# Some physical insight

##
1 ) For the target being a "Point Object"

So you have to solve the VECTOR equation

**Position**_{bullet} [ time=t_{1} > t_{0} ] == Position_{target} [ time=t_{1} > t_{0} ] -- (Eq 1)

Where the positions are given by the motion (also VECTOR) equations

**Position**_{object} [ t ] = Position_{object} [ t_{0} ] + Speed_{object} * ( t - t_{0} )

Now, the condition for the bullet to be able to reach the target is that the Eq 1 has solutions for x and y. Let's write down the equation for x:

**X**_{bullet} [ t_{0} ] + SpeedX_{bullet} * ( t - t_{0} ) = X_{target} [ t_{0} ] + SpeedX_{target} * ( t - t_{0} )

So for the collision time we have

**( t**_{Collision} - t_{0} ) = (x_{target} [ t _{0} ] - x_{bullet} [ t_{0} ] ) / (SpeedX_{bullet} - SpeedX_{target}) -- (Eq 2)

As we need solutions with t > t_{0}, that means that for having an intercept is enough that>

**Sign ( x**_{target}[ t_{0} ] - x_{bullet}[ t_{0} ] ) = Sign ( SpeedX_{bullet} - SpeedX_{target} ) -- (Eq 3)

`Which tells us the evident fact that if an object is moving faster than the other, and in the same direction, they will eventually collide.`

From Eq 2, you can see that for a given SpeedX_{target} **there exist infinite solutions** (as already pointed out in other answers) for t and SpeedX_{bullet}, so I think your specifications are not complete.

```
I guess (as stated in a commentary I made in another answer) thinking in a "tower defense" kind of game, that your bullets have a limited range.
```

So you need also another constraint:

**Distance [ Position**_{target} [ t_{Collision} - t_{0} ] - Position_{bullet} [ t_{0} ] ] < BulletRange -- (Eq 4)

```
Which still permits infinite solutions, but bounded by an upper value for the Collision time, given by the fact that the target may abandon the range.
```

Further, the distance is given by

Distance[v,u]= +Sqrt[ (Vx-Ux)^2 + (Vx-Vy)^2 ]

So, Eq 4 becomes,

**
(X**_{target}[t_{Collision} - t_{0}] - X_{bullet}[t_{0}])^{2} + (Y_{target}[t_{Collision} - t_{0}] - Y_{bullet}[t_{0}])^{2} < BulletRange^{2} -- (Eq 5)

Note that { X_{bullet}[t_{0}] , Y_{bullet}[t_{0}} is the tower position.

Now, replacing in Eq 5 the values for the target position:

**
(X**_{target}[t_{0}] + SpeedX_{target} * (t-t_{0}) - X_{bullet}[t_{0}])^{2} + (Y_{target}[t_{0}] + SpeedY_{target} * (t-t_{0}) - Y_{bullet}[t_{0}])^{2} < BulletRange^{2} -- (Eq 6)

Calling the initial distances:

** **

**
****Dxt0 = X**_{target}[t_{0}] - X_{bullet}[t_{0}]

and

**
Dyt0 = Y**_{target}[t_{0}] - Y_{bullet}[t_{0}]

Equation 6 becomes

**
(Dtx0 + SpeedX**_{target} * (t-t_{0}) )^{2} + (Dty0 + SpeedY_{target} * (t-t_{0}))^{2} < BulletRange^{2} -- (Eq 7)

Which is a quadratic equation to be solved in t-t0. The positive solution will give us the largest time allowed for the collision. Afterwards the target will be out of range.

Now calling

Speed_{target} ^{2} = SpeedX_{target} ^{2} + SpeedY_{target} ^{2}

and

H = Dtx0 * SpeedX_{target} + Dty0 * SpeedY_{target}

T_{Collision Max} = t_{0} - ( H
+/- Sqrt ( BulletRange^{2} * Speed_{target} ^{2} - H^{2} ) ) / Speed_{target} ^{2}

```
So you need to produce the collision BEFORE this time. The sign of the
square root should be taken such as the time is greater than t
```_{0}

```
``````
After you select an appropriate flying time for your bullet from the visual
effects point of view, you can calculate the SpeedX and SpeedY for the bullet
from
```

**SpeedX**_{bullet} = ( X_{target} [ t_{0} ] - X_{bullet} [ t_{0} ] ) / ( t_{Collision} - t_{0} ) + SpeedX_{target}

and

**SpeedY**_{bullet} = ( Y_{target} [ t_{0} ] - Y_{bullet} [ t_{0} ] ) / ( t_{Collision} - t_{0} ) + SpeedY_{target}

##
2 ) For the target and tower being "Extensive Objects"

Now, it is trivial to generalize for the case of the target being a circle of radius R. What you get, is the equivalent of an "extended range" for the bullets. That extension is just R.

So, replacing BulletRange by (BulletRange + R) you get the new equations for the maximum allowed collision time.

If you also want to consider a radius for the cannons, the same considerations apply, giving a "double extended range

**NewBulletRange = BulletRange + R**_{Target} + R_{Tower}

## Unlimited Range Bullets

In the case that you decide that some special bullets should not have range (and detection) limitations, there is still the screen border constraint. But it is a little more difficult to tackle. Should you need this kind of projectile, leave a comment and I'll try to do some math.