In my program which traces out the path of a particle, I get the following error:

```
Traceback (most recent call last):
File "C:\Users\Felix\Google Drive\Research\particles.py", line 154, in <module>
bfield += b_X(r_p(r,pos[2]))*(r_p(r,pos[2])/r)
*((r-r_p(r,pos[2]))**2+pos[2]**2)^(-1/2)*np.array
([(1-r_p(r,pos[2])/r)*pos[0],(1-r_p(r,pos[2])/r)*pos[1],pos[2]])
TypeError: ufunc 'bitwise_xor' not supported for the input types,
and the inputs could not be safely coerced to any supported types
according to the casting rule ''safe''
```

I can't seem to find what's going on. I don't have any instances of xor (although I suppose it might be encoded in an if/else statement). I don't know if the problem is local to the line so I will paste the entire code (up to that line) below, with comments and certain unnecessary parts edited out to decrease the probability of TLDR.

```
import numpy as np
from mpl_toolkits.mplot3d import Axes3D
import matplotlib.pyplot as plt
import sys, random, math
q_b=5.19230065e-39
m=1.78266184e-10
pos_0=np.array([-8.33937979, 0.00, 0.00])
vel_0=np.array([0.0, 0.0, 0.0])*(3.24077929e-20)
dt=1e8
distance_to_track= .00001
b1=0.1e-10
b2=3.0e-10
b3=-0.9e-10
b4=-0.8e-10
b5=-2.0e-10
b6=-4.2e-10
b7=0.0e-10
b8=2.7e-10
b_ring=0.1e-10
h_disk=0.4
w_disk=0.27
B_n=1.4e-10
B_s=-1.1e-10
r_n=9.22
r_s=16.7
w_h=0.2
z_0=5.3
B_X=4.6e-10
Theta0_X=49.0
rc_X=4.8
r_X=2.9
c=9.7156e-12
def mag(V):
return math.sqrt(V[0]**2+V[1]**2+V[2]**2)
pos=np.array([0.0, 0.0, 0.0])
for N in range(2):
pos[N]=pos_0[N]
vel=vel_0
trailx=(pos[0],)
traily=(pos[1],)
trailz=(pos[2],)
gam=1/math.sqrt(1-(mag(vel)/c)**2)
if gam!=1:
KE=m*c**2*(gam-1)*5.942795e48 #KE, converted to GeV
else:
KE=m*mag(vel)**2/2
KEhistory=(KE,)
distance_tracked=0.0
time=0.0
def L(Z,H,W):
return (1+math.e**(-2*(abs(Z)-H)/W))**-1
i=11.5
r_negx=np.array([5.1, 6.3, 7.1, 8.3, 9.8, 11.4, 12.7, 15.5])
def r_i(T,I):
return r_negx[I]*math.e**((T-math.pi)*math.tan(math.radians(i)))
def r_p(R,Z):
if abs(Z) >= math.tan(Theta0_X)*(R-rc_X):
return R*rc_X/(rc_X+abs(Z)/math.tan(Theta0_X))
else:
return R-abs(Z)/math.tan(Theta0_X)
def b_X(R_P):
return B_X*math.e**(-R_P/r_X)
if mag(vel) >= c:
print("Error: Initial velocity cannot exceed the speed of light.
Currently, it is",mag(vel)/c,"times c.")
sys.exit("Stopped program.")
while distance_tracked < distance_to_track:
r=math.sqrt(pos[0]**2+pos[1]**2)
theta=math.atan(pos[1]/pos[0])
gam=1/math.sqrt(1-(mag(vel)/c)**2)
if pos[2]>=0:
bfield = math.e**(-abs(pos[2])/z_0)*L(pos[2],h_disk,w_disk)*
B_n*(1-L(r,r_n,w_h)) * np.array([-1*pos[1]/r, pos[0]/r,0])
else:
bfield = math.e**(-abs(pos[2])/z_0)*L(pos[2],h_disk,w_disk)*
B_s*(1-L(r,r_s,w_h)) * np.array([-1*pos[1]/r, pos[0]/r,0])
if r_p(r,pos[2]) < rc_X:
bfield += b_X(r_p(r,pos[2]))*(r_p(r,pos[2])/r)**2*
((r-r_p(r,pos[2]))**2+pos[2]**2)^(-1/2)*
np.array([(1-r_p(r,pos[2])/r)*pos[0],
(1-r_p(r,pos[2])/r)*pos[1],pos[2]])
else:
bfield += b_X(r_p(r,pos[2]))*(r_p(r,pos[2])/r)*((r-r_p(r,pos[2]))**2+
pos[2]**2)^(-1/2)*np.array([(1-r_p(r,pos[2])/r)*pos[0],
(1-r_p(r,pos[2])/r)*pos[1],pos[2]])
```