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| import pandas as pd | |
| import numpy as np | |
| import yfinance as yf | |
| import streamlit as st | |
| import plotly.graph_objects as go | |
| with open(r"style/style.css") as css: | |
| st.markdown(f"<style>{css.read()}</style>", unsafe_allow_html=True) | |
| st.markdown( | |
| "<h1 style='text-align: center;'><u>CapiPort</u></h1>", unsafe_allow_html=True | |
| ) | |
| st.markdown( | |
| "<h5 style='text-align: center; color: gray;'>Your Portfolio Optimisation Tool</h5>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.header( | |
| "", | |
| divider="rainbow", | |
| ) | |
| color = "Quest" | |
| st.markdown( | |
| "<h1 style='text-align: center;'>🔍 Quest for financial excellence begins with meticulous portfolio optimization</u></h1>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.header( | |
| "", | |
| divider="rainbow", | |
| ) | |
| list_df = pd.read_csv("Data/Company List.csv") | |
| company_name = list_df["Name"].to_list() | |
| company_symbol = (list_df["Ticker"] + ".NS").to_list() | |
| company_dict = dict() | |
| company_symbol_dict = dict() | |
| for CSymbol, CName in zip(company_symbol, company_name): | |
| company_dict[CName] = CSymbol | |
| for CSymbol, CName in zip(company_symbol, company_name): | |
| company_symbol_dict[CSymbol] = CName | |
| st.markdown( | |
| """ | |
| <style> | |
| .big-font { | |
| font-size:20px; | |
| } | |
| </style>""", | |
| unsafe_allow_html=True, | |
| ) | |
| st.markdown('<p class="big-font">Select Multiple Companies</p>', unsafe_allow_html=True) | |
| com_sel_name = st.multiselect("", company_name, default=None) | |
| com_sel = [company_dict[i] for i in com_sel_name] | |
| num_tick = len(com_sel) | |
| if num_tick > 1: | |
| com_data = yf.download(com_sel, start="1900-01-01", end="2024-03-08")["Adj Close"] | |
| for i in com_data.columns: | |
| com_data.dropna(axis=1, how='all', inplace=True) | |
| com_data.dropna(inplace=True) | |
| num_tick = len(com_data.columns) | |
| if num_tick > 1: | |
| com_sel_name_temp = [] | |
| for i in com_data.columns: | |
| com_sel_name_temp.append(company_symbol_dict[i]) | |
| com_sel = com_data.columns.to_list() | |
| com_sel_name.sort() | |
| st.dataframe(com_data, use_container_width=True) | |
| ## Log-Return of Company Dataset | |
| log_return = np.log(1 + com_data.pct_change()) | |
| ## Generate Random Weights | |
| rand_weig = np.array(np.random.random(num_tick)) | |
| ## Rebalancing Random Weights | |
| rebal_weig = rand_weig / np.sum(rand_weig) | |
| ## Calculate the Expected Returns, Annualize it by * 247.0 | |
| exp_ret = np.sum((log_return.mean() * rebal_weig) * 247) | |
| ## Calculate the Expected Volatility, Annualize it by * 247.0 | |
| exp_vol = np.sqrt(np.dot(rebal_weig.T, np.dot(log_return.cov() * 247, rebal_weig))) | |
| ## Calculate the Sharpe Ratio. | |
| sharpe_ratio = exp_ret / exp_vol | |
| # Put the weights into a data frame to see them better. | |
| weights_df = pd.DataFrame( | |
| data={ | |
| "company_name": com_sel_name_temp, | |
| "random_weights": rand_weig, | |
| "rebalance_weights": rebal_weig, | |
| } | |
| ) | |
| st.divider() | |
| st.markdown( | |
| "<h5 style='text-align: center;'>Random Portfolio Weights</h5>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.dataframe(weights_df, use_container_width=True) | |
| # Do the same with the other metrics. | |
| metrics_df = pd.DataFrame( | |
| data={ | |
| "Expected Portfolio Returns": exp_ret, | |
| "Expected Portfolio Volatility": exp_vol, | |
| "Portfolio Sharpe Ratio": sharpe_ratio, | |
| }, | |
| index=[0], | |
| ) | |
| st.markdown( | |
| "<h5 style='text-align: center;'>Random Weights Metrics</h5>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.dataframe(metrics_df, use_container_width=True) | |
| st.divider() | |
| ## Let's get started with Monte Carlo Simulations | |
| ## How many times should we run Monte Carlo | |
| num_of_port = 8000 | |
| ## Create an Array to store the weights as they are generated | |
| all_weights = np.zeros((num_of_port, num_tick)) | |
| ## Create an Array to store the returns as they are generated | |
| ret_arr = np.zeros(num_of_port) | |
| ## Create an Array to store the volatilities as they are generated | |
| vol_arr = np.zeros(num_of_port) | |
| ## Create an Array to store the Sharpe Ratios as they are generated | |
| sharpe_arr = np.zeros(num_of_port) | |
| ## Let's start the Monte Carlo Simulation | |
| for ind in range(num_of_port): | |
| ## Let's first Calculate the Weights | |
| weig = np.array(np.random.random(num_tick)) | |
| weig = weig / np.sum(weig) | |
| ## Append the Weights to Weigths array | |
| all_weights[ind, :] = weig | |
| ## Calculate and Append the Expected Log Returns to Returns Array | |
| ret_arr[ind] = np.sum((log_return.mean() * weig) * 247) | |
| ## Calculate and Append the Volatility to the Volatitlity Array | |
| vol_arr[ind] = np.sqrt(np.dot(weig.T, np.dot(log_return.cov() * 247, weig))) | |
| ## Calculate and Append the Sharpe Ratio to Sharpe Ratio Array | |
| sharpe_arr[ind] = ret_arr[ind] / vol_arr[ind] | |
| ## Let's create a Data Frame with Weights, Returns, Volatitlity, and the Sharpe Ratio | |
| sim_data = [ret_arr, vol_arr, sharpe_arr, all_weights] | |
| ## Create a Data Frame using above, then Transpose it | |
| sim_df = pd.DataFrame(data=sim_data).T | |
| ## Give the columns in Simulation Data Proper Names | |
| sim_df.columns = ["Returns", "Volatility", "Sharpe Ratio", "Portfolio Weights"] | |
| ## Make sure the Data Types are correct in the Data Frame | |
| sim_df = sim_df.infer_objects() | |
| # Print out the results. | |
| st.write("\n\n") | |
| st.markdown( | |
| "<h4 style='text-align: center;'>Simulation Results</h4>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.dataframe(sim_df.head(), use_container_width=True) | |
| # Return the Max Sharpe Ratio from the run. | |
| max_sharpe_ratio = sim_df.loc[sim_df["Sharpe Ratio"].idxmax()] | |
| # Return the Min Volatility from the run. | |
| min_volatility = sim_df.loc[sim_df["Volatility"].idxmin()] | |
| max_sharpe_weights_df = pd.DataFrame( | |
| data={ | |
| "company_name": com_sel_name_temp, | |
| "random_weights": max_sharpe_ratio["Portfolio Weights"], | |
| } | |
| ) | |
| st.markdown( | |
| "<h5 style='text-align: center;'>Portfolio with Max Sharpe Ratio</h5>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.dataframe(max_sharpe_ratio, use_container_width=True) | |
| st.dataframe(max_sharpe_weights_df, use_container_width=True) | |
| min_volatility_weights_df = pd.DataFrame( | |
| data={ | |
| "company_name": com_sel_name_temp, | |
| "random_weights": min_volatility["Portfolio Weights"], | |
| } | |
| ) | |
| st.markdown( | |
| "<h5 style='text-align: center;'>Portfolio with Min Volatility</h5>", | |
| unsafe_allow_html=True, | |
| ) | |
| st.dataframe(min_volatility, use_container_width=True) | |
| st.dataframe(min_volatility_weights_df, use_container_width=True) | |
| st.divider() | |
| st.markdown("<h1 style='text-align: center;'>Plotting</h1>", unsafe_allow_html=True) | |
| fig = go.Figure( | |
| data=go.Scatter( | |
| x=sim_df["Volatility"], | |
| y=sim_df["Returns"], | |
| mode="markers", | |
| marker=dict(color=sim_df["Sharpe Ratio"], colorscale="RdYlBu", size=10), | |
| ) | |
| ) | |
| # Add color bar | |
| fig.update_layout(coloraxis_colorbar=dict(title="Sharpe Ratio")) | |
| # Add title and axis labels | |
| fig.update_layout( | |
| title="Portfolio Returns Vs. Risk", | |
| xaxis=dict(title="Standard Deviation / Volatility"), | |
| yaxis=dict(title="Returns"), | |
| ) | |
| # Plot the Max Sharpe Ratio, using a `Red Star`. | |
| fig.add_trace( | |
| go.Scatter( | |
| x=[max_sharpe_ratio[1]], | |
| y=[max_sharpe_ratio[0]], | |
| mode="markers", | |
| marker=dict(color="red", symbol="star", size=20), | |
| name="Max Sharpe Ratio", | |
| ) | |
| ) | |
| # Plot the Min Volatility, using a `Blue Star`. | |
| fig.add_trace( | |
| go.Scatter( | |
| x=[min_volatility[1]], | |
| y=[min_volatility[0]], | |
| mode="markers", | |
| marker=dict(color="blue", symbol="star", size=20), | |
| name="Min Volatility", | |
| ) | |
| ) | |
| st.plotly_chart(fig, use_container_width=True) | |