Simulations
A simulation is the use of a computer software to represent the dynamic responses of one system by the behaviour of another system modeled after it. A simulation uses a mathematical descriptions, or models, of a real system in the form of a computer program.
College Board Essential Knowledge
Simulation are absractions of more complex objects or phenomena for a specific purpose
- Mimic Real World Events
- Allows investigation of phenomenons without contraints of the Real World
- Helps you draw accurate inferences
Simulations utilize varying sets of values to reflect the changings states of a phenomenon
- simulations can simplfly things for functionality
- Simulations can contain bias from real world elements, that were chosen to be included or excluded
Simulations work best when the real world experemnts are too impractical or time consuming. For example, simulating how different cars behave when they crash, would be much better than crashng actual cars in the real world, which would be expensive and dangerous.
Rolling the Dice
Simulating something like a dice roll in real life would require accounting for things like: weight, flaws in design, thrust, and gravity.
- KEEP IT SIMPLE! just use a random-number generator! Ignore minor causes of variablility
Random
- “Random” is a built-in python function that allow the user to draw a random value from a set range.
- A Random Number Generator (RNG) is a common simulation that selects a random value from an array.
- The following code cell utilizes “random” to select a number from 1 to 100.
#imports random module so we can use it in our code
import random
#sets variable random_number as a random number between 1 and 100
random_number = random.randint(1, 100)
#Printing out your random Number
print(random_number)
More complex usage of “random”; Coin Toss Simulation
import random
def flip_coin():
return random.choice(["Heads", "Tails"])
def coin_flip_simulation(num_flips):
heads_count = 0
tails_count = 0
for _ in range(num_flips):
result = flip_coin()
if result == "Heads":
heads_count += 1
else:
tails_count += 1
return heads_count, tails_count
if __name__ == "__main__":
num_flips = 1000 #This is the number of coin flips you want to simulate
heads, tails = coin_flip_simulation(num_flips)
print("Number of Heads: "+ str(heads))
print("Number of Tails: " + str(tails))
print("Heads Probability: "+ str({heads / num_flips}))
print("Tails Probability: "+ str({tails / num_flips}))
Popcorn Hack #1
Utilize “random” to create a basic simulation of a rolling TWO dice. Print the sum of both dice rolls. Remember to practice good syntax when naming your variables.
import random
#Code, Code, Code
def roll_dice():
diceuno = random.choice([1, 2, 3, 4, 5, 6])
dicedos = random.choice([1, 2, 3, 4, 5, 6])
return diceuno + dicedos
if __name__ == '__main__':
for i in range(5):
add = roll_dice()
print(add)
5
9
11
4
6
Algorithms
Simulations often utilize algorithms and equations to perform tasks because simulations don’t always have the same output
- the output of a simulation depends on the input
An algorithm is a finite sequence of instructions used to solve problems or perform computations.
- commonly used alongside functions
Example Algorithm in a function
#Defining Function
def algorithm(input):
#Manipulating input and preparing it for the output.
output = input+2
#Return the output
return output
#Call the Function to start the algorithm
algorithm(5)
7
Mathematics
- Math can also prove to be very useful in certain types of situations.
- Commonly used along with Algorithms when simulating various things
Popcorn Hack #2
Simulate how long an object will fall for using an algorithm, with user-inputed variables for height dropped. Use the following formula as a reference.
- t = time (output)
- h = height dropped from (input)
- g = constant (given)
# Constant, Acceleration due to gravity (m/s^2)
G = 9.81
from math import sqrt
def simulation(height_dropped):
time = sqrt((2*height_dropped)/G)
return time
if __name__ == '__main__':
height = int(input("How high will your object be dropped?"))
print(simulation(height))
1.0096375546923044
Using Loops in Simulations
For loops can also be used in simulations
- They can simulate events that repeat but don’t always have the same output
# Example For Loop
#Creating For Loop to repeat 4 times
for i in range(4):
#Action that happens inside for loop
print("This is run number: " + str(i))
This is run number: 0
This is run number: 1
This is run number: 2
This is run number: 3
Popcorn Hack #3
You are gambling addic.
Each session you roll 2 dice.
If your dice roll is greater than or equal to 9 you win the session.
If you win over 5 sessions, you win the jackpot.
Simulate your odds to predict if you will hit the jackpot (how many rounds did you win?) using a for loop and random.
# Code Code Code
import random
#Code, Code, Code
def roll_dice():
dice1 = random.choice([1, 2, 3, 4, 5, 6])
dice2 = random.choice([1, 2, 3, 4, 5, 6])
return dice1 + dice2
if __name__ == '__main__':
rounds = 10
wins = 0
for i in range(rounds):
dice_sum = roll_dice()
print(f"Roll {i + 1}: {dice_sum}")
if dice_sum >= 9:
wins += 1
print(f"You won {wins} rounds")
if wins >= 5:
print("victorious")
else:
print("GG")
Roll 1: 6
Roll 2: 3
Roll 3: 10
Roll 4: 5
Roll 5: 3
Roll 6: 9
Roll 7: 11
Roll 8: 5
Roll 9: 5
Roll 10: 5
You won 3 rounds
You lost! :(
BONUS POPCORN HACK
Welcome to Flight Simulator! Your goal is to complete a Python program that simulates a flight We’ve set up some initial values for altitude, speed, and fuel. Your task is to update these values to make the flight more realistic.
- Your mission:
- Use random changes to simulate altitude, speed, and fuel changes.
- Keep the flight going until it reaches 10,000 feet or runs out of fuel.
- Make sure altitude, speed, and fuel remain realistic.
# Code Code Code
QUIZ TIME
- Quick true or false quiz, whoever answers this correctly(raise your hand) gets a piece of gum or a dinero.
T or F
- A simulation will always have the same result. T or F
- A simulation investigates a phenomenom without real-world constraints of time, money, or safety. T or F
- A simulation has results which are more accurate than an experiment, T or F
- A simulation can model real-worl events that are not practical for experiments
HOMEWORK HACK #1
First finish Popcorn Hack #3. Expand the simulation to involve your own money.
starting money: $100
(Dice Roll <= 3) → lose $70
( 6> Dice Roll >3) → lose $40
( 9> Dice Roll >=6) → win $20
( Dice Roll>= 9 + Session Win) → win $50
Jackpot → win $100
# Code Code Code
import random
#Code, Code, Code
def roll_dice():
dice1 = random.choice([1, 2, 3, 4, 5, 6])
dice2 = random.choice([1, 2, 3, 4, 5, 6])
return dice1 + dice2
if __name__ == '__main__':
rounds = 10
wins = 0
money = 100
for i in range(rounds):
dice_sum = roll_dice()
if dice_sum >= 9:
wins += 1
money += 50
elif dice_sum >= 6:
money += 20
elif dice_sum > 3:
money -= 40
else:
money -= 70
print(f"You won {wins} rounds")
if wins >= 5:
print("You won the jackpot!!")
money += 100
amount_won = money - 100
if amount_won >= 0:
print(f"You won ${amount_won} in total!\nNew Balance: {money}")
else:
print(f"You lost ${amount_won * -1} in total :(\nNew Balance: {money}")
You won 3 rounds
You won $230 in total!
New Balance: 330
HOMEWORK HACK #2
Given initial parameters for a car simulation, including its initial speed, acceleration rate, deceleration rate, maximum speed, and initial distance, write a program to simulate the car’s journey and determine the final speed, distance covered, and time taken before it either covers 1000 meters or slows down to below 5 m/s?
# Initial parameters
speed = 5 # Initial speed
acceleration = 2 # Acceleration rate in m/s^2
deceleration = 1 # Deceleration rate in m/s^2
max_speed = 60 # Maximum speed in m/s
distance = 0 # Initial distance
time = 0 # Initial time
import random
while (distance < 1000) or (speed < 5):
acceleration = random.choice([0, 1, 2, 3, 4])
deceleration = random.choice([0, 1, 2, 3, 4])
if acceleration > deceleration:
speed += (acceleration - deceleration)
else:
speed -= (deceleration - acceleration)
if speed > max_speed:
speed = max_speed
distance += speed
time += 1
print(f"Final Speed: {speed}\nDistance Covered: {distance}")
Final Speed: 11
Distance Covered: 1007
Simulations are computer programs modeling real-world processes.
They are widely used across various domains.
Key concepts include state, time step, randomness, and simulation types.
Event-driven and time-driven simulations have distinct characteristics.
Building simulations involves creating code to replicate scenarios.
Parameters and sensitivity analysis allow for system behavior exploration.
Challenges include accuracy and ethical considerations.
Real-world applications span science, engineering, and gaming.
Case studies demonstrate how simulations are applied in practice.
Students can create their own simulations for hands-on learning.
General understanding and appreciation of simulations in coding are the primary goals.