Suppose I wanted to make an animated bar graph of a couple of planes' acceleration to their top speeds at a couple of different altitudes. What specifications would I need to calculate the figures to feed into that animation?
You would need to calculate total thrust in pounds. This can be done with a simplified formula.
375 x Prop Efficiency X Horsepower / Initial Speed
You need to calculate total drag in pounds. This is more complicated as you need data from which to make the calculation.
With these two data points, you can then calculate acceleration.
One can calculate a reasonably close rate of acceleration if we can determine several unknowns. These are propeller efficiency and drag. We can use a constant for the the prop, but may have to estimate drag.
We can calculate the approximate thrust available at a given speed. To do this, we must estimate the efficiency of the propeller. If we begin at 150 mph, a typical WWII prop will demonstrate approximately 70% average efficiency over its normal speed range (can vary from 60% up to just over 80% and back down again). If this is applied to all examples, it becomes a fair, if not perfectly accurate method. Note that 2,400 hp in the Tempest is at 11 lb boost.
Thus, for the Tempest:
375 x .7 x 2,400 / 150 = 4,200 lb of thrust.
For the Spitfire Mk.XIV:
375 x .7 x 2050 / 150 = 3,588 lb of thrust.
Now that we know the available thrust, we can calculate acceleration in feet per second, per second. Of course, we need to know what the total drag is. This can also be calculated or obtained from a reliable source. In this case, I'm going to use what I believe are close estimates.
Total drag for the Tempest: 1,350 lb
Total drag for the Spit XIV: 990 lb
Thus, thrust - drag / mass (in slugs) = initial acceleration in feet per second, per second.
Tempest: 4200 (thrust) - 1350 (drag) / (11480/32.2) = 7.99 feet per second, per second.
Spit XIV: 3588 - 1090 / (8500/32.2) = 9.46 feet per second, per second.
Let's toss in the P-51D for comparison. I am calculating based upon an empty rear aux fuel tank (always burned off first on climb-out)
P-51D: 3010 - 845 / (9611/32.2) = 7.25 feet per second, per second.
Results, initial acceleration rate in g:
Spitfire Mk.XIV: 0.294 g
Tempest Mk.V: 0.248 g
P-51D: 0.225 g
Initial acceleration in the game, full load except for P-51D with 75% fuel. Time to accelerate from 150 mph to 200 mph at 100 feet ASL.
Spitfire Mk.XIV: 8.12 seconds (18 lb boost)
Tempest Mk.V: 8.16 seconds (10.5 lb boost)
P-51D: 10.81 seconds (67 in/hg boost)
The relationship between the Spitfire XIV and P-51D is reasonably close to the calculated acceleration (30% calculated vs 33% actual testing)
However, the difference between the Tempest and P-51D is much different (10% calculated vs 32% actual testing). In short, the AH2 Tempest appears to accelerate much faster than it should for the given boost and horsepower, at least in theory. Even if I reduce the Tempest's drag by 200 lb, it still should not accelerate as fast as it does in the game.
Dean published drag figures for most American fighters in his book, America's Hundred Thousand.
Note that acceleration is not going to be linear as propeller thrust decreases as speed increases. Also, you would have to know the available power at the various altitudes to calculate for each increment. There is also a gradual rise in drag as speed increases, which means an increasing error as speeds rise. All of these variables make accurate data over a speed and altitude range very difficult to pinpoint.
My regards,
Widewing
