## Part 1

The formula for a quadratic Bezier is:

**B**(t) = **a**(1-t)^{2} + 2**b**t(1-t) + **c**t^{2}
= **a**(1-2t+t^{2}) + 2**b**t - 2**b**t^{2} + **c**t^{2}
= (**a**-2**b**+**c**)t^{2}+2(**b**-**a**)t + **a**

where bold indicates a vector. With **B**_{x}(t) given, we have:

x = (**a**_{x}-2**b**_{x}+**c**_{x})t^{2}+2(**b**_{x}-**a**_{x})t + **a**_{x}

where **v**_{x} is the x component of **v**.

According to the quadratic formula,

-2(**b**_{x}-**a**_{x}) ± 2√((**b**_{x}-**a**_{x})^{2} - **a**_{x}(**a**_{x}-2**b**_{x}+**c**_{x}))
t = -----------------------------------------
(2**a**_{x}(**a**_{x}-2**b**_{x}+**c**_{x}))
**a**_{x}-**b**_{x} ± √(**b**_{x}^{2} - **a**_{x}**c**_{x})
= ----------------------
**a**_{x}(**a**_{x}-2**b**_{x}+**c**_{x})

Assuming a solution exists, plug that t back into the original equation to get the other components of **B**(t) at a given x.

## Part 2

Rather than producing a second Bezier curve that coincides with part of the first (I don't feel like crunching symbols right now), you can simply limit the domain of your parametric parameter to a proper sub-interval of [0,1]. That is, use part 1 to find the values of t for two different values of x; call these t-values i and j. Draw **B**(t) for t ∈ [i,j]. Equivalently, draw **B**(t(j-i)+i) for t ∈ [0,1].