How do I calculate the acceleration using only 3D distances?

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lil brain
lil brain on 15 Apr 2022
Commented: Les Beckham on 18 Apr 2022
Hi,
I have a list of distances in each cell of acc_dist . The first three columns in each cell are xyz coordinates. So column one are all x, column two are all y, and column three are all z. The rows are the coordinate points measured at a speed of 72 Hz.
I am trying to compute the acceleration of these coordinate points by first calculating the 3D euclidean distance between each point and the adjacent point like so:
sqrt((x2-x1).^2+(y2-y1).^2+(z2-z1).^2)
And then I am trying to use the acceleration formula like so:
acceleration = dv/dt
dv = change in velocity
dt = change in time
How would I go about calculating the acceleration for the entire length of each list?
Thank you!
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Walter Roberson
Walter Roberson on 15 Apr 2022
Use gradient() twice.
However... acceleration is a signed vector quantity, derived from velocity which is a signed vector quantity. This is a problem for you because sqrt((x2-x1).^2+(y2-y1).^2+(z2-z1).^2) is not signed and not a vector. You are calculating speed, not velocity.
lil brain
lil brain on 15 Apr 2022
Edited: lil brain on 15 Apr 2022
@Walter Roberson I dont think I follow could you elaborate on that?

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Accepted Answer

Les Beckham
Les Beckham on 15 Apr 2022
Edited: Les Beckham on 15 Apr 2022
Ran in:
load acc_dist.mat
xyz = cell_of_double_pre_ballsCopy{1};
dxyz = diff(xyz); % difference between adjacent points in xyz coordinates
v = sqrt(dxyz(:,1).^2 + dxyz(:,2).^2 + dxyz(:,3).^2) * 72;
a = gradient(v, 1/72);
t = 0:1/72:(length(a)-1)/72;
plot(t,v)
plot(t,a)
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Walter Roberson
Walter Roberson on 17 Apr 2022
Ran in:
@Les Beckham
"Apply this function to every element of this array" is one of the fundamental array operations in theory.
Consider for example,
A = [1 3 5]
A = 1×3
1 3 5
B = A.^2
B = 1×3
1 9 25
From a theoretical perspective, this is not "squaring the vector": from a theoretical perspective, it is "Apply the function x->x^2 to each element of A, returning an array of the results.
This is frequenty called the "map" operation. And having a brief call that says that you are mapping a function over all of the elements of an array, is often significantly clearer than using a for loop.

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