diff options
-rw-r--r-- | creator.py | 147 | ||||
-rw-r--r-- | evaluator.py | 52 |
2 files changed, 98 insertions, 101 deletions
@@ -53,14 +53,9 @@ class Coordinates: self.area = float() # Component material self.material = str() - # Upper coordinates - self.x_u = [] - self.z_u = [] - # Lower coordinates - self.x_l = [] - self.z_l = [] - # Coordinates x_u, z_u, x_l, z_l packed in single list - self.coord = [] + # Coordinates + self.x = [] + self.z = [] # The airfoil components know the Coordinates instance's coords global parent @@ -85,10 +80,8 @@ class Coordinates: print('Semi-span:', self.semi_span) print('Mass:', self.mass) print(num_of_dashes * '-') - print('x_u the upper x-coordinates:\n', np.around(self.x_u, round)) - print('z_u the upper z-coordinates:\n', np.around(self.z_u, round)) - print('x_l the lower x-coordinates:\n', np.around(self.x_l, round)) - print('z_l the lower z-coordinates:\n', np.around(self.z_l, round)) + print('x-coordinates:\n', np.around(self.x, round)) + print('z-coordinates:\n', np.around(self.z, round)) return None def info_save(self, save_path, number): @@ -182,14 +175,14 @@ class Airfoil(Coordinates): return theta def get_upper_coord(x): - x_u = x - get_thickness(x) * sin(get_theta(x)) - z_u = get_camber(x) + get_thickness(x) * cos(get_theta(x)) - return (x_u, z_u) + x = x - get_thickness(x) * sin(get_theta(x)) + z = get_camber(x) + get_thickness(x) * cos(get_theta(x)) + return (x, z) def get_lower_coord(x): - x_l = x + get_thickness(x) * sin(get_theta(x)) - z_l = get_camber(x) - get_thickness(x) * cos(get_theta(x)) - return (x_l, z_l) + x = x + get_thickness(x) * sin(get_theta(x)) + z = get_camber(x) - get_thickness(x) * cos(get_theta(x)) + return (x, z) # Densify x-coordinates 10 times for first 1/4 chord length x_chord_25_percent = round(self.chord / 4) @@ -200,10 +193,13 @@ class Airfoil(Coordinates): for x in x_chord: self.x_c.append(x) self.y_c.append(get_camber(x)) - self.x_u.append(get_upper_coord(x)[0]) - self.z_u.append(get_upper_coord(x)[1]) - self.x_l.append(get_lower_coord(x)[0]) - self.z_l.append(get_lower_coord(x)[1]) + self.x.append(get_upper_coord(x)[0]) + self.z.append(get_upper_coord(x)[1]) + # Behold the true power of Python list slicing! + # (This special list index reverses the list.) + for x in x_chord[::-1]: + self.x.append(get_lower_coord(x)[0]) + self.z.append(get_lower_coord(x)[1]) return None def add_mass(self, mass): @@ -211,8 +207,8 @@ class Airfoil(Coordinates): def info_print(self, round): super().info_print(round) - print('x_c the camber x-coordinates:\n', np.around(self.x_u, round)) - print('z_c the camber z-coordinates:\n', np.around(self.x_u, round)) + print('x_c the camber x-coordinates:\n', np.around(self.x, round)) + print('z_c the camber z-coordinates:\n', np.around(self.x, round)) return None @@ -223,12 +219,12 @@ class Spar(Coordinates): def __init__(self): super().__init__(parent.chord, parent.semi_span) - def add_coord(self, airfoil, spar_x): + def add_coord(self, airfoil, x_loc_percent): ''' Add a single spar at the % chord location given to function. Parameters: - coordinates: provided by Airfoil.coordinates[x_u, z_u, x_l, z_l]. + coordinates: provided by Airfoil.coordinates[x, z, x, z]. material: spar's material. Assumes homogeneous material. spar_x: spar's location as a % of total chord length. @@ -237,21 +233,22 @@ class Spar(Coordinates): ''' # Airfoil surface coordinates # unpacked from 'coordinates' (list of lists in 'Coordinates'). - x_u = airfoil.x_u - z_u = airfoil.z_u - x_l = airfoil.x_l - z_l = airfoil.z_l + x = airfoil.x + z = airfoil.z # Scaled spar location with regards to chord - loc = spar_x * self.chord - # bisect_left: returns index of first value in x_u > loc. - # Ensures that the spar coordinates intersect with airfoil surface. - spar_x_u = bi.bisect_left(x_u, loc) # index of spar's x_u - spar_x_l = bi.bisect_left(x_l, loc) # index of spar's x_l + loc = x_loc_percent * self.chord + # bisect_left: returns index of first value in x > loc + # starting from [0] + # bisect_right: returns index of first value in x > loc + # starting from [-1] (last list element). + # This ensures that the spar geom intersects with airfoil geom. + spar_x = bi.bisect_left(x, loc) # index of spar's x + spar_x = bi.bisect_left(x, loc) # index of spar's x # These x and y coordinates are assigned to the spar, NOT airfoil. - self.x_u.append(x_u[spar_x_u]) - self.z_u.append(z_u[spar_x_u]) - self.x_l.append(x_l[spar_x_l]) - self.z_l.append(z_l[spar_x_l]) + self.x.append(x[spar_x]) + self.z.append(z[spar_x]) + self.x.append(x[spar_x]) + self.z.append(z[spar_x]) return None def add_spar_caps(self, spar_cap_area): @@ -259,7 +256,7 @@ class Spar(Coordinates): return None def add_mass(self, mass): - self.mass = len(self.x_u) * mass + self.mass = len(self.x) * mass return None @@ -291,44 +288,44 @@ class Stringer(Coordinates): ''' # Find distance between leading edge and first upper stringer - interval = airfoil.spar.x_u[0] / (stringer_u_1 + 1) - # initialise first self.stringer_x_u at first interval + interval = airfoil.spar.x[0] / (stringer_u_1 + 1) + # initialise first self.stringer_x at first interval x = interval # Add upper stringers from leading edge until first spar. for _ in range(0, stringer_u_1): - # Index of the first value of airfoil_x_u > x - index = bi.bisect_left(airfoil.x_u, x) - self.x_u.append(airfoil.x_u[index]) - self.z_u.append(airfoil.z_u[index]) + # Index of the first value of airfoil_x > x + index = bi.bisect_left(airfoil.x, x) + self.x.append(airfoil.x[index]) + self.z.append(airfoil.z[index]) x += interval # Add upper stringers from first spar until last spar # TODO: stringer placement if only one spar is created - interval = (airfoil.spar.x_u[-1] - - airfoil.spar.x_u[0]) / (stringer_u_2 + 1) - x = interval + airfoil.spar.x_u[0] + interval = (airfoil.spar.x[-1] + - airfoil.spar.x[0]) / (stringer_u_2 + 1) + x = interval + airfoil.spar.x[0] for _ in range(0, stringer_u_2): - index = bi.bisect_left(airfoil.x_u, x) - self.x_u.append(airfoil.x_u[index]) - self.z_u.append(airfoil.z_u[index]) + index = bi.bisect_left(airfoil.x, x) + self.x.append(airfoil.x[index]) + self.z.append(airfoil.z[index]) x += interval # Find distance between leading edge and first lower stringer - interval = airfoil.spar.x_l[0] / (stringer_l_1 + 1) + interval = airfoil.spar.x[0] / (stringer_l_1 + 1) x = interval # Add lower stringers from leading edge until first spar. for _ in range(0, stringer_l_1): - index = bi.bisect_left(airfoil.x_l, x) - self.x_l.append(airfoil.x_l[index]) - self.z_l.append(airfoil.z_l[index]) + index = bi.bisect_left(airfoil.x, x) + self.x.append(airfoil.x[index]) + self.z.append(airfoil.z[index]) x += interval # Add lower stringers from first spar until last spar - interval = (airfoil.spar.x_l[-1] - - airfoil.spar.x_l[0]) / (stringer_l_2 + 1) - x = interval + airfoil.spar.x_l[0] + interval = (airfoil.spar.x[-1] + - airfoil.spar.x[0]) / (stringer_l_2 + 1) + x = interval + airfoil.spar.x[0] for _ in range(0, stringer_l_2): - index = bi.bisect_left(airfoil.x_l, x) - self.x_l.append(airfoil.x_l[index]) - self.z_l.append(airfoil.z_l[index]) + index = bi.bisect_left(airfoil.x, x) + self.x.append(airfoil.x[index]) + self.z.append(airfoil.z[index]) x += interval return None @@ -337,7 +334,7 @@ class Stringer(Coordinates): return None def add_mass(self, mass): - self.mass = len(self.x_u) * mass + len(self.x_l) * mass + self.mass = len(self.x) * mass + len(self.x) * mass return None def info_print(self, round): @@ -361,34 +358,34 @@ def plot_geom(airfoil): '-.', color='r', linewidth='2', label='Mean camber line') # Plot upper surface - plt.plot(airfoil.x_u, airfoil.z_u, + plt.plot(airfoil.x, airfoil.z, '', color='b', linewidth='1') # Plot lower surface - plt.plot(airfoil.x_l, airfoil.z_l, + plt.plot(airfoil.x, airfoil.z, '', color='b', linewidth='1') # Plot spars - for _ in range(0, len(airfoil.spar.x_u)): - x = (airfoil.spar.x_u[_], airfoil.spar.x_l[_]) - y = (airfoil.spar.z_u[_], airfoil.spar.z_l[_]) + for _ in range(0, len(airfoil.spar.x)): + x = (airfoil.spar.x[_], airfoil.spar.x[_]) + y = (airfoil.spar.z[_], airfoil.spar.z[_]) plt.plot(x, y, '.-', color='b') # Plot upper stringers - for _ in range(0, len(airfoil.stringer.x_u)): - x = airfoil.stringer.x_u[_] - y = airfoil.stringer.z_u[_] + for _ in range(0, len(airfoil.stringer.x)): + x = airfoil.stringer.x[_] + y = airfoil.stringer.z[_] plt.plot(x, y, '.', color='y', markersize=12) # Plot lower stringers - for _ in range(0, len(airfoil.stringer.x_l)): - x = airfoil.stringer.x_l[_] - y = airfoil.stringer.z_l[_] + for _ in range(0, len(airfoil.stringer.x)): + x = airfoil.stringer.x[_] + y = airfoil.stringer.z[_] plt.plot(x, y, '.', color='y', markersize=12) # Graph formatting plt.xlabel('X axis') plt.ylabel('Z axis') - plot_bound = airfoil.x_u[-1] + plot_bound = airfoil.x[-1] plt.xlim(- 0.10 * plot_bound, 1.10 * plot_bound) plt.ylim(- (1.10 * plot_bound / 2), (1.10 * plot_bound / 2)) plt.gca().set_aspect('equal', adjustable='box') diff --git a/evaluator.py b/evaluator.py index 5710522..801c5ae 100644 --- a/evaluator.py +++ b/evaluator.py @@ -39,11 +39,11 @@ class Evaluator: + airfoil.stringer.mass) self.mass_dist = [] # Upper coordinates - self.x_u = airfoil.x_u - self.z_u = airfoil.z_u + self.x = airfoil.x + self.z = airfoil.z # Lower coordinates - self.x_l = airfoil.x_l - self.z_l = airfoil.z_l + self.x = airfoil.x + self.z = airfoil.z self.lift_rectangular = [] self.lift_elliptical = [] self.lift_total = [] @@ -140,15 +140,15 @@ class Evaluator: stringer_area = self.stringer.area caps_area = self.spar.cap_area - x_spars = self.spar.x_u + self.spar.x_l - x_stringers = self.stringer.x_u + self.stringer.x_l - z_stringers = self.stringer.z_u + self.stringer.z_l + x_spars = self.spar.x + self.spar.x + x_stringers = self.stringer.x + self.stringer.x + z_stringers = self.stringer.z + self.stringer.z denom = float(len(x_spars) * caps_area + len(x_stringers) * stringer_area) - x_ctr = (sum([i * caps_area for i in self.spar.x_u]) + x_ctr = (sum([i * caps_area for i in self.spar.x]) + sum([i * stringer_area for i in x_stringers])) / denom - z_ctr = (sum([i * caps_area for i in self.spar.z_u]) + z_ctr = (sum([i * caps_area for i in self.spar.z]) + sum([i * stringer_area for i in z_stringers])) / denom return(x_ctr, z_ctr) @@ -159,12 +159,12 @@ class Evaluator: caps_area = self.spar.cap_area # Adds upper and lower components' coordinates to list - x_stringers = self.stringer.x_u + self.stringer.x_l - z_stringers = self.stringer.z_u + self.stringer.z_l - x_spars = self.spar.x_u + self.spar.x_l - z_spars = self.spar.z_u + self.spar.z_l + x_stringers = self.stringer.x + self.stringer.x + z_stringers = self.stringer.z + self.stringer.z + x_spars = self.spar.x + self.spar.x + z_spars = self.spar.z + self.spar.z stringer_count = range(len(x_stringers)) - spar_count = range(len(self.spar.x_u)) + spar_count = range(len(self.spar.x)) # I_x is the sum of the contributions of the spar caps and stringers I_x = (sum([caps_area * (z_spars[i] - self.centroid[1]) ** 2 @@ -212,27 +212,27 @@ def plot_geom(evaluator): q = evaluator.chord / 4 plt.plot(q, 0, '.', color='g', markersize=24, label='Quarter-chord') # Plot upper surface - plt.plot(evaluator.x_u, evaluator.z_u, + plt.plot(evaluator.x, evaluator.z, '', color='b', linewidth='1') # Plot lower surface - plt.plot(evaluator.x_l, evaluator.z_l, + plt.plot(evaluator.x, evaluator.z, '', color='b', linewidth='1') # Plot spars - for _ in range(0, len(evaluator.spar.x_u)): - x = (evaluator.spar.x_u[_], evaluator.spar.x_l[_]) - y = (evaluator.spar.z_u[_], evaluator.spar.z_l[_]) + for _ in range(0, len(evaluator.spar.x)): + x = (evaluator.spar.x[_], evaluator.spar.x[_]) + y = (evaluator.spar.z[_], evaluator.spar.z[_]) plt.plot(x, y, '.-', color='b') # Plot upper stringers - for _ in range(0, len(evaluator.stringer.x_u)): - x = evaluator.stringer.x_u[_] - y = evaluator.stringer.z_u[_] + for _ in range(0, len(evaluator.stringer.x)): + x = evaluator.stringer.x[_] + y = evaluator.stringer.z[_] plt.plot(x, y, '.', color='y', markersize=12) # Plot lower stringers - for _ in range(0, len(evaluator.stringer.x_l)): - x = evaluator.stringer.x_l[_] - y = evaluator.stringer.z_l[_] + for _ in range(0, len(evaluator.stringer.x)): + x = evaluator.stringer.x[_] + y = evaluator.stringer.z[_] plt.plot(x, y, '.', color='y', markersize=12) # Plot centroid @@ -244,7 +244,7 @@ def plot_geom(evaluator): plt.xlabel('X axis') plt.ylabel('Z axis') - plot_bound = evaluator.x_u[-1] + plot_bound = evaluator.x[-1] plt.xlim(- 0.10 * plot_bound, 1.10 * plot_bound) plt.ylim(- (1.10 * plot_bound / 2), (1.10 * plot_bound / 2)) plt.gca().set_aspect('equal', adjustable='box') |