Before I begin the problem, I use P0, P1, P2, and P3 for the four cubic Bezier points, and 't' since it's parametric. Also, I have searched for a similar problem in this site, as well as Google, and couldn't find one. I apologize if this is a common question.

The problem: I am getting a slope of 0 for both dx/dt and dy/dt for cubic Beziers in these two cases

```
1: t = 0 and P0 == P1
2: t = 1 and P2 == P3
```

Here's an example to illustrate (1), where t = 0 and P0 == P1.

Find the tangent (i.e dx/dt and dy/dt) of the following cubic Bezier at t = 0:

```
(100, 100) (100, 100) (150, 150) (200, 100)
```

To find the tangent, we'd want the first derivative of the cubic Bezier:

```
Cubic Bezier definition
B(t) = (1-t)^3P0 + 3t(1-t)^2P1 + 3t^2(1-t)P2 + t^3P3
First derivative of a bezier curve (if you'd like to see the steps I used to get here, let me know)
B'(t) = (-3P0 + 9P1 - 9P2 + 3P3)t^2 + (6P0 - 12P1 + 6P2)t + (-3P0 + 3P1)
```

Plugging in t = 0 to the first derivative equation, we get

```
B'(0) = -3P0 + 3P1
```

And finally, recall that P0 = P1 = (100, 100), so dx/dt and dy/dt are:

```
dx/dt = dy/dt = -3*(100) + 3*(100) = 0
```

This tells me...there is no tangent at t = 0 for this cubic Bezier. Which makes no sense if you were to graph and look at it.

What I'm doing to get a non-zero slope is to: Treat the points P1, P2, and P3 like a quadratic Bezier, convert them into the equivalent cubic Bezier, THEN find the first derivative at t = 0. Is there any way I can avoid doing that? I'm finding it difficult to accept a tangent that has 0 for dx/dt and dy/dt. Thanks for your help.