05+ final update ( facelift and newer )
only seem to be US bins, how like QKHJ is US 2007 update for the pre facelift 04
he can try these, it is a US bin so he'd have to use an EU ESKONF and hopefully thats it just to test the BTS in the logs.
GPHJ lines up with it well, most of the addresses are close, i made a small pack for it.

enjoy

I tested a GPHJ auto bin on a tf80 and it ran great, just no cc in 6th.  this was before i had proper wrhj wra72 logging parm
thank you tho!

On video you posted there is actually no rolling anti-lag (just NLS)
But here is anti-lag and nls shown: https://www.youtube.com/watch?v=-tWZVR7kp8I

It's done more od less the way you described.

There will be a problem with automatic transmission. Because on full throttle gearbox will switch to lower possible gear. So I prefer to save speed not rpm.

Then you can use speed, yes.

Well maybe master's degree at combustion engines theory is not enough (yeah i'v done such studies, very interesting and useless knowledge there is so little demand for combustion engines theorists that they closed this specialisation at my university few years later - just one guy found job in this specialization, he is designing diesel truck engines for one of big companies

But regarding engines and combustion i belive you are confusing concepts, no offense
There is no conversion of burned fuel into kinetic energy. Kinetic energy is related to velocity not thermal transformation.
Burning fuel is only needed to raise temperature of air in the combustion chamber.
When air in the combustion chamber get hotter according to 2nd rule of thermodynamic then pressure rises.
This pressure then push the piston.
Combustion is actually irrelevant for making power. There are external combustion piston engines like Stirling engine. All that matters is to heat up the medium (air) to rise the pressure.
There are even piston engines that do not need to heat up medium at all - they just use external source of pressure (pneumatic engines) that push pistons.

In internal combustion piston engine we burn fuel to heat up medium and rise pressure.
The earlier we ignite mixture the more time heat will have to penetrate pistons, cylinders and head. More of this heat will be absorbed by the engine.
If we retard ignition heat will have less time to be absorbed by the engine and more of it will be thrown out of the exhaust - that's wy EGT goes up when we retard ignition.

Compression and then decompression of burning mixture is irrelevant.
Of course when we compress air it warms up and then cools down on decompression but sum of energy is zero.
It's not heat that does work (push piston) but pressure.
Heat is just there to produce pressure.

Peak combustion temperature reach 2200C and average is around 1500C (gasoline).
This is how hot burning gasoline gets.

It doesn't matter if you ignite mixture earlier or later. It burns at around 2200C.

The longer heat stays inside cylinder the more is absorbed by the engine (pistons, cylinders, valves) so they are more heat stressed.
Its that simple

The more heat absorbed by the pistons and cylinders the less is left to be thrown out thru exhaust.

That's why you advance ignition and "magically" EGT goes down.
And when you retard ignition EGT "dangerously" goes up.

Bute there is the same amount of heat produced as long as the same amount of mixture is burned.
So what EGT sees is not relevant to heat inside engine.

Well given the same conditions like the same ignition, AFR, rpm and amount of air EGT is relevant to heat inside engine but when you change one condition like ignition angle you change EGT but actual amount of heat is the same.

For example, imagine we stop engine on the combustion cycle with mixture compressed inside and we ignite it.
It will burn and go out. What will happen with heat? All of it will stay inside cylinder. After a while engine block will absorb all of it - simply speaking we just heat up our engine a little.
Now imagine we have multiple burns one after another. and engine rotating. It will still heat up engine but this time some of it will also be ejected thru exhaust.
And now depending on how long mixture will stay burning inside (ignition angle) the more will go into heating engine block (pistons, cylinders) and less will be thrown out of the engine thru exhaust.

Another thing. If you cruise slowly on low rpm mixture still burns at 2200C (gasoline doesn't know your car goes much slower and have to burn with half of its normal temperature:) But your EGT will be like half of what is on full power. Why? Because flame stays a lot longer inside engine and more of it's heat is absorbed by the engine then is thrown away comparing to full power scenario. Of course thermal stress is also way lower because we burn much less amount of mixture.

I can't put it more simply I hope my english is not that bad either

Yeah sorry for my english, heat transfer soundes better
But EGT probe in the exhaust measure temperature... in the exhaust Not in the cylinder
As i said you can have more heat inside cylinder and less outside and other way around

I was taught other way around
Retarding ignition cools cylinder.

Combustion heat balance looks more or less like this:
1. 30% - is lost with exhaust
2. 30% - is lost into cylinder (heats up engine parts)
3. 30% - is what actually heats up air producing pressure

Heat 1. is exhaust stress.
Heat 2. is engine internals stress (pistons, cylinders, valves)

The more you retard ignition the more heat goes into 1. and less into 2.
So you simply cools cylinder But at the same time you heat up exhaust parts
For example - launching ALS - you see massive EGT rise but you also cool down cylinders - but you do not see this because you do not have temp. sensor inside cylinder.

Fun fact - we had test engine in the lab with temperature and pressure sensors installed and they were very accurate and even more expensive
No one cared about EGT temperature in the lab What was important was temperature inside cylinder (and pressure).

But because we do not have NASA like equipment available for our cars so we put primitive cheap EGT probes inside exhaust that do not tell us much about what is going inside engine but that is all we have
It's like watching distant galaxies with telescope - we can't go there personally and measure anything directly so we just observe it from far away and make assumptions what is going on there

And again "kinetic" energy is related to speed when body with certain mass is moving.
There is no kinetic energy extraction from combustion
Burning mixture has no kinetic energy and does not do any work. It just heats up medium (itself).
As i said there are engines that have external heat source like Stirling engine.
Stirling engine has no intake or exhaust, medium is closed inside.
You heat it up externally by heating cylinder walls!
And it works like ICE engine - all that matters is pressure - how you get pressure is irrelevant.
And as for thermal waste i wrote about it above.

Preignition or detonation is another topic.
Mixture ignited normally (with spark plug) burns quite slow at constant rate - so that why you advance ignition with engine speed.
But when too much heat or pressure it can self detonate and it causes more heat and more pressure and more self ignition occurs.
Then pressure inside cylinder goes crazy (jumps violently all the way around) and combustion is disrupted.
For example if you put too "hot" plugs they do not transfer enough heat off the plug itself to the head so they get too hot and start working like glow plugs in diesels pre-igniting mixture.

btw. this discussion made me refresh some knowledge from studies that i started to forgot:)