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Having a linear interpolation (lerp) function looking like:

/// Performs a linear interpolation between two vectors. (@p v1 toward @p v2)
///  @param[out]    dest    The result vector. [(x, y, x)]
///  @param[in]     v1      The starting vector.
///  @param[in]     v2      The destination vector.
///  @param[in]     t       The interpolation factor. [Limits: 0 <= value <= 1.0]
inline void dtVlerp(float* dest, const float* v1, const float* v2, const float t)
    dest[0] = v1[0]+(v2[0]-v1[0])*t;
    dest[1] = v1[1]+(v2[1]-v1[1])*t;
    dest[2] = v1[2]+(v2[2]-v1[2])*t;

Here by linear extrapolation I mean finding a position on line (see the drawing) enter image description here

will it work for linear extrapolation (say providing coef > 1 or less than 0)?

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Yes, the only difference between linear interpolation and linear extrapolation is that in interpolation, you estimate the value between known data points, and in extrapolation, outside the known range. – Daniel Fischer Mar 14 '13 at 11:39

1 Answer 1

up vote 2 down vote accepted

Yes, extrapolation is the same as interpolation (in this context, at least).

If you recall from high-school geometry, any line is defined by an equation of the form:

y = mx + c

where m is the gradient and c is an offset (specifically, the y-axis intercept). If you look at your code above, you'll see each dimension has an equation of the form:

dest = v1 + (v2-v1)*t

which is the same! We've simply substituted as follows:

  • y <-- dest
  • x <-- t
  • m <-- (v2-v1)
  • c <-- v1

So you can set t to any value (not just in the range [0,1]) and get a unique point somewhere on the line.

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