# Generating Position Vectors from Numpy Meshgrid

I'll try to explain my issue here without going into too much detail on the actual application so that we can stay grounded in the code. Basically, I need to do operations to a vector field. My first step is to generate the field as

`x,y,z = np.meshgrid(np.linspace(-5,5,10),np.linspace(-5,5,10),np.linspace(-5,5,10))`

Keep in mind that this is a generalized case, in the program, the bounds of the vector field are not all the same. In the general run of things, I would expect to say something along the lines of

`u,v,w = f(x,y,z)`.

Unfortunately, this case requires so more difficult operations. I need to use a formula similar to where the vector r is defined in the program as `np.array([xgrid-x,ygrid-y,zgrid-z])` divided by its own norm. Basically, this is a vector pointing from every point in space to the position (x,y,z)

Now Numpy has implemented a cross product function using `np.cross()`, but I can't seem to create a "meshgrid of vectors" like I need. I have a lambda function that is essentially

```xgrid,ygrid,zgrid=np.meshgrid(np.linspace(-5,5,10),np.linspace(-5,5,10),np.linspace(-5,5,10)) B(x,y,z) = lambda x,y,z: np.cross(v,np.array([xgrid-x,ygrid-y,zgrid-z]))```

Now the array `v` is imported from another class and seems to work just fine, but the second array, `np.array([xgrid-x,ygrid-y,zgrid-z])` is not a proper shape because it is a "vector of meshgrids" instead of a "meshgrid of vectors". My big issue is that I cannot seem to find a method by which to format the meshgrid in such a way that the `np.cross()` function can use the position vector. Is there a way to do this?

Originally I thought that I could do something along the lines of:

```x,y,z = np.meshgrid(np.linspace(-2,2,5),np.linspace(-2,2,5),np.linspace(-2,2,5)) A = np.array([x,y,z]) cross_result = np.cross(np.array(v),A)```

This, however, returns the following error, which I cannot seem to circumvent:

```Traceback (most recent call last): File "<stdin>", line 1, in <module> File "C:\Python27\lib\site-packages\numpy\core\numeric.py", line 1682, in cross raise ValueError(msg) ValueError: incompatible dimensions for cross product (dimension must be 2 or 3)```

• Can you post some more representative formula (`x`,`y` and `z` don't appear in it right now) and some example data and desired output? – Nils Werner Oct 28 '19 at 13:23
• Using `X, Y, Z = np.meshgrid(x, y, z)`, I feel like `A = np.array([X, Y, Z ])` gives you an array of position vectors. This can be fed directly to `np.cross`, and you can specify along which are axis the coordinates are using `axisa` or `axisb`. – Liris Oct 28 '19 at 14:14
• I'm not totally following your question. Is `v` a fixed vector field associated to the volume defined by the grid `x,y,z`? And are you trying to compute `B(x,y,z)`? – Quang Hoang Oct 28 '19 at 17:07
• @Liris, That was my initial intuition, but it gives the error that I have added above. My guess is that this produces an array of arrays, which numpy assumes is something like a 3x50 matrix that cannot be crossed. – BooleanDesigns Oct 28 '19 at 18:13
• @QuangHoang, Yes, in this case, `v` is the vector dl in the equation, which I have as a numpy array from a class in a different part of the program. The real issue is constructing the r vector because I need to create essentially a meshgrid of vectors pointing from the point `(x,y,z)` to any given point in the meshgrid. – BooleanDesigns Oct 28 '19 at 18:15

There's a work around with `reshape` and broadcasting:

``````A = np.array([x_grid, y_grid, z_grid])
# A.shape == (3,5,5,5)

def B(v, p):
'''
v.shape = (3,)
p.shape = (3,)
'''
shape = A.shape

Ap = A.reshape(3,-1) - p[:,None]

return np.cross(v[None,:], Ap.reshape(3,-1).T).reshape(shape)

print(B(v,p).shape)
# (3, 5, 5, 5)
``````
• what is `p`? is `p` this position? – BooleanDesigns Oct 29 '19 at 2:31
• `p` is your reference point, i.e., `p= (x,y,z)` in your post. – Quang Hoang Oct 29 '19 at 2:31

I think your original attempt only lacks the specification of the axis along which the cross product should be executed.

``````x, y, z = np.meshgrid(np.linspace(-2, 2, 5),np.linspace(-2, 2, 5), np.linspace(-2, 2, 5))
A = np.array([x, y, z])
cross_result = np.cross(np.array(v), A, axis=0)
``````

I tested this with the code below. As an alternative to `np.array([x, y, z])`, you can also use `np.stack(x, y, z, axis=0)`, which clearly shows along which axis the meshgrids are stacked to form a meshgrid of vectors, the vectors being aligned with axis 0. I also printed the shape each time and used random input for testing. In the test, the output of the formula is compared at a random index to the cross product of the input-vector at the same index with vector v.

``````import numpy as np

x, y, z = np.meshgrid(np.linspace(-5, 5, 10), np.linspace(-5, 5, 10), np.linspace(-5, 5, 10))
p = np.random.rand(3) # random reference point
A = np.array([x-p, y-p, z-p]) # vectors from positions to reference
A_bis = np.stack((x-p, y-p, z-p), axis=0)
print(f"A equals A_bis? {np.allclose(A, A_bis)}") # the two methods of stacking yield the same

v = -1 + 2*np.random.rand(3) # random vector v

B = np.cross(v, A, axis=0) # cross-product for all points along correct axis
print(f"Shape of v: {v.shape}")
print(f"Shape of A: {A.shape}")
print(f"Shape of B: {B.shape}")

print("\nComparison for random locations: ")
point = np.random.randint(0, 9, 3) # generate random multi-index
a = A[:, point, point, point] # look up input-vector corresponding to index
b = B[:, point, point, point] # look up output-vector corresponding to index
print(f"A[:, {point}, {point}, {point}] = {a}")
print(f"v = {v}")
print(f"Cross-product as v x a:         {np.cross(v, a)}")
print(f"Cross-product from B (= v x A): {b}")
``````

The resulting output looks like:

``````A equals A_bis? True
Shape of v: (3,)
Shape of A: (3, 10, 10, 10)
Shape of B: (3, 10, 10, 10)

Comparison for random locations:
A[:, 8, 1, 1] = [-4.03607312  3.72661831 -4.87453077]
v = [-0.90817859  0.10110274 -0.17848181]
Cross-product as v x a:         [ 0.17230515 -3.70657882 -2.97637688]
Cross-product from B (= v x A): [ 0.17230515 -3.70657882 -2.97637688]
``````