def createCurve(pt, n, ang=-20, HD = None):
###############################
# circular curve consisting of n points
# input: pt (starting point: x,y,z)
# n (numb of points in the curve)
# ang(angle in degrees till the curve goes)
# HD (height distribution
# output: x (x array of the points)
# y (y array of the points)
# z (z array of the points)
# description: the curve start in pt and then
# it is rotated by "angle" degrees.
x = np.zeros(n)
y = np.zeros(n)
z = np.zeros(n)
for i in range(n):
tmp = Point(x=pt.X, y=pt.Y, z=pt.Z)
tmp.rotZ(i*ang/n)
x[i] = tmp.X
y[i] = tmp.Y
z[i] = tmp.Z
if HD:
z[i] = getHeight(tmp, HD)
return x, y, z
def getAverage2D(IN, x, y, z, propName, typeline, typeavg, dtheta, dz=1.0):
###############################
# calculate the mass/area average of a property over a line/arc
# input: IN (input file)
# x, y, z (coordinates of the curve (can be a line or arc))
# propName (name of the property that is being averaged)
# typeline (type of curve, can be either line or arc)
# typeavg (type of average, can be either area or mass based)
# dtheta (only for ARC curves, is the total arc lenght in degrees)
# dz (only for 3D, is discretization in z-direction)
# output: average
# observation: this function is used in getAverage3D() which is called at each z-coordinate. That is why dz
# comes into the function. For quasi-3D we assumed dz=1.0
# extracting the line from the tecplot file
LINE = tp.data.extract.extract_line(zip(x, y, z))
n = len(y) - 1
# extracting variables
rho = (LINE.values('RHO').as_numpy_array())
prop = (LINE.values(propName).as_numpy_array())
vel_x = (LINE.values('vrel-X').as_numpy_array())
vel_y = (LINE.values('vrel-Y').as_numpy_array())
vel_z = (LINE.values('vrel-Z').as_numpy_array())
angle = np.arctan((LINE.values('Y').as_numpy_array())/(LINE.values('X').as_numpy_array()))/ (4 * np.arctan(1.0) / 180.)
# to check if all the line is include in the domain. In the case it is not, the lenght is changed
# which corresponds to the amount of intersection with the tecplot file
if (n+1)!=len(rho):
n = len(rho) - 1
momentum = np.zeros(n + 1)
mom = np.sqrt(vel_x ** 2 + vel_y ** 2 + vel_z ** 2) * rho
m = np.ones(n + 1)
# calculating the total and partial area
if typeline == 'ARC':
pt1 = Point(x=x[0], y=y[0], z=z[0])
radius = pt1.rad
dArea = getArcLenght(IN, radius, dtheta) * dz / n
for i in range(n+1):
# calculating the normal unit vector to the surface
normVect = Point(rad=radius, theta=angle[i], z=0) # unit vector normal to the surface
# normVect.rotZ(180) # the flow goes inwards
normVect.scale(1 / normVect.magnitude()) # making it unit vector
# projecting the velocity to the normal vector
momentum[i] = np.abs((vel_x[i] * normVect.X * rho[i]) + (vel_y[i] * normVect.Y * rho[i])
+ (vel_z[i] * normVect.Z * rho[i]))
else:
pt1 = Point(x=x[0], y=y[0], z=z[0])
pt2 = Point(x=x[-1], y=y[-1], z=z[-1])
dArea = getLineDistance(IN,pt1, pt2,n+1) *dz
# calculating the normal unit vector to the surface
normVect = pt2 - pt1
normVect.rotZ(-90) # making it normal to the line
normVect.scale(1/normVect.magnitude()) # making it unit vector
# projecting the velocity to the normal vector
for i in range(n + 1):
momentum[i] = np.abs((vel_x[i] * normVect.X * rho[i]) + (vel_y[i] * normVect.Y * rho[i])
+ (vel_z[i] * normVect.Z * rho[i]))
# calculating the average
if typeavg == 'MASS':
m_prop = np.sum(momentum * prop * dArea)
m_mass = np.sum(momentum * dArea)
elif typeavg == 'AREA':
m_prop = np.sum(m * prop * dArea)
m_mass = np.sum(m * dArea)
else:
m_prop = np.sum(mom*prop * dArea)
m_mass = np.sum(mom*dArea)
return m_prop, m_mass
