm frame side point on mine but the upper (within reason) and definitely the wheel side are all available. Thanks for compiling the data on things like KPA and Scrub out of all of those cars as a starting spot. Unclear if I start clean sheet on the front or practice by pulling the Q45 dimensions on the rear. Also why the 350Z hub for 5x4.5in [5x112.3mm]? I get not going with Ford hubs with the big centerbores but Nissan/Mazda/Hyundai are all still bigger than the Toyota/Honda size bore you have on your rear hubs. Keep up the great content!!!

Great video, I'm looking forward to seeing your upright design using the 350Z hubs

This is incredibly helpful.

I’m pulling for you; we’re all in this together

I applaud you for tackling this complicated and slippery challenge, and I hope it works out very well for you. However, the C4 Corvette was known as an excellent handling car, so I'd be careful about thinking that you've discovered that its front suspension geometry is garbage. It was particularly good on the race track, where the 'problems' you describe should be at their worst. Having said that, Corvette Engineering did redesign the C4's front suspension slightly for the 1988-96 cars, which got even wider tires than the 1984-87 cars had. Lotus Engineering consulted on the project. They widened the front suspension (the distance between the wheel hub faces) a couple of inches - about an inch on each side - by lengthening the A-arms. That necessitated a series of other adjustments, as you can now well imagine. The wider the tire, the less tolerant it is of camber change during suspension movement, and I suspect that's why this was done. Longer arms generally result in reduced camber change during suspension motion. They also, as I recall, _did_ reduce the scrub radius in that redesign, and I have a vague recollection that this was specifically suggested by the Lotus engineers. Scrub radius is part of the 'black art' of tuning an overall front suspension design package, and tires had come an _awfully_ long way since the last time the Corvette guys had redesigned theirs, way back when they designed the 1963 C2 Corvette. So maybe their first C4 iteration wasn't absolutely perfect, but it was damned good. It definitely _wasn't_ all wrong, or junk, or stupid, or anything like that. Just saying...

I'm glad you're using A arm, wishbones. If you go strut, like that Nissan Z, you open another can of worms. OEM front ends seem to favour parking, and understeer, some even have different wheelbase lengths on each side of the car.

loved it. i am still a little confused but thats not unusual, the ah-ha moment will come after a few read troughs. This is well worth a subscription.

Wow man... incredible!

I have experience.... messing suspension up real bad. Hahaha, I'm so curious to see the interplay between the camber gain and the aft kingpin inclination/offset planes of articulation in the SLA unit.

Looks like a great start of v2.0

HI, you said there was a lot of reading. Would you mind pointing me at a couple of these - names of books, where you got them, links to internet sources, anything you're happy to share. What you are doing is fantastic, keep pushing forward.

Wow, just wow!

Eagerly waiting for new updates.

I’ve found that I had to read many many books to get the whole picture. No one book by its self made these topics make sense to me.

Wow! I don't know if you've done this correctly, but it sure makes sense. Thanks for the heavy lifting. I'm dieing to see the Volvo on the track.

Thanks to share your experience. I build small electric vehicle (1 seat and 2 seal) and my biggest problem is the suspension geometry. I rebuild 4 time the geometry for the 1 seat and now I designing for the 2 seat. I using negative scrub to plan to have a better driving experience at high speed. But you use positive Scrub is it better Positive Scrub? If you want, you can contact me and I will share my plans and feed back on the roads.

Appreciate your effort

Awesome video, I see you have got .6deg per inch of camber and codos for figuring out this base line number. I believe your caster will also increase the camber as you turn the steering wheel, do you have a figure for angle of caster and how much extra this will add to the six degree per inch. Or is that in the next video, cant wait!

We like rabbit holes…. Its nicer when it’s someone else’s because we can just move on where you are stuck at least for now 👏

As always you did not skip any steps. I think that even I could understand it. 👍

Great video. Just my thoughts, but I'd try to design in adjustability. With those balljoints, you can get different lengths to tweak roll center, so that's good. Being able to adjust the inner pivot is good too as it will allow adjusting anti-dive and front/rear bias. Steering rack height adjustment to tweak bumpsteer. Alternative mounting holes or spacer stacks can be used to do it. Like the use of the Hub assemblies. I've been working on a design as and doing an IRS with it. Trying to find ones with the right wheel bolt patterns, good bearing spacing and readily available can be a hassle. Wonder if anybody has dug in deep to find some good ones?

Excellent video.

Hubris? I'm officially in on this, and a new subscriber. I love hubris!

You’re describing camber loss while we watch the angle decrease and the bubble shows you’re getting gain. I’m confused.

Fascinating

Are you sure your evaluation that test of the stock camber curve is correct ? At about 7:30 on. It looks to me like the wheel is going more neg camber with bump. Just eyeballing it compared to the background. Also your digital level has a generated image of a bubble level on it ? Its going to the right also, indicating the level is leaning to center of car. Or maybe im dyslexic .

Great work well explained This should help me Put me down for a triple like

Awsome video. Thanks

Great video Craig. I'm wondering if something like a modernized Mustang II/Pinto would have worked. Seems to be pretty popular with hot rodders. Not sure if the geometry is there or not but it looks decent at a glance. Looking forward to the next vid 👍

Thank you for explaining where some of the points in space come from and what is acceptable from a design point of view. From the way your thinking is progressing I am assuming you are going to machine your own uprights. From my experience (formula car racing) and research the suspension design starts with the upright, especially from the home workshop environment, as it is expensive to manufacture. It is usually more efficient to start with a production upright that has a minimum of compromises. Have you got one in mind? I am currently have the some of the same issues on my current project, a 77 Monza, which have crappy front suspension geometry, crappy uprights that don’t allow big brakes, good hubs, etc.

Great Video and explanation Sir♥♥ can you tell the name of the CAD software you used in this video?

Very worth the wait! I have gone down part of this rabbit hole (the analysis side) and have noticed that factory suspensions are rarely what I expect. I really don't think much of the "millions spent" on car designs have very much to do with actual good performing suspension. I suspect ride comfort and stability/ease of use at low speeds trump actual road holding performance under rougher heavy usage... My question is, are you going to make full custom control arms, the send-cut-send way, or are you going to go looking for arms that exist that meet the specs you define, you know, mix n match from different makes? And have you planned to make the whole thing adjustable, with either shims of adjustable arms etc?

Another excellent video Craig. Are you trying to design a suspension that won't need adjusting, except for toe. Seems to me once you start adding shims or rotating cams all these parameters will change. Minutely, but will it be enough to blow your mind?

Craig, where did you get the drawings for the Howe products? I need to use them on my suspension design and have not found stuff specifically for the Howes, only generalized 'K' number drawings on the pin height not locating shoulders and such.

What made you choose to start with a c4 front suspension? I don't think I would of started with a double a arm type.

Can you list some of the books you've read on suspension design? I also want to read all the books.

In your research of existing cars roll centers to help decide your geometry, did you also see a pattern between roll center height and track widths? If your reference cars actually followed a 'rule'? You did not directly mention anything about that here. The closest is the camber curve which, of I remember correctly, helps to keep the COG over the roll center. I know it is impossible to cover everything in this length of video but curious as to if that was part of your process. Your classic car is narrower and taller than modern high performance cars so how much should your reference them? This probably could be a video in itself.

I would’ve gone with the Corvette suspension and just drove into a ditch. Nice work!

Someone else: If it's good for Corvette its good enough for me. You: Something's not kosher! Back to the drawing board. But first back to school.

Honestly, suspension geometry has always been a mystery to me and not something I've ever felt I could tackle. Your video has finally made some things click in my head.... It's also made me realise I do not want to design my own suspension! 😂 Do you think you would publish the designs when you finish?

Are you still going to use the C4 vette spindle/upright or is that going to be made custom as well? I had planned on using the same setup in a 69 triumph GT6 but now I’m thinking it may not work since I need to narrow it so much. Great job on explaining your thoughts.

One _more_ book to read: _How to Make Your Car Handle_ by Fred Puhn. (I didn't see it in the montage.) Might be unnecessary if you've read and understood all those others, but for viewers who are just getting started it should be a valuable tome.

1:40 ❤ I find myself in too many diy projects because nobody’s invented it yet

It seems like it's going in a better direction, the corvette suspension looked wierd to me as it had the upper control arm sloping outwards rather than inwards as is custom, therefore the corvette instant centre would've been outside the wheel. I wonder what the result of mounting the inside of the corvette upper control arm lower would've been, this would to my mind put the instant centre in a more conventional spot (therefore a better roll centre) and also give better negative camber gain. When you rolled the vehicle in the model it was still losing contact patch, perhaps it could use some more negative camber gain? Where is the steering rack in this? If you don't consider the location of the rack you'll likely get bumpsteer or rollsteer issues (you measured the width so I assume it was in the modeling). Rather than inputing standard figures for camber gain why not calculate what camber you need? Camber gain required is equal to the degrees of roll, you've got the track width and a reasonable idea of suspension travel which should be enough to calculate it with some trigonometry. An older euro vehicle will tend to be less track width so may not be the same as more modern. Also camber curves depend on which suspension it is, macpherson struts go entirely the wrong way and are forced to start with too much negative camber so they have some left in bump.

No need to be looking at values from other cars except for sanity checks. Ask yourself what 'roll center height' actually means. You're essentially designing an 'anti-roll' feature; and that's a percentage, not some best practice value in millimeter or freedom parsecs. You are determining how much leverage you want to give the mass attached to the CG. Roll center on the tarmac means 0% anti-roll and a fun boat ride, RC at CG height means 100% anti-roll and zero roll even in a 5G turn. So you want to figure out the necessary amount of geometrically build-in 'anti-roll' to get x degrees of roll at x Gs of max lateral acceleration. The roll gradient for a boring family car is around 5°/G, a production sports car should be around 3-4°/G and little FSAE race cars are set up somewhere between 0.5 and 1.2°/G. My suggestion would be a target of 1.3G and 3°/G, pretty sporty for a road car. So the starting point for simulations I'd pick would be 4° of max roll, 0.25-0.5° static camber and 4.25-4.5° of camber gain at max roll. It's not a GT3 car after all. For the rest you'll need weight, weight distribution and spring rates. Get your spring rates sorted, calc the respective instant center heights, jacking forces, and see how much the car jacks up and rolls vs. what you want it to do, then apply the necessary 'anti-roll' by raising the static roll center to the right percentage of the CG height. CPI btw has a lot of interplay with caster, it basically increases (neg.) camber on the outside wheel and reduces it on the inside wheel. The right angle again depends on the amount of jacking, roll and positive camber gain at full droop. The good thing is, you can leave this parameter for last since you can simply slide the upper control arm along its virtual construction line once everything else is locked in. Hope this isn't too confusing, English isn't my first language.

Have you watched "Fanatic Builds"? I think he ended up designing his suspension from scratch. Quite involved and interesting in any case. P.S. Love your vids.

which software did you use?

Hi Craig: You can check out my approach anytime. Get a bunch of random suspension parts from China, throw them in by eyeball and hope for the best. Not a lot of calculation since we are measuring to thin air anyhow. The electric car driveline has arrived.

Although automotive companies spend millions on their designs, they have a lot more constraints than you do. You're building one custom vehicle for your own consumption, not trying to sell millions of vehicles to the masses. I realize you don't want to use an existing design, however you have the ability to leverage the knowledge others spent creating existing designs. This allow you to choose the benefits and compromises you're willing to accept based on your own criteria, parts availability, and packaging. I hope you see success on the suspension design and you're able to build something to surpass your expectations.