# Simple Steering Behaviour: Explain This Line

I am reading the book Programming Game AI by Example, and he gives code for a steering behaviour which causes the entity to decelerate so that it arrives gracefully at a target. After calculating dist, the distance from target to source he then (essentially) does this

``````double speed = dist/deceleration;
``````

I just cannot understand where this comes from however, am I just missing something really obvious? It is not listed as a known error in the book so I am guessing it is correct.

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This equation doesn't make sense. Would you mind showing us what he actually writes. –  Jean-François Corbett Sep 17 '12 at 12:02

If there was some physical truth to this, the units would have match up on either side.

From what I understand, this is akin to Zeno's paradoxes where you are trying to reach something, but you never get there because you always only travel one `n`th of the remaining distance.

Suppose

• the simulation proceeds at intervals of one second at a time.
• `deceleration` = 5
• `distance` = 1000 meters

With these initial conditions, `speed` will be set to `200` meters per second. Because the simulation proceeds at intervals of one second, we will travel exactly `200` meters (i.e. one fifth of the remaining distance), and end up at a distance of `800` meters from the target. The new speed is determined to be: `160` meters per second

Here is what happens in the first 30 seconds:

The last 30 seconds:

The last 10 seconds:

Observations

• Within the first 30 seconds, we travel roughly 998 meters
• Within the first 50 seconds, we cover 999.985 meters
• Within the last 10 seconds, we cover only ~1.2cm

As you can see, you get almost there very quickly, but it takes a long time to get close.

Plots by WolframAlpha

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Game distance is rounded to pixels (integer), therefore if you get in the last 30 seconds under 0.5, you stop. –  Petr Oct 20 '12 at 6:34
@Petr we don't know what the scale is. –  phant0m Oct 20 '12 at 9:31

Maybe there is something missing in your calculation. For a constant accelaration (or decelleration), and ignoring initial condictions, the speed is

``````v = a * t
``````

and the distance is

``````d = a * t^2 / 2
``````

If you eliminate t in both equations you get

``````v = a * sqrt(2 * d / a)
``````
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The distance should be half that ;) –  phant0m Sep 16 '12 at 15:23
@phant0m - you are right, I should revise my integrations. –  rpsml Sep 16 '12 at 21:28
These equations you regurgitate are only valid when starting from `v = 0` and not when decelerating i.e. starting from `v = v_0 ≠ 0` as is the case in this question. –  Jean-François Corbett Sep 17 '12 at 12:00
Yeah. That is what 'ignoring initial conditions mean'. But the correction for that is pretty obivous, isn't it? –  rpsml Sep 17 '12 at 22:10
For deceleration, it may not be that obvious. –  phant0m Sep 20 '12 at 7:10