Difference between revisions of "Maximum Escape Angle"
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With a maximum Robot velocity of 8.0, a theoretical Maximum Escape Angle would be <code>asin(8.0/Vb)</code>. Note that the actual maximum depends on the enemy's current heading, speed, and [[Wall Distance]]. | With a maximum Robot velocity of 8.0, a theoretical Maximum Escape Angle would be <code>asin(8.0/Vb)</code>. Note that the actual maximum depends on the enemy's current heading, speed, and [[Wall Distance]]. | ||
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== See Also == | == See Also == | ||
| − | * [[Maximum Escape Angle/Precise]] - | + | * [[Maximum Escape Angle/Precise Positional]] - A more precise method of calculating Maximum Escape Angle, that doesn't require movement simulation. |
| + | * [[Maximum Escape Angle/Precise]] - A sophisticated calculation for Maximum Escape Angle, using [[Precise Prediction]]. | ||
| + | {{Targeting Navbox}} | ||
[[Category:Robocode Theory]] | [[Category:Robocode Theory]] | ||
[[Category:Terminology]] | [[Category:Terminology]] | ||
Latest revision as of 14:39, 5 September 2012
When firing, the Maximum Escape Angle (MEA) is the largest angle offset from zero (i.e., Head-On Targeting) that could possibly hit an enemy bot, given the Game Physics of Robocode.
Calculation
Let's assume a triangle with sides a, b and c and angles (vertices) A, B, and C. A is the angle opposite to a, B is opposite to b, and C is opposite to c. The Law of sines says that:
Now let's say that your bot is in the vertex A and the enemy bot is in the vertex C. We will fire a bullet with angle A to hit the bot in vertex B. We know the value of b (it is the distance D from your bot to the enemy).
We don't know c, but we know that it will be the distance traveled by the bullet. Also, we know that a will be the distance traveled by the enemy bot. If we put a, b, and c as a function of time, we have:
b = D c = Vb * t (Vb is the bullet speed) a = Vr * t (Vr is the enemy bot velocity)
Now, using the Law of sines:
a/sin(A) = c/sin(C) -> Vr*t / sin(A) = Vb*t / sin(C) -> sin(A) = Vr/Vb * sin(C) -> A = asin(Vr/Vb * sin(C))
We don't know the value of C, but we can take the worst scenario where
C = PI/2 (sin(C) = 1) to get a Maximum Escape Angle of
A = asin(Vr/Vb * 1) = asin (Vr/Vb).
With a maximum Robot velocity of 8.0, a theoretical Maximum Escape Angle would be asin(8.0/Vb). Note that the actual maximum depends on the enemy's current heading, speed, and Wall Distance.
See Also
- Maximum Escape Angle/Precise Positional - A more precise method of calculating Maximum Escape Angle, that doesn't require movement simulation.
- Maximum Escape Angle/Precise - A sophisticated calculation for Maximum Escape Angle, using Precise Prediction.
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