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import random
import pandas as pd
import streamlit as st
import pydeck as pdk
from datetime import datetime, timedelta
# ---- Constants ----
POLES_PER_SITE = 12
SITES = {
"Hyderabad": [17.385044, 78.486671],
"Gadwal": [16.2351, 77.8052],
"Kurnool": [15.8281, 78.0373],
"Ballari": [12.9716, 77.5946]
}
# ---- Helper Functions ----
def generate_location(base_lat, base_lon):
return [
base_lat + random.uniform(-0.02, 0.02),
base_lon + random.uniform(-0.02, 0.02)
]
def simulate_pole(pole_id, site_name):
lat, lon = generate_location(*SITES[site_name])
solar_kwh = round(random.uniform(3.0, 7.5), 2)
wind_kwh = round(random.uniform(0.5, 2.0), 2)
power_required = round(random.uniform(4.0, 8.0), 2)
total_power = solar_kwh + wind_kwh
power_status = 'Sufficient' if total_power >= power_required else 'Insufficient'
tilt_angle = round(random.uniform(0, 45), 2)
vibration = round(random.uniform(0, 5), 2)
camera_status = random.choice(['Online', 'Offline'])
alert_level = 'Green'
anomaly_details = []
if tilt_angle > 30 or vibration > 3:
alert_level = 'Yellow'
anomaly_details.append("Tilt or Vibration threshold exceeded.")
if tilt_angle > 40 or vibration > 4.5:
alert_level = 'Red'
anomaly_details.append("Critical tilt or vibration detected.")
health_score = max(0, 100 - (tilt_angle + vibration * 10))
timestamp = datetime.now() - timedelta(hours=random.randint(0, 6))
return {
'Pole ID': f'{site_name[:3].upper()}-{pole_id:03}',
'Site': Site__c,
'Latitude': Location_Latitude__c,
'Longitude': Location_Longitude__c,
'Solar (kWh)': solar_kwh,
'Wind (kWh)': wind_kwh,
'Power Required (kWh)': Power_Required__c,
'Total Power (kWh)': total_power,
'Power Status': power_status,
'Tilt Angle (Β°)': tilt_angle,
'Vibration (g)': vibration,
'Camera Status': Camera_Status__c,
'Health Score': Health_Score__c,
'Alert Level': Alert_Level__c,
'Anomalies': "; ".join(anomaly_details),
'Last Checked': timestamp.strftime('%Y-%m-%d %H:%M:%S')
}
# ---- Streamlit UI ----
st.set_page_config(page_title="Smart Pole Monitoring", layout="wide")
st.title("π Smart Renewable Pole Monitoring - Multi-Site")
selected_site = st.text_input("Enter site to view (Hyderabad, Gadwal, Kurnool, Ballari):", "Hyderabad")
if selected_site in SITES:
SITES = ['Kurnool', 'Hyderabad', 'Ballari', 'Gadwal']
POLES_PER_SITE = 4
def simulate_pole(pole_id, site):
return {
'Id': f'P{pole_id}_{site[:3].upper()}',
'Site': site,
'Energy': round(100 + pole_id * 5.5, 2),
'Status': 'OK'
}
with st.spinner(f"Simulating poles at {selected_site}..."):
poles_data = [simulate_pole(i + 1, site) for site in SITES for i in range(POLES_PER_SITE)]
df = pd.DataFrame(poles_data)
site_df = df[df['Site'] == selected_site]
with st.spinner(f"Simulating poles at {selected_site}..."):
import time
time.sleep(2)
col1, col2, col3 = st.columns(3)
col1.metric("Total Poles", site_df.shape[0])
col2.metric("Red Alerts", site_df[site_df['Alert Level'] == 'Red'].shape[0])
col3.metric("Power Insufficiencies", site_df[site_df['Power Status'] == 'Insufficient'].shape[0])
# Table View
st.subheader(f"π Pole Data Table for {selected_site}")
with st.expander("Filter Options"):
alert_filter = st.multiselect("Alert Level", options=site_df['Alert Level'].unique(), default=site_df['Alert Level'].unique())
camera_filter = st.multiselect("Camera Status", options=site_df['Camera Status'].unique(), default=site_df['Camera Status'].unique())
filtered_df = site_df[(site_df['Alert Level'].isin(alert_filter)) & (site_df['Camera Status'].isin(camera_filter))]
st.dataframe(filtered_df, use_container_width=True)
# Charts
st.subheader("π Energy Generation Comparison")
st.bar_chart(site_df[['Solar (kWh)', 'Wind (kWh)']].mean())
st.subheader("π Tilt vs. Vibration")
st.scatter_chart(site_df[['Tilt Angle (Β°)', 'Vibration (g)']])
# Map with Red Alerts
st.subheader("π Red Alert Pole Locations")
red_df = site_df[site_df['Alert Level'] == 'Red']
if not red_df.empty:
st.pydeck_chart(pdk.Deck(
initial_view_state=pdk.ViewState(
latitude=SITES[selected_site][0],
longitude=SITES[selected_site][1],
zoom=12,
pitch=50
),
layers=[
pdk.Layer(
'ScatterplotLayer',
data=red_df,
get_position='[Longitude, Latitude]',
get_color='[255, 0, 0, 160]',
get_radius=100,
)
]
))
st.markdown("<h3 style='text-align: center;'>Red Alert Poles are Blinking</h3>", unsafe_allow_html=True)
else:
st.info("No red alerts at this time.")
if selected_site == "Kurnool":
st.write("Simulating for Kurnool")
else:
st.write("Simulating for another site")
st.warning("Invalid site. Please enter one of: Hyderabad, Gadwal, Kurnool, Ballari")
import streamlit as st
from salesforce_integration import fetch_salesforce_data
from utils import process_data # Optional, if you need data processing
# Fetch data from Salesforce
poles_data = fetch_salesforce_data()
# Process the data (optional, based on your model needs)
processed_data = process_data(poles_data)
# Display the processed data in Streamlit
st.title("Poles Data Visualization")
st.write("Processed Poles Data", processed_data)
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