Assignments WS 2023/2024

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Kopd05 - Simulace šíření pandemie

  • Cílem simulace bude zkoupání šíření různých virů, podle jejich koeficientu šíření, uzdravování či úmrtnosti.
  • Simulaci mohou využívat epidemiologové, ke zkoumání šířitelnosti virů a predikci vývoje pandemie.
  • Simulace bude vypracována pomoci NetLogo - Agent based modelu
  • V simulaci budou následující proměnné:
    • Rychlost šíření viru
    • Šance na uzdravení jedince
    • Riziko smrti
    • Počet jedinců
    • Počet nakažených
    • % imunních jedinců (náhodná)
    • Rychlost vakcinace
    • jeImunní
    • jeNakažený
    • jeOčkovaný
    • šanceNaUzdravení (náhodná)
  • Data mohou být založena na reálných datech o virech, či mohou být nastaveny individuálně.
    Například šiřitelnost virusu bude založena na reprodukčním čísle R (lze dohledat na internetu)
  • Vše bude založeno na volně dostupných datech online, které souvisí s daným tématem, virem, apod.

Kopd05 (talk) 21:02, 12 December 2023 (CET)

This course is in English. We accept English versions only. Tomáš (talk)

Tutd00 - Aquatic ecosystem simulation

  • The simulation is inspired by the classic "predator and prey" model. The goal is to model the behavior of fish, plants and predators in the generated aquatic environment.
  • The simulation will be developed using the NetLogo - Agent based model
  • The following variables will be in the simulation:
    • The water temperature
    • Pollution level
    • Number of fish
    • Number of sharks
    • Number of plants
    • Time of death of fish and shark (random)
    • Fish and shark breeding time (random, but only after feeding)
    • and also variables that depend on the basic ones: number of dead fish and sharks, number of plants eaten
  • The user has the option to set the number of fish, plants, sharks, water temperature and pollution level when starting the simulation.
  • This simulation allows the user to investigate how different parameter configurations affect ecosystem stability and dynamics and could be modified and used to model real aquatic systems.
  • The rules: Cold water temperatures accelerate the rate of reproduction of predators, while warm water speeds up the rate of reproduction of fish.High water pollution slows down the reproduction of fish and sharks, but speeds up the growth of plants. The user can change settings during the simulation.
  • The data used in the simulation is based on real sources dedicated to the topic of aquatic systems (example: https://www.nalms.org/wp-content/uploads/2018/09/31-2-5.pdf), but will be implemented in a simplified form.

DariaTut (talk) 10:47, 18 December 2023 (CET)

This course is in English. We accept English versions only. Tomáš (talk) 19:58, 19 December 2023 (CET)
Edited DariaTut (talk) 20:27, 19 December 2023 (CET)

Kubs09 - Simulation of Passenger Behavior at the Main Train Station

  • Topic: Passenger behavior when boarding trains at the entire Main Train Station
  • Utilization: This could be utilized, for instance, by Czech Railways/main station administrators to better adjust trains and their arrival positions.
  • Method: Agent-based modelling, Netlogo
  • Variables:
    • Number of passengers
    • Number of trains
    • Passengers positions
    • Timetable (train departures/arrivals)
    • Delays (random)
    • isCollision
    • isDelay(random)
  • Sources: For this simulation, predominantly sources from Google Scholar would be used, or scientific articles found in the E-library of VSE.

Kubs09 (talk) 20:35, 19 December 2023 (CET)

This course is in English. We accept English versions only. Tomáš (talk) 19:58, 19 December 2023 (CET)
Edited.

Vysj06 - Simulation of Agricultural Production and Climate Change

  • Objective of the simulation: To model the impact of climate change on agricultural production, including soil fertility, crop yields, and irrigation.
  • Usage: To provide farmers, scientists, and policymakers with tools for better planning and adaptation to climate changes.
  • Method: Agent-based modeling, using NetLogo.
  • Variables:
    • Types of crops (grains, vegetables, fruits).
    • Soil conditions and their changes.
    • Amount and distribution of precipitation.
    • Temperature changes.
    • Irrigation methods and their efficiency.
  • Data: Based on real climate and agricultural data, including historical trends and forecasts. Option to configure parameters.
  • Output: The simulation will provide users with the ability to visualize and understand the impact of various climate scenarios on agricultural production and possible adaptation strategies.

Vysj06 (talk) 21:25, 19 December 2023 (CET)

This course is in English. We accept English versions only. Tomáš (talk) 19:59, 19 December 2023 (CET)

Edited

Doba00 - Pricing in the Food Industry

  • Simulation: The simulation will model the dynamics of food prices in the food industry, focusing on the interactions between different factors influencing it.
    • Can be used by policymakers in the food industry to better evaluate policy proposals.
    • Incorporated variables: production costs, inflation rates, consumer demand, policy interventions
    • Random variables: weather
  • Goal: The goal of the simulation is to analyze the factors influencing food prices and to evaluate the stability and resilience of the food industry's pricing system under different scenarios.
  • Method: Vensim
  • Author: Doba00 (talk) 16:25, 19 December 2023 (CET)
Please provide us with the reference to particular data, you wil base your simulation on. How exactly will your simulation work? How will you simulate the dynamics of food prices in the food industry? From what data you will derive the formulas neccesary for it? Oleg.Svatos (talk) 17:17, 19 December 2023 (CET)

Tata05 - Simulation of the Ocean Carbon Uptake and Atmospheric Carbon Dioxide

  • Problem definition: I want to simulate the process of the Life cycle of processing carbon dioxide from the atmosphere and increasing the stored carbon dioxide on the ocean floor. This process influences ocean acidification and affects the entire climate. The ocean absorbs carbon dioxide from the atmosphere wherever air meets water. Regarding scientists oceans absorb 30% of our emissions, driven by a huge carbon pump.
  • Method: Agent-based simulation, NetLogo.
  • Variabels:
    • Solar Energy
    • Atmospheric CO2
    • Changes in temperature
    • Change in water acidity
    • CO2 dissolving
    • Carbon capture and storage
  • Resource: Information from National Oceanic and Atmospheric Administration, Nasa Global Climate, https://www.soest.hawaii.edu/oceanography/faculty/zeebe_files/Publications/ZeebeWolfEnclp07.pdf

Tata05 (talk) 16:46, 19 December 2023 (CET)

Please provide us with the reference to literature with formulas you will base your simulation on. Without it, it is impossible to evaluate wheather the simulation will make sense. Oleg.Svatos (talk) 17:13, 19 December 2023 (CET)
Reference: https://www.soest.hawaii.edu/oceanography/faculty/zeebe_files/Publications/ZeebeWolfEnclp07.pdf
Edited Tata05 (Tata05) 21:49, 19 December 2023 (CET)

akee00== Urban Traffic flow and Pollution Control

  • Primary objective: To analyze the impact of different traffic management strategies on urban traffic flow and air pollution levels.
  • Problem to solve: Determining the most effective traffic management strategy that minimizes traffic congestion and reduces air pollution in an urban environment.
  • Context: With growing urban populations, traffic congestion and pollution have become critical issues. This simulation aims to explore how various traffic control measures can alleviate these problems.
  • Method and Simulation Environment:
    • Agent based Modelling
    • Simulation Tool: Netlogo.
  • Environment Setup: A simulated urban area with a grid of streets, traffic signals, vehicles, and pollution indicators.
  • Variables and Data:
  • Random variables:
    • Vehicle breakdowns,
    • Driver behaviour: route choice and speed variability
    • Traffic incidents
    • Weather conditions
    • Vehicle emission rates.
  • Incorporated (deterministic) variables:
    • Vehicle agents: count, types
    • Traffic signal agents: signal timing, adaptive signals
    • Pollution measurement: Baseline emission levels, Air quality index
    • Traffic Management Strategies
    • Road layout.
  • Data source:
    • Traffic and transportation data for Prague from praha.eu
  • Expected outcome: The simulation should reveal the most effective traffic management strategies for reducing congestion and pollution. By comparing these results with real-world data, urban planners can make informed decisions to improve traffic flow and air quality in cities.
This is generally a good topic, however the scope you suggest is really large and you would be hardly able to deliver results. Limit the model reasonably, e.g. choose just a limited area or limit the model different way. Tomáš (talk) 20:04, 19 December 2023 (CET)