Assetto Corsa Competizione: The 5 Point Tyre Model Blog

Paul Jeffrey

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In another very interesting post from Kunos Simulazioni, physics developer @Aristotelis talks about the upcoming new 5 point tyre model for the simulation.


Developed by the makers of the popular Assetto Corsa racing simulation, and benefitting from the official licence to represent the 2018 and 2019 seasons of the Blancpain GT Series, Assetto Corsa Competizione continues to be expanded and improved upon following V1 release earlier in the year - the next development set to be a new 5-point tyre model...

Five point tyre model I hear you say... pray tell, what might this be? Frankly I've no idea, so I'll leave it to Aris to explain...

In modern computing, collision detection is still one of the most resource consuming operations a physics engine has to do. It needs to be very fast, very accurate and low resource demanding, but you can only choose two of them at once… Add to the equation that in AC and ACC the cars drive on an invisible physics 3D mesh with millions of polygons, derived from the laser scan of the real circuit, and it’s clear that a compromise has to be made. On top of that, AC and ACC uses the same player physics for the AI, requiring even more resources.

The collision detection of a simulation has to be very fast and very accurate, otherwise strange things might happen to the simulation. So in order to make it less resource demanding the tyre model of AC and ACC uses one single point to determine contact of the tyre with the terrain, being this last one a flat asphalt, bumps on the asphalt, various types of curbs, grass and so on.
This solution is a quite good compromise in order to have decent performance and high simulation accuracy. It permitted us to push hard and evolve the tyre model, adding more and more features on it. As a matter of fact the ACC tyre model is one of the most evolved ones, completely dynamic with a wide range of causes that affect and influence the grip and response of the tyre. Various heating levels, different tyre wear features, various influences in tyre rigidity and damping, completely dynamic slip ratio and angles, dynamic rolling resistance in different situations, full water draining simulation etc. etc. the list is very long, very complex, innovative and often involving completely original and breakthrough solutions, derived from meticulous studying and hard work of Stefano Casillo that you won’t find in any scientific paper, as he had to build new equations by himself.

Unfortunately, while still acceptable in AC, the more advanced physics engine of ACC put in evidence the limitations of the above solution. Our tyre model started to have issues and downright buggy behaviour under certain conditions over curbs. The use of laser scan circuits, gives no doubts on specific features of the circuits. If a curb is high, has a specific angle, has dangerous angled steps in it or any other strange feature, then the laser scan will show it in millimetric accuracy. On the other hand, our company motto is that we take no shortcuts in things we are certain. If a curb is made in a specific way, that’s how that curb is going to be implemented in the sim. If that means that our tyre model is going to suffer on it, then so be it, we will have to work hard to make it better and for sure we ain’t going to make the curb smoother just to “workaround” the issue. So let’s analyse what exactly happened with our tyre model in such conditions.

First of all, let’s see how the tyre model would deal with a high but smooth curb, like the many of the curbs at the circuit of Spa Francorchamps. As you can see in the screenshot a curb like this, although it has a smooth surface, it has a quite steep angle, often exceeding 30°.

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The single contact point is approaching the curb but still stays in the completely horizontal surface of the asphalt. Even if graphically the tyre starts to be “on the curb”, the actual point still remains down on the asphalt. This also tricks the mind of the driver, because in real life, if the edge of the tyre touches the curb surface, the driver will hear and feel the tyre touching the edge and take appropriate action or at least he will know he is gradually going over the curb. In ACC this won’t happen. As an example, many people see in real life the left inner curb of Eau Rouge being dirty from tyres and think real drivers abuse the curb. They try to do so in ACC and get an instant spin. In reality, you just need to touch the curb a bit and you can feel it and make it dirty. In ACC the driver will probably think he still has space and on the next lap he will go even close. This creates also a false impression to the driver of where the limits of the car are and the driver might caught himself trying to place his wheels in places he shouldn’t do. At some point the single point will go over the curb. Instantly it will understand a 30° surface inclination. This is an extremely big change on the contact point and a huge spike in load, vector, rolling resistance and so on, resulting also in big spikes in forces and grip. Consider the following situation:

You are on the limit of grip in a turn. The outside wheels are right on the edge. You climb with your front internal tyre on a high curb. This means that you raise the front inner end of the car and obviously you load the rear tyre with even more load. The tyre, already at the limit of its adhesion, cannot afford any more load so it starts to slide. In AC/ACC the front inner tyre will also take a big spike in load and rolling resistance, so it actually brakes for a moment and throws to the suspension more forces than it should. Those forces end up to the rear suspension and tyre in big spikes and the tyre loses even more grip. Usually in very stiff racecars, the inner rear tyre might even go airborne losing all grip and forcing the differential (if locked) to move even more torque to the outside rear tyre.

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If during the whole process, you also remain on the accelerator, you will have a situation where the rear outside tyre pushes forward with less lateral grip while the front inner tyre pushes backwards. Practically you car is transformed to a tank with treads that move in different speeds.

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This is why in AC/ACC if you modulate your accelerator the issue is practically non existent but also why if you stay on the accelerator the behaviour is exaggerated.

Another example are stepped curbs. As you can see in the following screenshot of a Paul Ricard curb, the steps of the curb are not equal from side to side, but gradually become more and more deeper (or in other curbs they might go upwards).

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The tyres of a GT3 car are quite wide, around 30cm wide. This means that often the tyre can be over the curb with the outside part going over the more shallow part of the step, and the inside part going over the completely flat part of the curb, leaving only the center of the tyre hanging through the most deep part of the stepped curb. The result in real life is that while you will feel vibrations from the curb, they will not be as important as the most profound part of the curb. Again, unfortunately in AC/ACC the single contact point at the center of the tyre, will get the worse possible condition of the stepped curb, something that in reality would never occur. So again in AC/ACC the behaviour is much more harsh and critical than in real life.

Finally, some kerbs have an almost vertical step at their outside edge.

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Often the driver will ride and go over the edge of said kerb and then slowly return to the main road going almost parallel with the curb. ACC in particular is extremely critical in such situations. Adding full 3D flex of the contact point (only vertical in AC), created a critical condition in the above scenario. The single contact point would go to the vertical parallel side step and being as high and vertical, instead of climbing over it, it would start to flex outwards, practically getting trapped in a rail. The driver would see that the car wouldn’t follow his commands to reenter and at some point he would move some more the steering wheel, creating more lateral force than actually needed. The front tyre contact point would climb over the step and then obviously would have excessive slipangle that would steer the front end very fast. At the same time, the rear tyre would be in the same condition and still trapped, so it won’t be able to follow the rotation of the car and will continue straight ahead in the rail, practically inducing the car into a very fast spin.

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This is one of the most well known and widely reported “curb of death” situations in ACC and in great need of a solution.

Paradoxically, sometimes trying to make the tyre model even more accurate, detailed and realistic to drive, you get into extreme situations that are so critical and have so bad side results that can practically destroy all the good intentions and effort to offer an even better simulation.
Fernando has been hard at work on our tyre model. With the help of Stefano so that he can understand the underlying code and make sure we get no big impact in performance. Some extra code performance optimisation from Fabio was more than welcome too. So from version 1.0.7, ACC now features a 5 point contact model! We implement 2 contact points at the edge of the front of the tyre footprint, 1 in the middle of the footprint and 2 more contact points at the edge of the rear of the footprint. Each single point moves and flexes independently reacting on forces and surface contact, but also, predictably forces to move the other points together, averaging the resulting forces and vectors, giving a much better representation of what an actual tyre would do.
Examining the above 3 examples again, we can observe massive improvements of how the new tyre model is reacting.

On the first smooth high curb situation, the advantages are multiple. First of all, when the edge of the tyre touches the curb it activates the sound and properly moves the FFB steering wheel, thus communicating at the driver the correct width and position of the tyre. Furthermore the contact points at the edge of the tyre, get the spike of the steep angle of the curb, but their forces are averaged to the rest of the contact points that are still on a flat surface. The tyre actually “climbs” over the curb, instead of instantly finding itself on top of it. There are no more load and angle spikes except the realistic load changes.

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So obviously if you are too aggressive the rear tyre will lose grip and can still provoke a spin, but the result is no more exaggerated so there are no more excuses for bad driving ;)

On the second example, the contact points now include the whole width of the tyre and if that’s the case successfully keeping the middle of the tyre in the air while also being spread longitudinally in the footprint length. There is always a contact point touching the surface at the front or the rear of the footprint even if the tyre is rolling on the steps. On top of that, the extra points are controlling for load spikes and avoid situations of excessive rolling resistance or vectors that point backwards to the car motion.

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This greatly improves acceleration over stepped curbs, as in example at the exit of turns, which in the past, drivers would avoid in order to not harm their acceleration.

Finally, on the most important third example, as clearly explained before, the multiple points now permit the tyre to “climb” over obstacles. So when the edge of the tyre hits the vertical step of the edge of the curb, those contact points start to flex and go parallel “entering the rail”, but the rest of the contact points, still push through the direction and push also the edge points to climb the edge. The driver doesn’t have to do anything with the steering wheel, and the tyre simply goes over the edge of the curb without any dramatic situations.

As an extra bonus, we have also added a new dynamic feature to the tyre flex behaviour. As you know the footprint of our tyre model now flexes in three dimensions. Going even further in tyre simulation, the lateral flex provokes the tyre to lower its profile. This means that the more the tyre flexes laterally the more the ride height lowers. Obviously the change in ride height is minimal, but in a car with proper simulated aerodynamics we know that even one millimetre is important to the handling and balance and so this new tyre model feature plays an important role to the car’s handling. You might notice a bit less understeer on power exit with some rear and mid engined cars, since the lateral flex of the tyre will bring the nose very slightly lower. Gives a bit more control to the front end of the car.

The new tyre model feels even more accurate to drive, permitting placing the car with more precision and absorbing bumps and undulations better with more predictability. All of this is now possible without any hits in terms of performance, which is practically a miracle and win win situation for all of us. As I’m writing this article, we are working very hard on balancing the various values and testing performances and handling, so that laptimes will remain more or less equal and general balance of the cars and your setups won’t change, except maybe for better precision, stability and predictability of the tyres both on and off the curbs.

One more thing…
In our never-ending research for more realism, we knew that we had to improve our Traction Control systems. With the strict rules of the Blancpain series and the BoP in place, there’s not much performance to be found in terms of aerodynamics, chassis, engine and suspension. But the electronics, although regulated, are still a big open field and automakers spend a big amount of their budget to improve such systems.
In street cars, the Traction control engages on the aperture of the accelerator (drive by wire), on the engine ignition timing, on the engine ignition cut and on the brakes. With a combination of all of those controls, the engage of the TC can be smooth and highly efficient.
In GT3 race cars, the control of the throttle and the brakes activation is prohibited by the rules. The TC can “only” modify the ignition timing which lowers up to a point the engine power delivery and if this is not enough, then it will start to totally cut the ignition at a high frequency, resulting in the characteristic engine rattling and vibration.
Been able to lower the ignition timing before cutting totally the ignition, is very important because it permits a more gradual power delivery and a more accurate control at the initiation of a sliding, giving the driver the possibility to modulate throttle application or work around the slide with steering inputs.
To better control the TC engagement, the ECU not only tries to estimate the sliding and slipping of the tyres, but now also uses gyroscopes that measure the yaw rotation of the car, sensors on the steering wheel, and many other parameters so that it can accurately calculate the acceleration of the yaw rotation of the car and understand and predict if it is controllable by driver or if it has to intervene to slower such rotation and give the driver the time to react.
All of the above is now simulated in ACC, delivering a more advanced TC intervention that not only can make you faster and safer but also, incredibly enough, make the car handling more enjoyable even over the limit! Honestly I never thought I would say this for a electronic system…

All of the above, was not a small feat by any means. It took hard problem solving, analysis, non stop testing and balancing. We are very proud of the results as we think they push the simulation realism even further and we are confident that all of you will enjoy ACC even more and appreciate the efforts to not deliver you just another racing game, but really push the boundaries of simulation. As with such complex systems, we hope everything will work flawlessly but if you find any issues, please report everything to our support forums and we will do our best to resolve them.

Original post HERE.

Assetto Corsa Competizione is available now on PC.

For more from the world of ACC, why not head over to our Assetto Corsa Competizione sub forum and get yourself into the thick of the action? We have a great and knowledgeable community, plus some pretty epic League and Club Racing events, if I do say so myself. Go on, treat yourself!



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Great to read about how the Kunos team were willing to look at the kerb problem in detail. It always felt odd to me to be able to spin a car like the Huracan just by getting the front inside wheel on the kerb, it's never happened to me on a real track. Reading how the forces were being transferred to the rear suspension helps understand what was happening. I've adjusted my driving line specifically to avoid these deadly kerbs.

for me, this is where Kunos rely too much on the technically 'correct' data and not enough on driver feel and feedback. And yes other devs rely far too much on subjective feel so it's probably a difficult balance to strike. Like F1 designers who say the simulation tells them everything about a new part is great but then fit the parts to the car and find the drivers can't get the same performance gains from the change.

It'll be great to see how big a change this is.

I hope that one day Kunos will also have the time to put this much dedication and attention to detail into the 'game' elements such as career mode and working in game leaderboards/laptimes.
,
First the tech side has to be as perfect as possible, if this works flawless, than you can give more preference to these kind of things. And to all complaining "not ready" "beta", I have to ask them, which program or game has been perfect from day one? Only look at your Windows 98, 7, 8, 8.1, 10, where this game is running on. They didn't got it perfect till the next version has come out.
 
Maybe it is still rubbish, but it had a better contact patch model than "5 points contact patch" almost 10 years ago.
Back OT, nice to see Kunos Simulazioni still fooling people who do not understand anything about sim physics. NkPro, FVA, AC and now ACC, and they are still late to the party... they should hire more physics coders and vehicle dynamic engineers instead of PR guys. Advertising something absolutely not sensational everywhere, also on non specialistic blogs where people do not understand anything about sim, will not make this "mediocre at best" simulator better.
The problem is another, and I have been a subscriber for 5 years since 2010, the iRacing tire model no one noticed the more than 5 points of contact ... and it was thus described like this: |----| ...... :rolleyes:
 
Make setups, not war.
I generally agree with the rest of your post, but it also remembers me why i'm more of an AC-hater. I spend hundreds of hours trying setups in AC and came to the conclusion that your tyre-model sucks, especially on the track that's just very close from my place: Nordschleife. No hard feeling about that and i'm glad i found better sims, but i think Kunos should fix the problems in AC, since it's still the most popular sim-racing title on PC. Some might say it's iRacing, but i don't believe that. Just this minute they are displaying, that 4.7k are online, but when i look at the servers, i see just a tiny fraction of that and the majority of series are just dead.
 
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  • Deleted member 503495

if simplicity is your only goal then ya.. you can consider it a step back.

But in a sim simplicity isn't the only goal, or we'd be here playing Pole Position with better graphics. The goal is to strike the golden ratio between simplicity and the amount of complexity that is:

1) maintenable
2) does what you need it to do

I give you another example. Let's say you want to simulate a combustion engine in a car. You can do what most sims do:

A) simply work with LUT for different throttle positions and work some kind of throttle response delay.

or

B) You can go all the way, simulate every single atom of matter interacting with the engine, working its way through the intake or the fuel pump, simulate every single spark going off, valves going up and down, program an entire virtual CPU to simulate the actual ECU controlling all the engine parameters in real time.

Now.. the funny thing is that if you implement B perfectly (which you'll never be able to do because you'll never be able to acquire that data from a real car necessary to make it work) it'll basically match up the results from solution A.

So at the end.. which one is the "better" sim? A or B?

No argument on the benefits of simplicity when it does the job. With all that was said, when did you decide to go from the first iteration to that single point that just didn't work well enough under those important circumstances? Did you consider bringing it back to the game and if so, why didn't any version of the original or current solution didn't make it?
 
These demands never cease to amaze me. Kunos clearly communicated 1.0.7 is in its final steps towards release a few days ago and people are impatient as if the developers went undercover for half a year.

I didn't mean to be inpatient. Maybe I just overread that part. Don't judge people to quickly @Timberwind ;) . I am very patient with devs, being a rF2 racer aswell since years you know what patience feels like and how to endure it. :)

Also @kunos give me some of that wine or at least let me join you on your yachts! I'll do the fishing and barbecue ;)
 
I generally agree with the rest of your post, but it also remembers me why i'm more of an AC-hater. I spend hundreds of hours trying setups in AC and came to the conclusion that your tyre-model sucks, especially on the track that's just very close from my place: Nordschleife. No hard feeling about that and i'm glad i found better sims, but i think Kunos should fix the problems in AC, since it's still the most popular sim-racing title on PC. Some might say it's iRacing, but i don't believe that. Just this minute they are displaying, that 4.7k are online, but when i look at the servers, i see just a tiny fraction of that and the majority of series are just dead.

I remember last year that you have stated, that you quite often loose the car when crossing the curbs - and you have blamed it on the tyre model of AC. My experience with AC was and is different. It depends on the specific setup - i.e. front stabilizer, damping (both slow, fast), front toe out.

Using the "default" setups in ACC, the Eau Rouge is pretty difficult to drive. Very often the car catches the curb or the back gets lost at the 1. right corner. As described by KUNOS. In that background I have tried one of my AC setups and -e voila - the world looks much more better.

Cheers
 
Isn´t the specific course of the discussion, specially the touch of inquisition, weird as well? The strategy "who asks leads" might be suitable for an interrogation. Not only in this biotope it is simply dispensable.


Cheers
 
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