From:* Byron Short
\nDate:* Wed*Dec*3,*2003* 10:31 am
\nSubject:* Re: [evolution-disc.] Re: Minimizing Distance vs. a Proper Line<\/p>\n
Yeah, I’m still lurking…<\/p>\n
The slalom formula is:<\/p>\n
(pi \/ 8 ) * sqrt( d \/ g)<\/p>\n
where d is the lateral displacement of the vehicle in feet, and g is the
\npeak g capability of the vehicle in g’s. When we say “lateral
\ndisplacement” we mean “how far do you have to move the vehicle from peak
\nleft to peak right to get around the cones. This usually means the
\nwidth of the vehicle plus the width of the cone when the cones are in a
\nstraight line, but you can compute it with some offset either positive
\nor negative if the course design dictates that.<\/p>\n
When you solve for the formula you get a number that is typically around
\n1, which corresponds to the seconds to go from one cone to the next in a
\nforever, never-ending, consistently spaced slalom. In the real world we
\ncan and do shortcut the first and last cones of slaloms, but the middle
\ncones are subject to this formula.<\/p>\n
Also, you’ll note that there’s no variable for the distance between
\ncones because that doesn’t matter. Unlike a radius turn, the speed in
\nthis cases increases in direct proportion to the distance between the
\ncones so unless you get to ridiculously small gates where hand speed,
\npower steering pump, weird ackerman angles, etc, become factors, the
\ndistance between cones doesn’t matter. However, as Rick pointed out,
\nthe distance you miss the cones by increases d and increases the time
\nconsiderably.<\/p>\n
For instance, let’s take an autocross car that pulls 1g and is 5.5 feet
\nwide, going past a cone that is 1 foot wide at the base. This means<\/p>\n
t = (pi \/ 8 ) * sqrt( 6.5 \/ 1 ) = 1.001 sec<\/p>\n
If we miss each cone by a foot on each side, then we have increased d
\nnot by 1foot, but by 2 feet (one foot on each side of each cone). So now<\/p>\n
t=(pi \/ 8 ) * sqrt( 8.5\/1 ) = 1.145 sec<\/p>\n
For a total difference of 0.144 per cone!<\/p>\n
This formula was derived with invaluable help from (yep, you guessed it)
\nJay Mitchell back around 1994 or so. I’ve tested it empirically for
\nyears and still find that it holds water, no matter the size of the
\nvehicle (even dually pickups and Suburbans, down to shifter karts and
\nkid-karts), no matter the g-loads, no matter the distances (with the
\nabove caveat not withstanding). This simple formula is a lot of fun and
\nvery useful. In conjunction with a G-Cube you can use this formula to
\ncompute how much you missed the cones by, for instance. And you can
\ncertainly predict how fast a street car will slalom if you know it’s
\nwidth and have a good estimate of it’s lateral g limits.<\/p>\n
Okay, I’m getting back to real work now. Lurk mode ON!<\/p>\n
–Byron<\/p><\/blockquote>\n
There’s a couple key variables here – d (the lateral distance we have to move the car, roughly equal to its width), and g (the lateral grip the car produces).<\/p>\n
Let’s take a real world example – two cars with a 1.2g lateral limit, but one (Car A) is 66″ wide, the other (Car B) is 72.5″ wide. \u00a0The cones are in a typical straight line, with a 12″ base. \u00a0What will the difference in time be around each cone?<\/p>\n
Car A’s time: (pi\/8 ) * sqrt((5.5′ [car width]+.5′ [half of cone width]) \/1.2)<\/p>\n
=0.39269908169872415480783042290994 (we’ll round this to .3927) * sqrt(5)<\/p>\n
=.3927 * \u00a02.236 = \u00a0.878 seconds<\/p>\n
Car B’s time: (pi\/8 ) * sqrt((6.04′ [car width]+.5′ [half of cone width]) \/1.2)<\/p>\n
=.3927 * sqrt(5.45)<\/p>\n
=.3927 * 2.55 = \u00a0.916 seconds<\/p>\n
For a difference of .916-.878 = \u00a0.038 seconds per cone<\/p>\n
After having passed 5 cones, the narrower car has a 2 tenths of a second advantage. \u00a0Plenty of jackets have been won by less than this. \u00a0Plenty of courses out there where between the boxes and jogs and offsets in addition to regular slaloms, you’ve got to transition 20-30 times before the run is over. \u00a0It adds up.<\/p>\n
![\"\"](\"http:\/\/www.rhoadescamaro.com\/build\/wp-content\/uploads\/2011\/05\/IMG_0189s.jpg\" "\\"IMG_0189s\\"")
<\/a>Wide cars look cool, but you pay the price at every transition!<\/p>\n