Perpetual Bloom
Perpetual Bloom
Perpetual Bloom
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
Eth-no-Maths
The project involved developing a computational model that can visualise perfect celestial systems with circular orbits
The simulated systems would be rendered visually to create aesthetic and informative representations. These visualizations would allow for a deeper understanding of the system's dynamics and structure.
The project involved developing a computational model that can visualise perfect celestial systems with circular orbits
The simulated systems would be rendered visually to create aesthetic and informative representations. These visualizations would allow for a deeper understanding of the system's dynamics and structure.
The project involved developing a computational model that can visualise perfect celestial systems with circular orbits
The simulated systems would be rendered visually to create aesthetic and informative representations. These visualizations would allow for a deeper understanding of the system's dynamics and structure.
The project involved developing a computational model that can visualise perfect celestial systems with circular orbits
The simulated systems would be rendered visually to create aesthetic and informative representations. These visualizations would allow for a deeper understanding of the system's dynamics and structure.
The project involved developing a computational model that can visualise perfect celestial systems with circular orbits
The simulated systems would be rendered visually to create aesthetic and informative representations. These visualizations would allow for a deeper understanding of the system's dynamics and structure.









Selected Patterns
Selected Patterns
Selected Patterns
Selected Patterns
Selected Patterns
Selected Patterns
Selected Patterns
The Visualisations were created with different numbers of bodies, creating unique and interesting patterns here are some of the results.
Ranging from a single celestial body to 10.
(Not to scale)
The Visualisations were created with different numbers of bodies, creating unique and interesting patterns here are some of the results.
Ranging from a single celestial body to 10.
(Not to scale)
The Visualisations were created with different numbers of bodies, creating unique and interesting patterns here are some of the results.
Ranging from a single celestial body to 10.
(Not to scale)
The Visualisations were created with different numbers of bodies, creating unique and interesting patterns here are some of the results.
Ranging from a single celestial body to 10.
(Not to scale)

















































































Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.
Inspired by humanity's celestial fascination, this project models and visualizes hypothetical celestial systems featuring perfectly circular orbits. By increasing the number of moons, we investigate the impact on orbital stability and overall system dynamics, offering a glimpse into how these systems might appear from afar.