It caught my eye as a lot of the stuff he has shared over the last few years I have personally validated at one point or another through experience.
These basic formula that allow you to select the right cam spec within spitting distance of ideal were like an epiphany moment for me when I had 90% of the feel for cam specs worked out in my head just from knowledge and more importantly, ability to ignore junk and white noise on the net that drowns out the actual legit real stuff that is far and few in between.
You may know I recently got to do a custom tune for an off the shelf popular cam, the stage 3 for VN-VR and it was the final puzzle piece that nailed it into my head what a good cam looks like for the Buick in particular, but in general for most engines.
Then after seeing and playing with David's formulas I was like, holly crap! yep, I was 100% on the right track and was able to validate exactly what I was experiencing and also the results of others, actually mainly the shortcomings of others.
There are two formulas.
1st is the important one which is what I have figured out myself over the years and recently confirm for sure, is the LSA for the cam.
2nd is also important but after running the numbers over cams I have and many examples of available cams, it seems I fluked all mine spot on without even being aware of this, and all cams I ran the numbers on all came out perfect too. So this seems to be a standard bit of maths that all companies use, but derive via completely different means I guess. This is the required intake adv duration based on the LSA and overlap you choose.
3rd, which actually should be figured first, but not a formula, but a general guide is the overlap at adv spec, which selects the application of the cam.
I'll start from the last and go in logical order.
The advertised cam overlap range and what you want out of it. The category might be a bit subjective to some people. I would say it's pretty good though and agrees with my personal categories where I call most cams too small for how they are advertised, at least from the bigger companies like comp or crow cams especially. Smaller guys like Clive cams are more in line and call most stuff that is popular mild or small.
10º - 40º - Towing
30º - 60º - Regular street/OEM
50º - 75º - Street performance
70º - 90º - Street/strip
85º - 100º - Race
95º - 115º - Pro race
The next is the formula for the LSA which I found extremely important when getting a given cam profile to work either really well, or be a complete bucket of shit (eg most mild/medium crow cams).
This formula is based on the SBC of 10.5 comp for pump petrol for street use, but seems to agree extremely closely to most engines including the Buick V6 and the ecotec but the latter is lacking data from my end but it seems to agree so far.
There is a factor which I think relates to head flow and maybe comp has a say as well.
Excuse my excessive use of brackets, I suck at maths for the most part I write formulas as if I am writing the whole thing into a calculator in a fool proof way so each bracketed bit is calculated in the right sequence and so a calculator doesn't mix the wrong bits if that makes sense.
LSA = 128 - (((CID/NoCyl)/VDin) * 0.91)
Where "CID/NoCyl" is the cubic inch displacement divided by the number of cylinders to give the individual cylinder cubic inches.
That is then divided by the VDin or the valve diameter in inches as well for the intake only. All these calcs are for the intake only.
Then that is multiplied by a factor of 0.91 to give a figure. That figure is subtracted from the SBC factor of 128 to give the final LSA figure.
SBF uses the factor 127 and BBC uses 132. But the 128 value works for most engines of the pushrod domain. This is where I figured this factor has something to do with how well heads flow and/or some other head related factor.
The last formula is the required advertised duration for the given LSA and chosen overlap.
It goes like this. OL mean overlap btw.
AdvDur = ((LSA + (OL/2)) * 2)
I found this last one just fluked right for all the cams I designed in the past, but I reckon this is well understood in engine sims and other commercial programs used by OEM and cam makers. All cams came out perfect.
When I said this is all for the intake. I actually found that it perfectly spits out the duration for even split duration cams. If you take a typical cam of such, add the two durations together and then divide by 2, you get the average of the two and this exactly matches I found. So you could work backwards and get the figures for a split cam I guess, but I am not that smart in maths to do that without wasting a heap of time and some cursing before I figure it out, then immediately forget how I got to the answer.
So going to what I found over the years is that at least with the Buick is that they love a tight LSA and more overlap than what nearly the entire internet, and cam companies etc... all recommend. I finally put a nail in the coffin to the common wide LSA is best which was the other end of the spectrum to the trend I leaned towards, confirmed these engines hate a wide LSA and love a tight one. And now it makes sense why most people get poor results from modding these engines with similar or even larger cams than I used. This also confirms that Buick, at least before the 3800 II was developed, knew what was ideal for these engines. The 80s saw the GNs and Regal and other V6 models running LSAs of about 107º
VN introduced with the 113º but larger cam. Then later they made the cam a tad smaller, but tightened the LSA to 111 which in my opinion seems to respond better to mods than the older LN3, this is likely why.
When I ran these formulas, it confirmed that the Buick, at least for a high comp engine would want about 107. I run 109 ish in my red VP and I now know that it makes very good power for such a small cam. It was also far far easier to tune than the car that has the crow stage 3 with it's otherwise almost the same spec except the 113 LSA, it really did not like that cam at all.
It seems most engines go for that 108-109 figure, but a BBC is more in the 110 range. So the smaller the intake valve or the bigger the displacement vs the valve, the tighter the LSA wants to be. Even the LS engines, they also seem to demand the tighter LSA, in the 108-110 range too.
OEM went wide with LSA for emission reasons more than likely, and I have read that a wide LSA works well with shit exhausts, where as a tight LSA and heaps of overlap, it is absolutely critical to have a proper header and large, very low restriction exhaust, otherwise there is knock and loss of power due to poor exhaust scavenging/cylinder filling.
David and one other guy, Stan do sell the program that is more like a full sim like pipeworks or similar, but only does SBF, SBC and BBC for the cams atm, but I would be keen to have a play to get a feel for the other factors that change the LSA and other cam requirements.
I want to explore this more when I get the resources and time.
I encourage you to run your own real life examples and see what the formulas tell you, post them up!
When I ran this on the already true n tried combo of the FH cars/engines. It also spat out the figures within a degree of the actual physical cam I have in hand, and then the adv duration was exactly to the deg. So yeah, seems to be on the money and so simple to just get a good ballpark and sanity check if your cam is going to be decent or a steaming pile of poo. Or to even get a good one from the get go as part of the planing stage.
This is one of the videos out there and I'll ref it here.
https://www.youtube.com/watch?v=Y_oWghjGHYk
The programs I found here, but they cost.
However, they do like a short rental version too which is cheap enough to run a bunch of engines though and get what you need.
http://www.magneticlynx.com/DV/