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Chernobyl Disaster Optimizer || Step-By-Step || ~xRay Pixy

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Chernobyl Disaster Optimizer || Step-By-Step || ~xRay Pixy

Learn the Chernobyl disaster optimizer (CDO) Step-By-Step using Examples.
Video Chapters: Chernobyl Disaster Optimizer (CDO)
00:00 Introduction
02:05 Chernobyl Disaster Optimizer 
02:31 Topics Covered
02:05 Chernobyl Disaster || How Chernobyl Disaster Happened? 
05:40 3 Radiation Released after Chernobyl Disaster 
07:35 How CDO Simulates Chornobyl Nuclear Disaster
09:44 How particle attack models Mathematically
10:44 CDO Step-By-Step 
14:52 Conclusion

On April 26, 1986, Reactor 4 at the Chernobyl Nuclear Power Plant in Ukraine had a test while running at low power. Things went wrong, causing an explosion and a fire that destroyed the reactor. This accident released a huge amount of radiation into the air, affecting many people and the environment.

Key Isotopes Released in the Chernobyl Disaster:

  • Iodine-131: Short-lived but highly radioactive; primarily affects the thyroid gland.
  • Cesium-137: Long-lived; spreads widely and contaminates soil and water.
  • Strontium-90: Mimics calcium and accumulates in bones, posing long-term health risks.
  • Plutonium-239: Extremely toxic and long-lived, with a half-life of over 24,000 years.

Long-Term Consequences:

  • Health Effects: Thousands of cases of thyroid cancer, particularly in children, have been linked to the disaster due to radioactive iodine exposure.
  • Environmental Damage: The surrounding area, known as the Chernobyl Exclusion Zone, remains highly contaminated. It has become an unintended wildlife sanctuary.
  • Economic and Social Costs: The disaster led to billions of dollars in damages and had long-lasting political and social impacts, including growing criticism of the Soviet government.

Radiation Spread: The radioactive fallout spread over large parts of Europe, particularly affecting UkraineBelarus, and Russia. The disaster forced the evacuation and resettlement of more than 300,000 people.

  • Alpha Radiation: A slow-moving truck (16,000 km/s). It's strong but doesn't go very far or fast.
  • Beta Radiation: A sports car (270,000 km/s). It's faster but not the fastest.
  • Gamma Radiation: A jet plane (300,000 km/s). It's incredibly fast and can cover long distances quickly. 

    • The Chornobyl Disaster Optimizer (CDO) uses ideas inspired by nuclear radiation propagation (alpha, beta, and gamma particles).

    In CDO:
    • The human victim represents the best solution (analogous to the prey in GWO).
    • All particles (gamma, beta, alpha) adjust their positions iteratively to converge toward the victim's position in the search space.
    • The fitness function evaluates how "close" each particle is to the victim, guiding the optimization process.

    #optimization #algorithm #metaheuristic #robotics #deeplearning #ArtificialIntelligence #MachineLearning #computervision #research #projects #thesis #Python
    #optimizationproblem #optimizationalgorithms #chernobyldisaster #nucleardisaster

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