You can just create a differential scheme, i.e. model speed and coordinate of the source point at discrete moments in time. Say you fix some `dt = 0.1 sec`

for example, starting speed is given by blue vector as `v0`

. We start at `x0`

.
Say `y[j]`

are the points of the black path.

Let `x1 = x0 + v1 * dt`

, where `v1 = v0 + (y[k(x0)+1] - x0) * f(abs(y[k(x0)+1] - x_0))`

. Where

`k(x0)`

is the index of the nearest to `x0`

point among `y[j]`

,

`f(x)`

is a function characterizing the 'force' pulling your trajectory to that of the defined path. It defined for nonnegative `x`

es only.

This models pulling your trajectory to the next point in the defined path to that closest to current modeled position on the trajectory.

A good example of `f(x)`

could be one modeling the gravitational force: `f(x) = K/(x * x)`

, where `K`

should be adjusted experimentally to be giving natural desired results.

Then `x2 = x1 + v2 * dt`

, where `v2 = v1 + (y[k(x1) + 1] - x1) * f(abs(y[k(x1) + 1] - x_1))`

and so on:

`x[n+1] = x[n] + v[n+1] * dt`

, where `v[n+1] = v[n] + (y[k(x[n]) + 1] - x[n]) * f(abs(y[k(x[n])+1] - x[n]))`

...

You'll have to adjust `dt`

and `K`

here. `dt`

should be small enough for the trajectory to be smooth. Bigger `K`

makes trajectory more close to defined precisely, smaller `K`

makes it more relaxed.

**Edit** now actually when I thought a little bit, I understand that selection of the force function `f`

was not good, as gravitational force allows space velocities, i.e. ability for your trajectory to fly away from the desired one infinitely if the initial speed is too big. So you should construct another function, possibly just something along the lines of `f(x) = K x`

or `f(x) = K x ^ alpha`

, where `alpha > 0`

. You see, this scheme is quite general, so you should experiment.