Beauty#
Tails, Surviving, Overcoming#
Note
He was the ultimate ally in life, art, and politics - Emma Thompson of Alan Rickman
1. Life: Said/Heard-Own Fault
\
2. Thought-Ignorance -> 4. Transposed: Art-Image -> 5. Science-Love -> 6. Morality-Repent
/
3. Done-Weakness
Show code cell source
import networkx as nx
import matplotlib.pyplot as plt
import numpy as np
# Create a directed graph
G = nx.DiGraph()
# Add nodes representing different levels (subatomic, atomic, cosmic, financial, social)
levels = ['i: Obama', 'ii7♭5: Trump', 'V7: Clinton']
# Add nodes to the graph
G.add_nodes_from(levels)
# Add edges to represent the flow of information (photons)
# Assuming the flow is directional from more fundamental levels to more complex ones
edges = [('ii7♭5: Trump', 'V7: Clinton'),
('V7: Clinton', 'i: Obama'),]
# Add edges to the graph
G.add_edges_from(edges)
# Define positions for the nodes in a circular layout
pos = nx.circular_layout(G)
# Set the figure size (width, height)
plt.figure(figsize=(10, 10)) # Adjust the size as needed
# Draw the main nodes
nx.draw_networkx_nodes(G, pos, node_color='lightblue', node_size=30000)
# Draw the edges with arrows and create space between the arrowhead and the node
nx.draw_networkx_edges(G, pos, arrowstyle='->', arrowsize=20, edge_color='grey',
connectionstyle='arc3,rad=0.2') # Adjust rad for more/less space
# Add smaller red nodes (photon nodes) exactly on the circular layout
for edge in edges:
# Calculate the vector between the two nodes
vector = pos[edge[1]] - pos[edge[0]]
# Calculate the midpoint
mid_point = pos[edge[0]] + 0.5 * vector
# Normalize to ensure it's on the circle
radius = np.linalg.norm(pos[edge[0]])
mid_point_on_circle = mid_point / np.linalg.norm(mid_point) * radius
# Draw the small red photon node at the midpoint on the circular layout
plt.scatter(mid_point_on_circle[0], mid_point_on_circle[1], c='lightpink', s=500, zorder=3)
# Draw a small lime green arrow inside the red node to indicate direction
arrow_vector = vector / np.linalg.norm(vector) * 0.1 # Scale down arrow size
plt.arrow(mid_point_on_circle[0] - 0.05 * arrow_vector[0],
mid_point_on_circle[1] - 0.05 * arrow_vector[1],
arrow_vector[0], arrow_vector[1],
head_width=0.03, head_length=0.05, fc='limegreen', ec='limegreen', zorder=4)
# Draw the labels for the main nodes
nx.draw_networkx_labels(G, pos, font_size=18, font_weight='normal')
# Add a legend for "Photon/Info"
plt.scatter([], [], c='lightpink', s=100, label='Chord Progression') # Empty scatter for the legend
plt.legend(scatterpoints=1, frameon=True, labelspacing=1, loc='upper right')
# Set the title and display the plot
plt.title('Emotional Arc', fontsize=15)
plt.axis('off')
plt.show()
1. Nodes
\
2. Edges -> 4. Nodes -> 5. Edges -> 6. Scale
/
3. Scale
ii
\(\mu\) Single Note#
ii
\(f(t)\) Phonetics: 29 30Fractals
\(440Hz \times 2^{\frac{N}{12}}\), \(S_0(t) \times e^{logHR}\), \(\frac{S N(d_1)}{K N(d_2)} \times e^{rT}\)
Show code cell source
import numpy as np
import matplotlib.pyplot as plt
# Parameters
sample_rate = 44100 # Hz
duration = 20.0 # seconds
A4_freq = 440.0 # Hz
# Time array
t = np.linspace(0, duration, int(sample_rate * duration), endpoint=False)
# Fundamental frequency (A4)
signal = np.sin(2 * np.pi * A4_freq * t)
# Adding overtones (harmonics)
harmonics = [2, 3, 4, 5, 6, 7, 8, 9] # First few harmonics
amplitudes = [0.5, 0.25, 0.15, 0.1, 0.05, 0.03, 0.01, 0.005] # Amplitudes for each harmonic
for i, harmonic in enumerate(harmonics):
signal += amplitudes[i] * np.sin(2 * np.pi * A4_freq * harmonic * t)
# Perform FFT (Fast Fourier Transform)
N = len(signal)
yf = np.fft.fft(signal)
xf = np.fft.fftfreq(N, 1 / sample_rate)
# Modify the x-axis to represent a timeline from biblical times to today
timeline_labels = ['2000 BC', '1000 BC', 'Birth of Jesus', 'St. Paul', 'Middle Ages', 'Renaissance', 'Modern Era']
timeline_positions = np.linspace(0, 2024, len(timeline_labels)) # positions corresponding to labels
# Down-sample the y-axis data to match the length of timeline_positions
yf_sampled = 2.0 / N * np.abs(yf[:N // 2])
yf_downsampled = np.interp(timeline_positions, np.linspace(0, 2024, len(yf_sampled)), yf_sampled)
# Plot the frequency spectrum with modified x-axis
plt.figure(figsize=(12, 6))
plt.plot(timeline_positions, yf_downsampled, color='navy', lw=1.5)
# Aesthetics improvements
plt.title('Simulated Frequency Spectrum with Historical Timeline', fontsize=16, weight='bold')
plt.xlabel('Historical Timeline', fontsize=14)
plt.ylabel('Reverence', fontsize=14)
plt.xticks(timeline_positions, labels=timeline_labels, fontsize=12)
plt.ylim(0, None)
# Shading the period from Birth of Jesus to St. Paul
plt.axvspan(timeline_positions[2], timeline_positions[3], color='lightpink', alpha=0.5)
# Annotate the shaded region
plt.annotate('Birth of Jesus to St. Paul',
xy=(timeline_positions[2], 0.7), xycoords='data',
xytext=(timeline_positions[3] + 200, 0.5), textcoords='data',
arrowprops=dict(facecolor='black', arrowstyle="->"),
fontsize=12, color='black')
# Remove top and right spines
plt.gca().spines['top'].set_visible(False)
plt.gca().spines['right'].set_visible(False)
# Customize ticks
plt.xticks(timeline_positions, labels=timeline_labels, fontsize=12)
plt.yticks(fontsize=12)
# Light grid
plt.grid(color='grey', linestyle=':', linewidth=0.5)
# Show the plot
plt.tight_layout()
plt.show()
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V7
\(S(t)\) Temperament: \(440Hz \times 2^{\frac{N}{12}}\)i
\(h(t)\) Scales: 12 unique notes x 7 modes (Bach covers only x 2 modes in WTK)Soulja Boy has an incomplete Phrygian in PBS
Flamenco Phyrgian scale is equivalent to a Mixolydian
V9♭♯9♭13
V7
\(\sigma\) Chord Stacks#
\((X'X)^T \cdot X'Y\): Mode: \( \mathcal{F}(t) = \alpha \cdot \left( \prod_{i=1}^{n} \frac{\partial \psi_i(t)}{\partial t} \right) + \beta \cdot \int_{0}^{t} \left( \sum_{j=1}^{m} \frac{\partial \phi_j(\tau)}{\partial \tau} \right) d\tau\)
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import matplotlib.pyplot as plt
import numpy as np
# Clock settings; f(t) random disturbances making "paradise lost"
clock_face_radius = 1.0
number_of_ticks = 7
tick_labels = [
"Root-iADL (i)",
"Hunter-gather (ii7♭5)", "Peasant (III)", "Farmer (iv)", "Manufacturer (V7♭9♯9♭13)",
"Energy (VI)", "Transport (VII)"
]
# Calculate the angles for each tick (in radians)
angles = np.linspace(0, 2 * np.pi, number_of_ticks, endpoint=False)
# Inverting the order to make it counterclockwise
angles = angles[::-1]
# Create figure and axis
fig, ax = plt.subplots(figsize=(8, 8))
ax.set_xlim(-1.2, 1.2)
ax.set_ylim(-1.2, 1.2)
ax.set_aspect('equal')
# Draw the clock face
clock_face = plt.Circle((0, 0), clock_face_radius, color='lightgrey', fill=True)
ax.add_patch(clock_face)
# Draw the ticks and labels
for angle, label in zip(angles, tick_labels):
x = clock_face_radius * np.cos(angle)
y = clock_face_radius * np.sin(angle)
# Draw the tick
ax.plot([0, x], [0, y], color='black')
# Positioning the labels slightly outside the clock face
label_x = 1.1 * clock_face_radius * np.cos(angle)
label_y = 1.1 * clock_face_radius * np.sin(angle)
# Adjusting label alignment based on its position
ha = 'center'
va = 'center'
if np.cos(angle) > 0:
ha = 'left'
elif np.cos(angle) < 0:
ha = 'right'
if np.sin(angle) > 0:
va = 'bottom'
elif np.sin(angle) < 0:
va = 'top'
ax.text(label_x, label_y, label, horizontalalignment=ha, verticalalignment=va, fontsize=10)
# Remove axes
ax.axis('off')
# Show the plot
plt.show()
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i
\(\%\) Predict NexToken#
\(\alpha, \beta, t\) NexToken: Attention, to the minor, major, dom7, and half-dim7 groupings, is all you need 31
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import matplotlib.pyplot as plt
import numpy as np
# Clock settings; f(t) random disturbances making "paradise lost"
clock_face_radius = 1.0
number_of_ticks = 9
tick_labels = [
"Sun-Genomics", "Chlorophyll-Transcriptomics", "Flora-Proteomics", "Animals-Metabolomics",
"Wood-Epigenomics", "Coal-Lipidomics", "Hydrocarbons-Glycomics", "Renewable-Metagenomics", "Nuclear-Phenomics"
]
# Calculate the angles for each tick (in radians)
angles = np.linspace(0, 2 * np.pi, number_of_ticks, endpoint=False)
# Inverting the order to make it counterclockwise
angles = angles[::-1]
# Create figure and axis
fig, ax = plt.subplots(figsize=(8, 8))
ax.set_xlim(-1.2, 1.2)
ax.set_ylim(-1.2, 1.2)
ax.set_aspect('equal')
# Draw the clock face
clock_face = plt.Circle((0, 0), clock_face_radius, color='lightgrey', fill=True)
ax.add_patch(clock_face)
# Draw the ticks and labels
for angle, label in zip(angles, tick_labels):
x = clock_face_radius * np.cos(angle)
y = clock_face_radius * np.sin(angle)
# Draw the tick
ax.plot([0, x], [0, y], color='black')
# Positioning the labels slightly outside the clock face
label_x = 1.1 * clock_face_radius * np.cos(angle)
label_y = 1.1 * clock_face_radius * np.sin(angle)
# Adjusting label alignment based on its position
ha = 'center'
va = 'center'
if np.cos(angle) > 0:
ha = 'left'
elif np.cos(angle) < 0:
ha = 'right'
if np.sin(angle) > 0:
va = 'bottom'
elif np.sin(angle) < 0:
va = 'top'
ax.text(label_x, label_y, label, horizontalalignment=ha, verticalalignment=va, fontsize=10)
# Remove axes
ax.axis('off')
# Show the plot
plt.show()
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\(SV_t'\) Emotion: How many degrees of freedom does a composer, performer, or audience member have within a genre? We’ve roped in the audience as a reminder that music has no passive participants
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import numpy as np
import matplotlib.pyplot as plt
# Define the total utility function U(Q)
def total_utility(Q):
return 100 * np.log(Q + 1) # Logarithmic utility function for illustration
# Define the marginal utility function MU(Q)
def marginal_utility(Q):
return 100 / (Q + 1) # Derivative of the total utility function
# Generate data
Q = np.linspace(1, 100, 500) # Quantity range from 1 to 100
U = total_utility(Q)
MU = marginal_utility(Q)
# Plotting
plt.figure(figsize=(14, 7))
# Plot Total Utility
plt.subplot(1, 2, 1)
plt.plot(Q, U, label=r'Total Utility $U(Q) = 100 \log(Q + 1)$', color='blue')
plt.title('Total Utility')
plt.xlabel('Quantity (Q)')
plt.ylabel('Total Utility (U)')
plt.legend()
plt.grid(True)
# Plot Marginal Utility
plt.subplot(1, 2, 2)
plt.plot(Q, MU, label=r'Marginal Utility $MU(Q) = \frac{dU(Q)}{dQ} = \frac{100}{Q + 1}$', color='red')
plt.title('Marginal Utility')
plt.xlabel('Quantity (Q)')
plt.ylabel('Marginal Utility (MU)')
plt.legend()
plt.grid(True)
# Adding some calculus notation and Greek symbols
plt.figtext(0.5, 0.02, r"$MU(Q) = \frac{dU(Q)}{dQ} = \lim_{\Delta Q \to 0} \frac{U(Q + \Delta Q) - U(Q)}{\Delta Q}$", ha="center", fontsize=12)
plt.tight_layout()
plt.show()
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Show code cell source
import matplotlib.pyplot as plt
import numpy as np
from matplotlib.cm import ScalarMappable
from matplotlib.colors import LinearSegmentedColormap, PowerNorm
def gaussian(x, mean, std_dev, amplitude=1):
return amplitude * np.exp(-0.9 * ((x - mean) / std_dev) ** 2)
def overlay_gaussian_on_line(ax, start, end, std_dev):
x_line = np.linspace(start[0], end[0], 100)
y_line = np.linspace(start[1], end[1], 100)
mean = np.mean(x_line)
y = gaussian(x_line, mean, std_dev, amplitude=std_dev)
ax.plot(x_line + y / np.sqrt(2), y_line + y / np.sqrt(2), color='red', linewidth=2.5)
fig, ax = plt.subplots(figsize=(10, 10))
intervals = np.linspace(0, 100, 11)
custom_means = np.linspace(1, 23, 10)
custom_stds = np.linspace(.5, 10, 10)
# Change to 'viridis' colormap to get gradations like the older plot
cmap = plt.get_cmap('viridis')
norm = plt.Normalize(custom_stds.min(), custom_stds.max())
sm = ScalarMappable(cmap=cmap, norm=norm)
sm.set_array([])
median_points = []
for i in range(10):
xi, xf = intervals[i], intervals[i+1]
x_center, y_center = (xi + xf) / 2 - 20, 100 - (xi + xf) / 2 - 20
x_curve = np.linspace(custom_means[i] - 3 * custom_stds[i], custom_means[i] + 3 * custom_stds[i], 200)
y_curve = gaussian(x_curve, custom_means[i], custom_stds[i], amplitude=15)
x_gauss = x_center + x_curve / np.sqrt(2)
y_gauss = y_center + y_curve / np.sqrt(2) + x_curve / np.sqrt(2)
ax.plot(x_gauss, y_gauss, color=cmap(norm(custom_stds[i])), linewidth=2.5)
median_points.append((x_center + custom_means[i] / np.sqrt(2), y_center + custom_means[i] / np.sqrt(2)))
median_points = np.array(median_points)
ax.plot(median_points[:, 0], median_points[:, 1], '--', color='grey')
start_point = median_points[0, :]
end_point = median_points[-1, :]
overlay_gaussian_on_line(ax, start_point, end_point, 24)
ax.grid(True, linestyle='--', linewidth=0.5, color='grey')
ax.set_xlim(-30, 111)
ax.set_ylim(-20, 87)
# Create a new ScalarMappable with a reversed colormap just for the colorbar
cmap_reversed = plt.get_cmap('viridis').reversed()
sm_reversed = ScalarMappable(cmap=cmap_reversed, norm=norm)
sm_reversed.set_array([])
# Existing code for creating the colorbar
cbar = fig.colorbar(sm_reversed, ax=ax, shrink=1, aspect=90)
# Specify the tick positions you want to set
custom_tick_positions = [0.5, 5, 8, 10] # example positions, you can change these
cbar.set_ticks(custom_tick_positions)
# Specify custom labels for those tick positions
custom_tick_labels = ['5', '3', '1', '0'] # example labels, you can change these
cbar.set_ticklabels(custom_tick_labels)
# Label for the colorbar
cbar.set_label(r'♭', rotation=0, labelpad=15, fontstyle='italic', fontsize=24)
# Label for the colorbar
cbar.set_label(r'♭', rotation=0, labelpad=15, fontstyle='italic', fontsize=24)
cbar.set_label(r'♭', rotation=0, labelpad=15, fontstyle='italic', fontsize=24)
# Add X and Y axis labels with custom font styles
ax.set_xlabel(r'Principal Component', fontstyle='italic')
ax.set_ylabel(r'Emotional State', rotation=0, fontstyle='italic', labelpad=15)
# Add musical modes as X-axis tick labels
# musical_modes = ["Ionian", "Dorian", "Phrygian", "Lydian", "Mixolydian", "Aeolian", "Locrian"]
greek_letters = ['α', 'β','γ', 'δ', 'ε', 'ζ', 'η'] # 'θ' , 'ι', 'κ'
mode_positions = np.linspace(ax.get_xlim()[0], ax.get_xlim()[1], len(greek_letters))
ax.set_xticks(mode_positions)
ax.set_xticklabels(greek_letters, rotation=0)
# Add moods as Y-axis tick labels
moods = ["flow", "control", "relaxed", "bored", "apathy","worry", "anxiety", "arousal"]
mood_positions = np.linspace(ax.get_ylim()[0], ax.get_ylim()[1], len(moods))
ax.set_yticks(mood_positions)
ax.set_yticklabels(moods)
# ... (rest of the code unchanged)
plt.tight_layout()
plt.show()
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1. f(t)
\
2. S(t) -> 4. Nxb:t(X'X).X'Y -> 5. b -> 6. df
/
3. h(t)
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import pandas as pd
# Data for the table
data = {
"Thinker": [
"Heraclitus", "Plato", "Aristotle", "Augustine", "Thomas Aquinas",
"Machiavelli", "Descartes", "Spinoza", "Leibniz", "Hume",
"Kant", "Hegel", "Nietzsche", "Marx", "Freud",
"Jung", "Schumpeter", "Foucault", "Derrida", "Deleuze"
],
"Epoch": [
"Ancient", "Ancient", "Ancient", "Late Antiquity", "Medieval",
"Renaissance", "Early Modern", "Early Modern", "Early Modern", "Enlightenment",
"Enlightenment", "19th Century", "19th Century", "19th Century", "Late 19th Century",
"Early 20th Century", "Early 20th Century", "Late 20th Century", "Late 20th Century", "Late 20th Century"
],
"Lineage": [
"Implicit", "Socratic lineage", "Builds on Plato",
"Christian synthesis", "Christianizes Aristotle",
"Acknowledges predecessors", "Breaks tradition", "Synthesis of traditions", "Cartesian", "Empiricist roots",
"Hume influence", "Dialectic evolution", "Heraclitus influence",
"Hegelian critique", "Original psychoanalysis",
"Freudian divergence", "Marxist roots", "Nietzsche, Marx",
"Deconstruction", "Nietzsche, Spinoza"
]
}
# Create DataFrame
df = pd.DataFrame(data)
# Display DataFrame
print(df)
Show code cell output
Thinker Epoch Lineage
0 Heraclitus Ancient Implicit
1 Plato Ancient Socratic lineage
2 Aristotle Ancient Builds on Plato
3 Augustine Late Antiquity Christian synthesis
4 Thomas Aquinas Medieval Christianizes Aristotle
5 Machiavelli Renaissance Acknowledges predecessors
6 Descartes Early Modern Breaks tradition
7 Spinoza Early Modern Synthesis of traditions
8 Leibniz Early Modern Cartesian
9 Hume Enlightenment Empiricist roots
10 Kant Enlightenment Hume influence
11 Hegel 19th Century Dialectic evolution
12 Nietzsche 19th Century Heraclitus influence
13 Marx 19th Century Hegelian critique
14 Freud Late 19th Century Original psychoanalysis
15 Jung Early 20th Century Freudian divergence
16 Schumpeter Early 20th Century Marxist roots
17 Foucault Late 20th Century Nietzsche, Marx
18 Derrida Late 20th Century Deconstruction
19 Deleuze Late 20th Century Nietzsche, Spinoza
Show code cell source
import networkx as nx
import matplotlib.pyplot as plt
def add_family_edges(G, parent, depth, names, scale=1):
if depth == 0 or not names:
return parent
# Adding children based on depth and given names
children = names.pop(0)
for child in children:
G.add_edge(parent, child)
# Recursive call to add descendants of the current child
add_family_edges(G, child, depth - 1, names, scale * 0.7)
def create_extended_fractal_tree():
G = nx.Graph()
# Start with the initial node 'God'
root = "God"
G.add_node(root)
# Add 'Adam' as a child of 'God'
adam = "Adam"
G.add_edge(root, adam)
# Define a list of tuples with children nodes for each patriarch and modern figures
descendants = [
["Noah", "Shem"], # Children of Adam
["Abraham", "Ham"], # Children of Noah or Shem (adding Ham as Noah's second child)
["Isaac", "Jacob"], # Children of Abraham
["Judah", "Joseph"], # Children of Jacob
["Ilya Sutskever", "Sergey Brin"], # Modern "children" from Judah as missing links
["OpenAI", "AlexNet"], # AI organizations stemming from Ilya Sutskever
["GPT", "AGI"], # Further developments in AI
["Google Brain", "Transformer"], # AI developments stemming from Sergey Brin
["Elon Musk/Cyborg"], # Elon Musk as a child of AlexNet
["Tesla", "SpaceX", "Boring Company", "Neuralink", "X", "xAI"] # Elon Musk's companies as children of Elon Musk
]
# Generate edges recursively
add_family_edges(G, adam, len(descendants), descendants)
# Manually add dashed edges to indicate "missing links"
G.add_edge("Judah", "Ilya Sutskever") # Adding conceptual missing link
G.add_edge("Judah", "Sergey Brin") # Adding conceptual missing link
G.add_edge("AlexNet", "Elon Musk/Cyborg") # Elon Musk as a child of AlexNet
for company in ["Tesla", "SpaceX", "Boring Company", "Neuralink", "X", "xAI"]:
G.add_edge("Elon Musk/Cyborg", company) # Elon Musk's companies
# Adding Sergey Brin's children
G.add_edge("Sergey Brin", "Google Brain")
G.add_edge("Sergey Brin", "Transformer")
return G
# Generate the extended fractal tree with Musk and Brin's additions
extended_tree_graph = create_extended_fractal_tree()
# Visualization
plt.figure(figsize=(12, 10))
pos = nx.spring_layout(extended_tree_graph, seed=42)
# Define color maps for nodes
color_map = []
for node in extended_tree_graph.nodes():
if node == "God":
color_map.append("lightblue") # Color for God
elif node in ["OpenAI", "AlexNet", "GPT", "AGI", "Google Brain", "Transformer"]:
color_map.append("lightgreen") # Color for AI entities
elif node == "Elon Musk/Cyborg" or node in ["Tesla", "SpaceX", "Boring Company", "Neuralink", "X", "xAI"]:
color_map.append("yellow") # Color for Elon Musk and his companies
else:
color_map.append("lightpink") # Color for human figures
# Draw all solid edges first
solid_edges = [edge for edge in extended_tree_graph.edges() if edge not in [("Judah", "Ilya Sutskever"), ("Judah", "Sergey Brin")]]
nx.draw(extended_tree_graph, pos, edgelist=solid_edges, with_labels=True, node_size=1000, node_color=color_map, font_size=10, font_weight="bold", edge_color="grey", width=2)
# Identify the "missing link" edges
missing_link_edges = [("Judah", "Ilya Sutskever"), ("Judah", "Sergey Brin")]
# Draw the missing link edges as dashed lines
nx.draw_networkx_edges(
extended_tree_graph,
pos,
edgelist=missing_link_edges,
style="dashed",
edge_color="lightgray", # Set to light yellow for a good contrast
width=2
)
plt.axis('off')
plt.show()
Show code cell output
South Sudanese models are overrepresented in the world of fashion for several compelling reasons, each contributing to their prominence in the industry:
Unique Aesthetic Appeal: South Sudanese models often possess a striking and distinctive aesthetic that aligns with the fashion world’s demand for unique and memorable looks. Their features—such as tall, slender frames, high cheekbones, and deep skin tones—fit the high-fashion criteria for runway and editorial work. These qualities stand out in a crowd, creating a powerful visual impact on the runway and in fashion photography.
Resilience and Determination: Many South Sudanese models come from challenging backgrounds, including refugee camps and war-torn regions. Their journeys to success often reflect a remarkable level of resilience and determination, traits that are highly valued in the competitive fashion industry. This determination is not just about survival but also about thriving and breaking barriers, which resonates well in an industry constantly searching for compelling stories and personalities.
Diversity and Inclusivity Trends: The fashion industry has increasingly embraced diversity and inclusivity, seeking to reflect a broader range of beauty standards and cultural backgrounds. South Sudanese models bring diversity to the catwalk and fashion campaigns, which aligns with the industry’s evolving ethos. Fashion brands and designers, eager to appeal to a global audience, see the inclusion of South Sudanese models as a way to showcase their commitment to these values.
Role Models and Mentorship: The success of pioneers like Alek Wek has paved the way for other South Sudanese models. Wek’s impact on the industry demonstrated that South Sudanese beauty could command global attention, inspiring a new generation of models from her homeland. Her success has created a ripple effect, encouraging agencies to scout for similar talents and fostering a sense of community and mentorship among South Sudanese models who support each other in navigating the industry.
Strong Scouting Networks: There has been an active effort by international modeling agencies to scout talents from South Sudan. Due to the unique qualities and untapped potential of models from this region, agencies have set up scouting networks and collaborations with local organizations to discover new talents. This systematic approach ensures a steady influx of South Sudanese models into the international fashion scene.
Fashion as a Platform for Advocacy: Many South Sudanese models use their platforms to advocate for important causes, such as refugee rights, education, and social justice. This advocacy work makes them appealing not just as models but also as influencers and spokespeople. Fashion houses, magazines, and brands often align with such models to boost their own social impact narratives, further amplifying the visibility of South Sudanese talent.
Their overrepresentation is not just about meeting a trend or a quota; it’s about the fashion industry’s recognition of their beauty, strength, and the unique narratives they bring to the runway. The combination of these factors creates a compelling presence that resonates both visually and culturally, cementing their place in fashion’s elite circles.