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import streamlit as st
import pandas as pd
import plotly.graph_objects as go
import plotly.express as px
import numpy as np
from abc import ABC, abstractmethod
# Set the title of the app
st.title("Homer Simpson Meta-Learning with Hierarchical Reinforcement Learning Intrinsic Reward Lecture")
# Display the image with a caption
st.image("homer.webp", caption="Homer Simpson Meta-Learning HRL Lecture", use_column_width=True)
# Display and play the audio files
st.write("Audio Playback Meta-Learning with HRL Intrinsic Reward Lecture:")
st.audio("h0.wav", format="audio/wav")
st.audio("h1.wav", format="audio/wav")
st.write("Oh, sweet Homer's doughnuts! If that second .wav file ain't playin', just download the darn thing! Mmm... downloads...")
st.audio("h2.wav", format="audio/wav")
st.image("intrinsic_reward_formulation.png", caption='Intrinsic Reward Formulation')
st.write("Solving the first 5 equations @ (0,0):")
df_0_0 = pd.read_csv('df_0_0.csv')
st.write(df_0_0.shape)
st.write("Example 1 via Method 1:")
# Define parameters
eta = 0.1
N_st = 1
epsilon = 1e-5
# Intrinsic reward formulation
r_t_int = eta * (1 / (N_st + epsilon)**0.5)
# Display the formulation with parameters plugged in
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{1 + 1(10^{-5})}}
""")
st.write(f"Calculated intrinsic reward: {r_t_int}")
st.write(f"Calculated intrinsic reward rounded 2 decimal places:", np.round(r_t_int,2))
st.dataframe(df_0_0[:1])
# Display the formulation with parameters plugged in
st.write("Example 2 via Method 2:")
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{2 + 1(10^{-5})}}
""")
# Abstract Base Class for Intrinsic Reward Calculation
class IntrinsicRewardCalculator(ABC):
@abstractmethod
def calculate_intrinsic_reward(self, eta, count, epsilon):
pass
# Concrete Class for Intrinsic Reward Calculation
class ConcreteIntrinsicRewardCalculator(IntrinsicRewardCalculator):
def calculate_intrinsic_reward(self, eta, count, epsilon):
return eta * (1 / np.sqrt(count + epsilon))
def populate_df_0_0(self, df_0_0, eta, count, epsilon):
intrinsic_reward = self.calculate_intrinsic_reward(eta, count, epsilon)
df_0_0.at[0, 'Intrinsic Reward'] = intrinsic_reward
return df_0_0
# Example 2 parameters
eta = 0.1
count = 2
epsilon = 1e-5
x,y = 0,0
# Create instance for Intrinsic Reward Calculation
irc = ConcreteIntrinsicRewardCalculator()
intrinsic_reward = irc.calculate_intrinsic_reward(0.1, 2, 1e-5)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y}:", intrinsic_reward)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y} rounded 4 decimal places:", np.round(intrinsic_reward,4))
# Populate the DataFrame with the calculated intrinsic reward
df_0_0 = irc.populate_df_0_0(df_0_0, eta, count, epsilon)
# Display the updated DataFrame
st.dataframe(df_0_0[1:2])
st.write("Example 3 via Method 1:")
# Example 3 parameters
eta = 0.1
N_st = 3
epsilon = 1e-5
# Intrinsic reward formulation
r_t_int = eta * (1 / (N_st + epsilon)**0.5)
# Display the formulation with parameters plugged in
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{3 + 1(10^{-5})}}
""")
st.write(f"Calculated intrinsic reward: {r_t_int}")
st.write(f"Calculated intrinsic reward rounded 4 decimal places:", np.round(r_t_int,4))
st.dataframe(df_0_0[2:3])
# Display the formulation with parameters plugged in
st.write("Example 4 via Method 2:")
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{4 + 1(10^{-5})}}
""")
# Abstract Base Class for Intrinsic Reward Calculation
class IntrinsicRewardCalculator(ABC):
@abstractmethod
def calculate_intrinsic_reward(self, eta, count, epsilon):
pass
# Concrete Class for Intrinsic Reward Calculation
class ConcreteIntrinsicRewardCalculator(IntrinsicRewardCalculator):
def calculate_intrinsic_reward(self, eta, count, epsilon):
return eta * (1 / np.sqrt(count + epsilon))
def populate_df_0_0(self, df_0_0, eta, count, epsilon):
intrinsic_reward = self.calculate_intrinsic_reward(eta, count, epsilon)
df_0_0.at[0, 'Intrinsic Reward'] = intrinsic_reward
return df_0_0
# Example 4 parameters
eta = 0.1
count = 4
epsilon = 1e-5
x,y = 0,0
# Create instance for Intrinsic Reward Calculation
irc = ConcreteIntrinsicRewardCalculator()
intrinsic_reward = irc.calculate_intrinsic_reward(0.1, 4, 1e-5)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y}:", intrinsic_reward)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y} rounded 2 decimal places:", np.round(intrinsic_reward,2))
# Populate the DataFrame with the calculated intrinsic reward
df_0_0 = irc.populate_df_0_0(df_0_0, eta, count, epsilon)
# Display the updated DataFrame
st.dataframe(df_0_0[3:4])
st.write("Example 5 via Method 1:")
# Example 5 parameters
eta = 0.1
N_st = 5
epsilon = 1e-5
# Intrinsic reward formulation
r_t_int = eta * (1 / (N_st + epsilon)**0.5)
# Display the formulation with parameters plugged in
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{5 + 1(10^{-5})}}
""")
st.write(f"Calculated intrinsic reward: {r_t_int}")
st.write(f"Calculated intrinsic reward rounded 4 decimal places:", np.round(r_t_int,4))
st.dataframe(df_0_0[4:5])
st.audio("h3.wav", format="audio/wav")
st.write("Oh, sweet Krusty-licious! At coordinates (0,0) for that plotly visualization, we need a whopping 7036 intrinsic reward calculations to get things rollin'! And don't forget to update those State Visitations. Those were just the first five. Mmm... 7031 more to go... remember the oscillation starts at zero not 1 D'oh!")
# Display the formulation with parameters plugged in
st.write("Last Example 7035 via Method 2:")
st.latex(r"""
r_{t}^{int} \eta \frac{1}{\sqrt{N(s_{t}) + \epsilon}} = 0.1 \frac{1}{\sqrt{7035 + 1(10^{-5})}}
""")
# Abstract Base Class for Intrinsic Reward Calculation
class IntrinsicRewardCalculator(ABC):
@abstractmethod
def calculate_intrinsic_reward(self, eta, count, epsilon):
pass
# Concrete Class for Intrinsic Reward Calculation
class ConcreteIntrinsicRewardCalculator(IntrinsicRewardCalculator):
def calculate_intrinsic_reward(self, eta, count, epsilon):
return eta * (1 / np.sqrt(count + epsilon))
def populate_df_0_0(self, df_0_0, eta, count, epsilon):
intrinsic_reward = self.calculate_intrinsic_reward(eta, count, epsilon)
df_0_0.at[0, 'Intrinsic Reward'] = intrinsic_reward
return df_0_0
# Example 4 parameters
eta = 0.1
count = 7035
epsilon = 1e-5
x,y = 0,0
# Create instance for Intrinsic Reward Calculation
irc = ConcreteIntrinsicRewardCalculator()
intrinsic_reward = irc.calculate_intrinsic_reward(0.1, 7035, 1e-5)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y}:", intrinsic_reward)
st.write(f"Intrinsic Reward @ {count} @ Coordinates {x,y} rounded 4 decimal places:", np.round(intrinsic_reward,4))
# Populate the DataFrame with the calculated intrinsic reward
df_0_0 = irc.populate_df_0_0(df_0_0, eta, count, epsilon)
# Display the updated DataFrame
st.dataframe(df_0_0[7034:7035])
st.image("homer_formula_7035.webp", caption='Homer Meta-Learning HRL Formula 7035')
st.image("homer_formula_7035_2.webp", caption='Homer Meta-Learning HRL Formula 7035 2')
# Define the grid and visitations
grid = np.zeros((6, 6))
visitations = {
(0, 0): 7035, (1, 0): 3579, (2, 0): 1359, (2, 1): 1707, (3, 1): 520, (4, 1): 227,
(4, 2): 243, (5, 1): 217, (5, 2): 181, (5, 0): 241, (4, 0): 267, (5, 3): 179,
(4, 3): 1034, (3, 3): 2163, (2, 3): 2080, (0, 1): 3313, (1, 1): 3015, (0, 2): 1846,
(0, 3): 1104, (0, 4): 351, (1, 4): 518, (1, 3): 1497, (1, 2): 2236, (2, 2): 2239,
(2, 4): 842, (1, 5): 238, (2, 5): 217, (0, 5): 341, (3, 5): 382, (4, 5): 1872,
(4, 4): 2038, (3, 4): 1684, (3, 0): 383, (3, 2): 1102, (5, 4): 198
}
# Fill the grid with visitations
for (x, y), count in visitations.items():
grid[x, y] = count
# Calculate the total number of visitations
total_visitations = sum(visitations.values())
# Calculate the percentages
percentages = {state: (count / total_visitations) * 100 for state, count in visitations.items()}
# Print the percentages in the specified order
order = [
(0, 0), (0, 1), (0, 2), (0, 3), (0, 4), (0, 5),
(1, 0), (1, 1), (1, 2), (1, 3), (1, 4), (1, 5),
(2, 0), (2, 1), (2, 2), (2, 3), (2, 4), (2, 5),
(3, 0), (3, 1), (3, 2), (3, 3), (3, 4), (3, 5),
(4, 0), (4, 1), (4, 2), (4, 3), (4, 4), (4, 5),
(5, 0), (5, 1), (5, 2), (5, 3), (5, 4), (5, 5)
]
st.title("State Visitations Visualization")
st.write("### State Visitations Percentages:")
for state in order:
st.write(f"State {state}: {percentages.get(state, 0):.2f}%")
# Create a pie chart
labels = [f"State {state}" for state in visitations.keys()]
values = list(visitations.values())
fig_pie = go.Figure(data=[go.Pie(labels=labels, values=values)])
fig_pie.update_layout(title_text="State Visitations Pie Chart")
st.plotly_chart(fig_pie)
# Create a heatmap
fig_heatmap = px.imshow(grid, labels=dict(x="Column", y="Row", color="Visitations"),
x=list(range(6)), y=list(range(6)), title="State Visitations Heatmap")
fig_heatmap.update_xaxes(side="top")
st.plotly_chart(fig_heatmap)
# Load the CSV data
df = pd.read_csv('goal_rows.csv')
# Aggregate the data to count the number of visits to each State_2D
visitation_counts = df['State_2D'].value_counts().reset_index()
visitation_counts.columns = ['State_2D', 'Visitation_Count']
# Create the Plotly bar chart
fig = px.bar(visitation_counts, x='State_2D', y='Visitation_Count',
title='Goal Position Visitation Counts',
labels={'State_2D': 'State 2D', 'Visitation_Count': 'Visitation Count'})
# Display the plot using Streamlit
st.title('Goal Position Visitation Counts Visualization')
st.plotly_chart(fig)
# Aggregate the data to count the number of visits to each State_2D
visitation_counts = df['State_2D'].value_counts().reset_index()
visitation_counts.columns = ['State_2D', 'Visitation_Count']
# Clean the State_2D column to remove any extra characters or spaces
visitation_counts['State_2D'] = visitation_counts['State_2D'].str.replace(r'[^\d,]', '', regex=True)
# Split the cleaned State_2D into separate columns
visitation_counts[['x', 'y']] = visitation_counts['State_2D'].str.split(',', expand=True).astype(int)
# Create the Plotly heatmap
fig = px.density_heatmap(visitation_counts, x='x', y='y', z='Visitation_Count',
title='Goal Position Visitation Counts Heatmap',
labels={'x': 'X Coordinate', 'y': 'Y Coordinate', 'Visitation_Count': 'Visitation Count'})
# Display the heatmap using Streamlit
st.title('Goal Position Visitation Counts Heatmap Visualization')
st.plotly_chart(fig)
df = pd.read_csv('intrinsic_analysis.csv')
st.write("Intrinsic Analysis DataFrame:")
st.dataframe(df) |