Best Geometry for a Reverse Tilting Trike #6

As the lead engineer of the original Arcimoto cyber trike project, good show friend.

Castor and Camber work in tandem. As you have observed, a lot of caster will make your bike stable at speed but when riding slow, it tends to 'fall' into the curve. This is because as you turn the wheels, the frame of the bike moves lower. Therefore the weight of the bike acts as a force that wants to increase steer angle. Camber has the opposite effect, when you steer away from straight, camber will lift your bike (with 0° caster) . Therefore the weight will always push it back to its lowest position, which is going straight. By choosing caster, you can control high speed stability, by matching camber you can restore / adjust low speed stability.
Toe at 0° is usally for best efficiency, which i guess is most important in bikes. If your ball joints do have a little play toe out / toe in will put preload on them and they wont flop around all the time. This preload techinque is also used because ball joints have a reduced livetime if the direction of force does change often. This may be irrelevant on a bike that does a lot less miles and is way lighter.
As a rule of thumb, 20° caster is already unuasally high and compensation by camber will not work perfectly anymore. typ. is 5-15° in the applications i know
Another factor you havent touched on is the length of the control arms. Usually, the lower arm is longer than the upper arm. This gives the effect off added camber when the suspension is compressed. One reason for this is to eliminate tire scrub when going over bumps, the other reason i believe is added stability when carrying heavy cargo. This may also be a reason why lengthening your lower control arm for added camber gave you such benefits. However it can also be done by moving the frame mounting of the upper control arm further outside.
And when changing suspension geometry, always check that the sterring rods and their joints are still correctly spaced in the plane of the other joints, otherwise you will introduce bump steer. Bump steer is when compressing the suspension changes toe.
Very cool project of yours and i completely understand that a test must be reduced to some variables, thank you for the work you put into this experiment!

This is the most important video on tadpole tilting cargo trikes on youtube. Thank you very much

Tadpole cargo trikes make the most sense:
- two tyre contacts in the front
- redundant front brakes
- can use a tilt-lock
- retains the simplicity of a single rear wheel
Love it!
P.S. : there are similar trikes called "HNF Nicolai CD1" and "Mäx & Mäleon"
You could look up what values they used as a reference.

I knew a genius fabricator who created a 4 wheel mountain bike with a roll cage body and I followed him at 50 mph on the first run at Plattekill where we were downhill racers. anyway. his toe-in was about 1 degree and camber was about 7 degrees. His vehicle had a solid rear axle so he could use the inside rear wheel to friction brake in sweeping turns. It was awesome to behold

Bravo! I am not building a cargo bike but loved every minute of your analysis and commentary. Please continue, looking forward to the next revision.

I'm not sure if anyone else did but I found this useful to understand what toe, camber and castor means and now I plan on using this information to make better tunes in Forza horizon 5. Had the general idea on camber but visualizing it helps a whole lot more. Thanks.

You are a skilled scientist and inventor. This video is much appreciated for your detail are care for these very relevant topics.

This has to be one of the best cargo bike builds on YT. Well done Pedro. I have thought about building a3 wheeler so many times, but I have been riding a 2 wheel 8freight for years and for me the benefits of 2 wheels on the infrastructure in the uk outweigh the benefits of 3 wheels. But I would still love to build one like yours.

Hi Pedro, well done. Nice piece of work.
As regards Toe, I would suggest 0deg. In cars they sometimes set a toe that allows for the flexure of the rubber bushes so that the end result ubder load is 0deg. 0deg is minimum scrub so maximum tyre life and minimum drag.
As regards castor, you are altering trail (the distance between the steering axis intersection with the road to the tyre intersection) as well. Increasing trail will make the steering a bit heavier, decreasing trail will make it twitchier. It also means that in transferring your results to a larger wheel (if you did that) may alter the optimum.
For the ball joints binding I suggest putting a bend in the arms so that the ball joint is at 90deg to the steering axis to even out the play in the 2 directions so lean-ability is maximum.
Finally, neg camber will wear the tyres on one side. So from time to time swap the tyres left to right and vice-versa to get best life out of them.
Doing away with your castor plates will let you shorten it a bit without affeting your load bed.
Finally, if you had a lean lock, that would be handy when you have to stop for junctions, traffic lights (both feet on the pedals) and parking. It may also help balance on really steep hills. You could delete the side stand too.
Lovely job, I look forward to the next part.

Hello! Engineer here :) Nice to see that this idea keep moving these days. I have done a lot of leaning trikes with motor. Let me share some insights?
First one - consider a Roll center. Surprisingly, but CG for Leaning trikes must be at groung level instead of over it like a car design. Thats why you struggling with balance while ride without hands. The second - Ackerman angle: Try to decrease amount of it because : A. slip angle of tyre, B. tyre works on a sidewall while leaning and you get camberthrust.
And last one. Due to long base your front (air) spring too stiff so it would be harsh with strait (especially at high speed)..
(and.. front wheel pressure. IDK but there might be 30-50% lower than ordinary bike)

I'm building a tilting trike but with enclosed cabin for weather protection and better aero, this vide is super useful, thanks

Toe is not typically used on leaning vehicles.
Because they lean, the just don't need it: tilted wheels solve that issue already.
0 toe is fine.

Your creations are getting better and better. This trike is just brilliant. Greetings from Italy

The corect turn geometry is the one that when turning, the projections of the two wheel angles alyways cross in the extension of the back axel.
Toe mostly used on cars to enhance break and acceleration performance, and fix changes of geometry on wide wheels.
Usually, for the geometry and handling toe-out is what you want. It may help tweak the lost of handling from caster.
Maybe 6/5 degrees is too much for toe.

I'm not engineer but having a good feel with technical stuff my opinion is that if camber no toe,it is one or the other,both is too chaotic for a smooth ride and you actually already proove that camber is usefull to add. Congrat for your patience!!and thanks,this was great and really usefull for the community.Ps you gave me some more reasons to make mine!!Thanks again Pedro.

Nice project thanks for sharing. Any Camber will "work the spokes" as the wheel rotates, i.e. the load in the spokes will go positive and negative with each rotation of the wheel. Athletic Wheel chairs with camber have problems with spokes loosening.

very helpful technical tests. thank you for sharing your knowledge.

A mechanic once explained to me that toe-in gives very little real benefit to steering or stability, but that exactly 0 toe is very hard to maintain and even slight toe-out has a very negative effect on steering. Therefore slight toe-in gives a slight safety advantage.
Really enjoyed this video and your process!

When we visited Amsterdam, I amazed by the cargo bikes that I saw there and been meaning to fabricate one similar to what I saw there. Yours is a bit more complex for me ahaha but by seeing this build, it gives me motivation to go ahead with my project...

Hi Pedro,
You are an inspiration to all! Hats off to you for your build!
I would love to see if 5 degree caster is any better with negative camber you have set. I know your bolt locations do not allow this, but since you are going to alter the build, maybe you can try this on the old build before committing to the new design. I would bet that you would enjoy the additional manoeuvrability without sacrificing much stability.
As you described you can add electric motors. I don't know if your ultimate purpose is more geared towards heavier cargo or not, but it seems like you would be ok with a pedal assist system given your location is mostly flat. You could try front wheel drive, (would be a quite a bit more complex as you need to control the speed based on many parameters, steering angle, tilt etc.) or even all wheel drive (but it seems like you wouldn't need this). If you are making the new one from scratch, you can also try to use a more optimized design for the rider frame. Most of the frame geometry is overengineered for the loads you have it seems, you can potentially cut back on weight there a little bit.
If you design the entire linkage including ball joint with camber and caster settings you have in mind you will enjoy a better ride and longevity.
I would advise against toe due to fact that your vehicle is tilting and thus no need for "correcting" steering dynamics due to weight and contact patch distribution is needed. With toe you will get added wear on tyres (negligible if you don't use very soft tyres) and most importantly additional effort is required to energy dissipated as heat with geometry causing shearing on contact patch. In terms of handling feel theory suggests that toe out will make it more "twitchy", in non-tilting vehicles a little toe-in goes a long way for responsiveness but has some costs for high-speed stability. In your case the effect at such small angles is negligible as you have tilting. If you drive front wheels with motors, then you might want to consider toe-in for added traction, but again using ESC to control torque would be the better option.
I appreciate the knowledge you have shared and hope to make use of this for myself in the future.

Love this research and content - thanks for taking the time and extra effort in making an adjustable config so you can test different options.
I've wondered about a cofiguration where as you are initially turning, the bike is more resistant to the action, as a way to improve stability riding in a straight line.. then as you lean into the turn, you're essentially confirming to the bike that are are actually trying to turn, and the turn gets easier as you commit. Added bonus to this is that it also would prefer to return back to straight riding at the end of the turn

The level of talent and knowledge you have...i m humbled

Just stumbled across this video, what a great project. I live in CPH and have tried many different 3 wheel cargo bikes, currently with the Butchers and Bicycles trike for family duties. I have to say the tilting trike is a the best solution that I have tried, on the Butchers the main drawbacks are related to the room the wishbones are taking up from the passenger/Cargo box, and the fact that the ‘cargo’ weight is also positioned directly over the wheel axle, if I put an adult in the box hard braking and that weight shift makes the bike pretty unstable, your solution is definitely getting around that. Also, from experience it can be pretty disconcerting to run out of ‘lean’ when committed to a corner.

XLnt testing! i have a few recumbent e-bikes and trikes and lately bought an e-Heisenberg secondhand. it stays, always pleasant to feel the different geometries when you ride one.

NO WORDS TO THANK YOU.The greatest video of explaining ....I like be a special friend of you from Sri Lanka.....

Another piece of the geometry you can change to achieve Ackerman is the tie rod connection point on the steering knuckles. Move the tie rod connection points inboard. This will turn the inboard wheel more relative to the outboard wheel. You mentioned moving the steering arm forward. I interpreted your statement as moving the whole assembly forward. You could just rotate the arm around so the connection point is forward of the pivot point. But this would require crossing the arm from the handle bars. I’m familiar with setting this up in four wheel vehicles. Requires some shifting in thinking to do it on a bike. For what my opinion is worth, I also don’t like the idea of camber on bicycle wheels. They don’t deal with side loads very well. I’d try to keep the wheel aligned with the resultant load. But you probably know that already.

Wow, what an extraordinary project. I ride an ICE recumbent e-trike. Me and the trike are a little lighter than your setup, and there are a lot more spokes on the front wheels. But even then I'll break one every so often. So I would agree with you, more spokes! I run drum brakes up front, so no hydraulic maintenance, and I really like the progressive feel. Perfect for tadpoles. Anyway, good luck with what you are doing, you are obviously a brilliant young man.

This was a fun exploration of the math behind steering geometry. You might further refine results with rake & trail adjustment to bias tandem tires load vs single steer on the front axle, maybe even with torque bias observations for left vs right steering effort with your current weight distributions. Thanks for sharing.

Hello Pedro. For Ackerman steering. Draw a triangle from the middle of the rear axle to the steering pivot point on each front wheel assembly. Your steering rack links to the front assemblies on this tapering triangle. Then you won't need that strange double bracket at the steering input.
I hope I have explained well enough. Please let me know. Also very well thought out testing procedures.

Riding ‘no hands’ is how I confirm proper geometry.
I am not happy with a bike until I can control it coasting by weight shifting alone.
I never built a tilting trike but it is in my project list, and your work is going to make it easier. Thanks a lot.

Congrats on hitting such a milestone! Designing things is always such an interative process that takes patience and dedication. Your hard work and perspective are inspiring!

Very excellent design video, I really enjoyed it and I learned a few good to know things before I start making an inverted trike motorcycle! It will be interesting to see how much I need to scale everything up.

Well done, Pedro.
This is fantastic progress.
I look forward to your next instalment.

Thanks mate you have inspired me .
Not that I haven’t got enough going on. 😊

Very nice...much potential...looks pleasing to operate, ride....lookin forward to electrics or combustion....

Beautiful ! Suddenly I know more about the geometriproblems. Thank you and good luck with the electric conversion, 10 kilos of extra muscles will make this a vehicle for the future city traveller. Perhaps a tentlike cabin for kids as the next project. I had theese thoughts myself 40 years ago, right idea wrong timing in my case.

I have never had a trike, no intention to have or build one ever. Enjoyed the video anyway!

The Ackermann steering problem you have is caused by the (reversed) T-shape articulated connection. To obtain a symmetric turning radius, you need to use an I-shape, where both wheels extension arms are connected above each other (at the I-bottom articulated connection).
Also as you noticed; the 20° caster inclination on the central turntable making the steering stiffer is practically better applicable for high speed. Once you have the electrical version going high speeds, try to invent a caster central turntable that automatically adjust the inclination on the angle from 10° to 30°, as speed goes higher. If you manage to develop such a functioning system, you can patent it straight away!

Great thought. 1 down side though. When you load the cargo it will be harder for you to turn the vehicle. Because of the weight of it.

You do want a small amount of tow in. It's hard to reproduce on demand but if you have zero tow, you can get a little shimmy in your wheels if there is even a little play in any of the mechanism. A small amount of tow in will prevent that, I don't think you need any more than 1 degree, 1/2 degree may be enough. You don't want to go too far because it will cause excessive tire wear.

wow, great experiment.
I like the scientific approach

Very cool, Pedro. Love it. I think tilting trikes are the way of the future, (until we can just fly everywhere). Your idea of adjustable linkages is inspiring. My mind goes to variable linkages, using linear actuators, or cable levers, so that all could be adjusted on the fly. Cargo, no cargo. Hi speed, low speed etc.

Nice video and presentation.
Positive trail length will induce a negative camber angle in proportional to the steered angle for balancing stability. Having a constant camber angle is a different issue.

¡¡Hola, Pedro!! Following your progress has been fantastic! Thank you for taking so much time/effort to distill and present it here for all interested to learn from and enjoy. Your video production improves and improves, and that takes much effort and talent!
You are certainly inspiring me and sparking/filling my noggin with new ideas. Love it!!
It seems that a close to neutral toe is optimal for your design. More toe-in, or toe-out, would cause increased tire friction/scrubbing and wear, and add to your pedaling efforts. No es bueno. Since our human body is relatively meager in terms of power output, we are pretty sensitive to additional load increases or decreases. I do like how you gave several of the configuration ~2 days of trial. Riding different bikes/configurations may preemptively feel "wrong", but our body/brain adapts quickly and then we, as you were, are able to make better comparisons.
Also, if you had simply made a trike, with no suspension, bleccchhhhh! Vehicles like that become "dynamically dead" and it becomes far removed from the fun experience of a bicycle. Your front suspension definitely IMPROVES upon that!!! Now you have a beautifully unique tri-wheeled bicycle.
As for tools, have you improved and/or gathered new ones? Got a small (they can definitely fit your needs) TIG machine? It would be nice to see some 4130 chromoly tubing in the front, lighter AND stronger for a future iteration. Then you could refit that on a future, lighter rear end. A rear end that will maybe have a 7-speed gear cluster that would always be there and NEVER need an electrical outlet.
Oh, and straight handlebars are okay for aesthetics, but suck-suck for ergonomics. Hold your hands out forward, loosely, in front of you, grabbing an imaginary handlebar, and your hands grip at a natural ~12-15deg bend. In the future, consider that. Your elbows and shoulders will thank you! LOL
And, THANKS as well for speaking to us in completely intelligible English! You communicate excellently! Because of that your video is completely accessible to me. Lucky me.
You made me smile when you spoke of how you felt after all you have done to achieve your ride/design to this point. What you have done, in terms of creativity, is NO DIFFERENT than a fine artist who applies oils to a canvas. To think otherwise is simple arrogance or ignorance. Maybe big dashes of both! I REALLY like your creativity because its product is functional. It interacts with your entirety as you interact with it. AND, of course, in its essence, it is a bicycle. A beautiful bicycle.
Lastly, tip 'o the hat, and two thumbs up, to your camera dude/chic!!! Your video was greatly improved by their assistance. Please, pass my "THANK YOU!" to them as well.
I am only more excited for that day in the future when you share with us again...
PS Straighten out the nose of your saddle. I'm picky that way. LOL

You have chosen far to great differences.
Even 1 degree is a great difference!
You could have a look what cars use.

Amazing work! Thanks to the second camera person

great job= you must be the world authority on this

Ackerman's principle is measured with the steering wheel straight head, not at lock.
That's how the geometry of different steering wheel radiius are followed.
If you draw a triangle between both front steering axis (at hub level?) and the centre of the rear axle line, that's the line your steering knuckles should be.
It kinda looks like your front wheels are a little parralel. At full lock, they should look like they point in a visiblely different direction.

that's a lot of intertwined variables - thanks for sharing! nice suspension but gads ... that's gotta multiply the variables too - keen to watch you iterate!

Very nice Pedro. You might want to consider the 1 degree toe-in when you add brakes to the equation. Braking force will force the wheels back and create a somewhat unstable situation due to toe-out. I've tested this on my first prototype (way to heavy in the end) and found braking and steering at the same time to be more stable. This wasn't a tilting trike though, but a rigid one with 8 inch front wheels and drum brakes all around
Looking forward to the improvements!
Pjotr (Tesla Tilburg)

Marvelous to watch! Thanks, I’ve been interested in this approach for years. Will be exciting with a 750W motor (or two)

Wow! Great experiment. I think a "blind" rider would make your outcomes more sciencetifically significant. Still a great endeavor. Thanks

What an ingenius testing rig !
Congrats for that idea !
Cheers Kai

Toe in adds stability, toe out adds quick turning maneuvering. Most rally cars have front toe out and rear toe in

For velomobiles quite some experiments were done, years ago, around 1990. Camber can be made very large without increasing the rolling resistance of the trike (velomobile). With adjusted geometry you can go up to about 20% before noticing increased resistance.

Track-oriented cars usually run about -2 to -3 degrees of camber to improve stability. Also 1 or 2 degrees of to in. Drift cars run serious negative camber on the front wheels to improve front grip during slides as you load up the outside wheel

You knocked it out of the park with the adjustable geometry ! Just slap a hub motor on the back 😉 . Also bigger wheels might be more forgiving.

A beautiful job of solving a problem which does not exist on a bicycle. At considerable cost in both money and weight.

I loved this video sooo much 😅 I could add some of my advice on geometry of the front end but it looks like others comments have covered this, loved your real world testing, am building my own one of these 3 wheeled tilt bikes but with a motorbike engine, swing arm, back wheel and shock at the back, but where mine with differ is that I am building a aluminium tub for sit down position like in an open wheel racecar like F1.😅 Really glad to see this and would like to see your improvements. After you put a motor on it you could actually also have a low seating position right on top of your cargo area lol, cause the lower to the ground you are increases the sensation of speed and lowers the centre of gravity, and you could make it reversible so you could change between riding/driving positions when ever you like 😅😅 really good work

Awesome information! You're very creative. Kind of hard to do in my two-wheel e-bike but it was very informative and entertaining to watch. Thank you!

Amazing project, you getting in the wright direction, and yes this will be a dream with a electric assisted power, though you ever thought about a chainless but a dohc drive to make it a ideal bike

This is so fascinating! Thanks for all the testing!
Now if I could only learn to weld properly (all my experiments trying to weld up my own cargo bike have been disasters so far! )😊

Very hood analysis. I appreciate your detail and effort. Thank you

The only thing my ocd head noticed was the main shaft hidden was connected to the right only, rather than a dual connection to give a more sturdy control. ( Like the difference between the way a two wheel trailer that connects to the left side only, which gives the rider a herky jerky feel when riding or the Burley Coho XC one wheel trailer that connects on both sides of the hub and the difference is amazing! ). ✌️🌍✌️

That's awesome! I'd like to build one myself too! Though my engineering skills aren't at your level. What electric motors are you thinking of adding to the bike? Hub? Mid Drive?

Travail très instructif.
Merci.

I love the video. -- The detailed approach to all the variables and riding conditions is very impressive. On toe-in, it seems like if 5deg was too much and 1deg was hard to notice, then trying 2 and working up to some limit >=5deg would be worth testing.
Finally, viewing in the U.S. 2024-05-11, I got a pretty offensive ad demonizing immigrants.

Outstanding efforts! I tried commenting earlier but didn't see it show up, so I sent an email to the account linked in the channel info asking if you might consider using something like Cannondale Lefty hubs for your next front wheelset and knuckle design. It could save you the fabrication time and plot a course to a design which could eventually be implemented by more people.

Ackerman is also called "toe out on turns". It's so, as you say, the wheels turn at a different rate on turns, as of course, the inner wheel has less of a circumference than the outer while turning.

Thanks for sharing. Very interesting project you have there. Hope to see the improvements you come up with in the future.

Lovely engineering step by step

Cool project, great presentation, good job on the english too.
Love the flash logo on the front.

What would really tighten that turning radius up would be to have rear wheel steering! I kid 😉Thanks for the fantastic presentation of your process and build!

Very nice build. I was thinking about something similar. It will be even better when you get the electric motor in. Plus with the trike set up you can have a larger battery pack :)
Have you thought of having the power come from the rear wheel? You could have a larger motor and less cost. best of luck to you.

If the front wheels are to be unpowered probably -0.5 degree to -1 degree would fine to adapt to small flex and movement. If powered similar amount of not a bit more positive would be good to make up for flex of components. Great bike also great process, testing is always best.

Camber will make the load uneven, most likely part to straight out break is the spokes as the load isn't shared as well between the sides. If there are stability issues, it's usually better to fix them than trying to compensate for them.

Thank you! Thank you! Thank you!! You are so valuable!!!

45 kilos is very good for a DIY steel cargo trike. I expected something like 60 kilos. Well done!
You changed the geometry a lot. 6 degrees of camber is a gigantic change to 0 Degrees. Many rayle cars don't have that much, even though they sometimes apply a lot of it. Your build is very good, so enjoy it for a while. But maybe in the future you could redo the test with smaller increments.

Kudos maker I have always marveled after interesting tech

Toe is generally used to optimize lateral forces produced by the front tires at a specific range of steering and slip angles. I’d assume given the necessity of efficient use of energy; you’d try to match a marginal amount of toe out to reduce tire scrub from camber thrust while going in a straight line. Optimizing your Ackerman is probably a more ideal solution to lateral forces while turning vs toe given the constraints.

I think the toe angle will have an impact on high speed cornering and stabilty when slip angles start to come into play, but you're not going to gain anything at the speeds you're doing. It also causes scrubbing of the tyres, which you noticed as resistance at extreme angles, but is still there creating drag at low angles.
Likewise camber will create some scrubbing and increase drag as you are effectively riding on cones which want to roll in circles. If you get noticeable gain in stability though it's probably worth it.
For the steering, rather than a T bar shape central pivot to move the steering rod joints outwards, you could use 2 central pivots linked by another bar to make a parallelogram mechanism?

Great project, looks like it will be very efficient.

Toe in and out is all about tyre wear. "toe' on cars simply compensates for driving or non driving wheels, so that it drives parallel to the road while driving (zero toe in). Front Wheel drives want to bring the wheels together (so needs toe out to start with). Read Wheel drive, the front wheel gets pushed out and so needs toe in to start with.

Great work, Pedro. Thanks for sharing your findings!

ตรงจุดประโยชน์ที่ได้ใช่สวยงาม😮..ดีไซน์จะตอบการใช้งาน❤

traditional bikes have a metric called 'rake' that describes the offset of the front wheel from the steering axis, it stabilizes the bike. Tire contact patch behind steering axis and wheel axel in front of steering axis (rake) for stable handling.

Where did you get the hubs for this fantastic project?

Sorry, I have to say I already know that toe-in is not a function of preset geometry, but a counter to flexing geometry. Ideally toe-in would automatically counter whatever geometric flex was caused by whatever weight caused it. So toe-in is only a work around to flex.
The best way to anticipate a certain toe-in is to put on the entire weight of rider & cargo, introducing the geometric flex, & zero up the toe-in-out while under load. After removing the load, whatever toe-in results is correct only for what that load was.

you are a real scientist !

To get the Akermann steering correct, you need to have the tie rods level with their pivots, as you had to move the steering mechanism back to accomodate the castor plates, it's always going to be a compromise. The other issue you're finding is that the steering mechanism is a T bar, so it turns the T which alters the spacing of the tie rods, again, this will be better with the T being central to the steering tie arms. It would also be best if it slides rather than turns, but this is quite difficult to do while having the steering link to it.

Wow idea brilians... Hebat sekali bro sepedanya bisa membantu pekerjaan. Bukan hanya dipake pergi bekerja.. 👏👏👌🤝🤝🙏🙏🙏

Hi Pedro, thank you for your job, well done, i learn a lot . have a god day.

2points camber to 1 point caster active motion 2-1 ratio or 3 to 1 for lower speed steering stability vs control vs °s of motion. Use ball joints on your tie rods. The use of an A arm usually a lower one would ensure accurate camber caster motion decreased drag ect

The Ackerman principle is at any point of turning, the axis of all three wheel will meet at one point… set it in a way at full turn , the axis of both front wheels will both meet, along the axis of the rear wheel… check with the kenimatics of motion…

Whatever your used to will feel best. After returning to cycling after riding a heavy motorcycle, I literally couldn't keep the bars straight. It takes time for your brain to adjust to the new feeling and sensitivity.

Hey, just found your channel and I love what you do. I can't offer any advice on your mechanical design, but for your experiment design I recommend looking into orthogonal (Taguchi) arrays - it's a way to test multiple variables and how tbey interact much more efficiently. As others have suggested caster and camber tend to work together, and this would be the way to find the right setting in a greatly reduced number of experiments.
Hope this is useful!

Do you think you could make the front wheel distance a bit smaller for better city maneuverability?

you might want to try camber and caster together at higher angles.
say 20-30° of caster with 2-4-6-8° of camber.
you dont need to remake the arms for that: just lower the suspension, so the arms droop lower. just doing that will increase camber with your current geometry.
30° is close to the typical steering caster angle (also called rake) of a bike, which is between 24° (super agressive, seen on time trial bikes) and 34° (super slack, seen on downhill frames as it helps absorb landing hits and maintains stability with the bike at full droop, when the fork is fully compressed)
the caster angle needed is relative to the wheelbase. the longer the vehicle, the more caster is needed to help reduce the turn radius.
as far as my research go, toe helps adjusting the ackermann, combined with caster and camber. you can see it dynamically change as you steer on the final form of the bike. that's the direct effect of having close to 40mm of scrub, something i will explain later.
you might want to make a new camber plate with 5 degree increments, something you can easily do by drilling a new set of holes closer to centerline.
and when making the new steering hub, since you're making your own, could fit *around* the knuckle.
the closer the knuckle mounting axis is to the center of the wheel, the easier it will be to adjust, and you will have less scrub (the wheel will travel less relative to the pivot center) and dynamic toe out when tilted to the max (as the wheel is closer to the knuckle).
in automotive terms, this is called positive offset. your car has positive offset, it is called ET in wheel terms. should be between +35 and +55, usually.
that can be done with a virtual center wishbone (but that is extremely complex since you have tilt steer on top of double wishbones) : instead of 4, 3 point wishbones, you have 8 links, who work in pairs. the space between the end of the links at the knuckle, relative to the space at the frame, deports the steering center to and from the wheel centerline.
and you can weld together these pairs at the wanted knuckle offset to spread evenly the suspension load.
this means you can forgo the camber plate, as you can effectively change caster as you change the virtual pivot's location... yeah it's going to be a little bit complex to read, i know.
you can see one being made on this channel: www.youtube.com/@councilhousecreations8035
the lad at council house creations had to do that because he's making a 4 wheel drive gokart... no room for a conventional knuckle close to the wheel center.
you can see this principle of a virtual steering pivot on a few 2 wheeled cargo bikes, like some of veloma's, the catan titanium frame from a few years ago or the EScargo, where the caster and the angle relative between the frame and the knuckle create the wheel's trail and caster.
to not mix with bikes like the ketter cargoline, which run a pivot inside the wheel with a fixed swingarm, something seen on some motorcycles too, like the bimota tesi, vyrus 985 or yamaha gts1000.

😊прекрасная разработка.