CBE30338
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Index of Python Libraries used in this Repository
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argparse
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B.2.5.2 B.) Tracker.py
-Tracker.py)
av
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
CBE30338
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A.1.2
CBE30338.plotter()
`)
control
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3.4.2 Initializations
4.12.2 Notebook Initialization
5.1.2 Library Usage
5.2.2 Block Diagram for Car Cruise Control
5.3.1 Initializations
5.5 Baroreflex as a Linear Control System
cv2
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
B.2.5.2 B.) Tracker.py
-Tracker.py)
datetime
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
google
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7.6.1 Required Installations
imutils
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B.2.5.2 B.) Tracker.py
-Tracker.py)
ipywidgets
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5.4.3.1 Interactive Tuning of a PID Controller
math
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1.2.2.4 Importing in Python: Math and plotting
matplotlib
¶
1.1.4.5 Plotting with Matplotlib
1.2.2.4 Importing in Python: Math and plotting
1.3.4 Numpy - "The Fundamental Package for Scientific Computing with Python"
1.4.2.4.1 Step 1: Initialization
2.2.4.1 Step 1. Initialize Jupyter and Python
2.3.2.1 Step 1. Initialize Python Workspace
2.4.3.1 Step 1. Imports
2.5.5.1 Step 1. Initialization
2.6.2 Reaction Kinetics
2.7.2 Python Implementation
2.8 Model Library
3.1.3 Nonlinear Step Response
3.2.3.5 Example: Gravity Drained Tank
3.4.2 Initializations
3.5.5.1 Step 1. Initialization
3.6.1.1 Overdamped ($\zeta > 1$)
)
3.6.2 Simulation
3.6.4.2 Starting with a Step Response
3.7.2.2 Part b.
3.8.3 Initializations
3.9.2.4 Simulation
3.9.2.5 How many people will be infected following an outbreak?
3.9.3 Model 2. SEIR model
3.9.4 Model 3. Mitigation and Social Distancing
3.9.5 Model 4. Improving the fidelity of the model.
4.6.1 Empirical Methods
4.6.2.2 Tuning Rules
4.11.1 Model
4.11.6.1 Contents of PIDsim.py
4.12.2 Notebook Initialization
5.1.2 Library Usage
5.2.2 Block Diagram for Car Cruise Control
5.3.1 Initializations
5.4.2.1 Entering Process Transfer Functions
5.5 Baroreflex as a Linear Control System
6.1.2 Continuous Stirred Tank Reactor
6.1.3 Analytical Solution using Calculus
6.1.5 [Bonus Discussion] Batch Reactor
6.7.2 Denatured Alcohol
7.1.1 Installations and Initialization
7.2.2 Python Initializations
7.3 Simulation in Pyomo
7.4.2 Imports
7.5.1 First-Order Differential Equation with Initial Condition
7.6.5 Visualizing Car Path
7.7.2 Preliminary Code
7.8 Path Constraints
7.8.1 Recoding for Compact Style
7.8.2 Subscripting Equations
8.1.2 Demonstration
9.1.4.2 State Inventories
9.1.4.5 Gannt Chart
9.3.4 Visualization
9.3.5 Multiple Machines
A.1.1.1.1 Functions are Python objects
A.1.1.1.1 Functions are Python objects
A.1.1.1.2 Create simple functions with
lambda
A.1.1.1.2 Create simple functions with
lambda
A.1.1.1.2 Create simple functions with
lambda
A.2.1.1 Typical Usage
A.3.3.1 Step 1. Create the background frame.
A.3.4 Example: Phase Plane Animation for an Exothermic Stirred-Tank Reactor
B.1.3.1 Import Libraries
numpy
¶
1.1.4.2 Python Libraries
1.1.4.5 Plotting with Matplotlib
1.3.4 Numpy - "The Fundamental Package for Scientific Computing with Python"
1.4.2.4.1 Step 1: Initialization
2.2.4.1 Step 1. Initialize Jupyter and Python
2.3.2.1 Step 1. Initialize Python Workspace
2.4.3.1 Step 1. Imports
2.5.5.1 Step 1. Initialization
2.6.2 Reaction Kinetics
2.7.2 Python Implementation
2.8 Model Library
3.1.3 Nonlinear Step Response
3.2.3.5 Example: Gravity Drained Tank
3.4.2 Initializations
3.5.5.1 Step 1. Initialization
3.6.1.1 Overdamped ($\zeta > 1$)
)
3.6.2 Simulation
3.6.4.2 Starting with a Step Response
3.7.2.2 Part b.
3.8.3 Initializations
3.9.2.4 Simulation
3.9.2.5 How many people will be infected following an outbreak?
3.9.3 Model 2. SEIR model
3.9.4 Model 3. Mitigation and Social Distancing
3.9.5 Model 4. Improving the fidelity of the model.
4.5.1 Example: PID Control with Significant Measurement Noise
4.5.3 Example Revisited
4.6.1 Empirical Methods
4.6.2.2 Tuning Rules
4.11.1 Model
4.11.6.1 Contents of PIDsim.py
4.12.2 Notebook Initialization
5.1.2 Library Usage
5.2.2 Block Diagram for Car Cruise Control
5.3.1 Initializations
5.4.2.1 Entering Process Transfer Functions
5.5 Baroreflex as a Linear Control System
6.1.2 Continuous Stirred Tank Reactor
6.1.3 Analytical Solution using Calculus
6.1.5 [Bonus Discussion] Batch Reactor
6.4.5.1 Data in Matrix/Vector Format
6.7.2 Denatured Alcohol
6.99.2 Example 19.3: Linear Programming Refinery
7.2.2 Python Initializations
7.4.2 Imports
7.6.5 Visualizing Car Path
7.7.2 Preliminary Code
7.8 Path Constraints
7.8.1 Recoding for Compact Style
7.8.2 Subscripting Equations
8.1.1 Interpolation Function
8.1.2 Demonstration
9.1.3.4 Pyomo Model
A.1.1.1.1 Functions are Python objects
A.1.1.1.1 Functions are Python objects
A.1.1.1.2 Create simple functions with
lambda
A.1.1.1.2 Create simple functions with
lambda
A.1.1.1.2 Create simple functions with
lambda
A.1.1.1.3 Create complex functions with
def
A.1.2
CBE30338.plotter()
`)
A.2.1.1 Typical Usage
A.3.3.1 Step 1. Create the background frame.
A.3.4 Example: Phase Plane Animation for an Exothermic Stirred-Tank Reactor
B.1.3.1 Import Libraries
B.2.5.1 A.) TelloCV.py
-TelloCV.py)
os
¶
6.8 Gasoline Blending
B.2.5.1 A.) TelloCV.py
-TelloCV.py)
pandas
¶
2.5.3 Historical Data
6.7.5 Display Composition
6.8 Gasoline Blending
6.99.2 Example 19.3: Linear Programming Refinery
9.1.4.2 State Inventories
9.3.1 Example
9.3.1 Example
9.3.3 Pyomo Model
9.3.5 Multiple Machines
pyomo
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6.6.1.1.5 Pyomo Model
6.7.4 Optimization Model
6.8 Gasoline Blending
6.8.3 Blending Model
seaborn
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4.11.1 Model
5.1.2 Library Usage
5.2.2 Block Diagram for Car Cruise Control
5.5 Baroreflex as a Linear Control System
7.6.5 Visualizing Car Path
A.3.3.1 Step 1. Create the background frame.
A.3.4 Example: Phase Plane Animation for an Exothermic Stirred-Tank Reactor
shutil
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6.8 Gasoline Blending
7.4.2 Imports
sympy
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1.1.4.6 Solve Equations using Sympy Library
sys
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6.8 Gasoline Blending
tellopy
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
threading
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
time
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B.2.5.1 A.) TelloCV.py
-TelloCV.py)
B.2.5.2 B.) Tracker.py
-Tracker.py)
warnings
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5.3.1 Initializations
5.5 Baroreflex as a Linear Control System