StarDrive
Introduction
StarDrive technology represents a revolutionary advancement in space travel, enabling ships to navigate through a parallel dimension called drivespace. Unlike traditional propulsion systems, the StarDrive creates a controlled singularity that transports the ship from normal space into drivespace. This innovation has significantly altered the way we explore and navigate the universe.
Drivespace Submergence Whenever a ship engages its StarDrive, it enters drivespace, which is a distinct dimension closely linked to our universe. Each drivespace submergence lasts precisely 30 Cycle , roughly equivalent to 2.5 rotation . During this period, the ship is effectively cut off from normal space, rendering it unable to maneuver or be affected by external forces until it reaches its destination.
Power Source The key component to activate a StarDrive is a mass reactor. No other power system can generate the energy required for this technology. Mass reactors harness the energy released when dark matter undergoes decay into normal matter, producing a vast amount of power needed to engage the StarDrive.
Navigation and Plotting Careful navigation and plotting are essential for a ship equipped with a StarDrive. Once a ship enters drivespace, it loses its ability to change course or maneuver. Therefore, precise calculations and trajectory planning are necessary to ensure the ship reaches its intended destination without any complications or deviations.
Distance and Ship Class The distance a ship can travel in a single jump using the StarDrive is primarily determined by its class. The following table provides a base guideline for each ship class:
Small: 5 light-years Light: 10 light-years Medium: 20 light-years Heavy: 30 light-years Super-heavy (S-heavy): 50 light-years These distances are achieved during a single jump and serve as the foundation for StarDrive technology.
Energy Requirements Activating a StarDrive consumes a significant amount of power. Specifically, it requires 5 percent of the ship's hull and 3 power points for each hull point of the system. For example, a ship with 80 hull points necessitates a 4-hull point StarDrive and 12 power points to initiate starfall.
It's possible to extend the distances beyond the base values by allocating additional power. For every 10 power points allocated beyond the minimum requirement, the ship can extend its starfall distance by one light-year. For instance, a battleship with 1,000 hull points initially requires 150 power points for its StarDrive. However, if 300 power points are allocated, it can now starfall up to 45 light-years instead of the standard 30 light-years.
Recharging After completing a drivespace journey, the StarDrive system requires several days to recharge for the next starfall. Typically, it takes around 15 Cycle for the system to replenish its energy and be ready for the next interstellar jump.
In summary, StarDrive technology has revolutionized space travel by allowing ships to navigate through a parallel dimension and cover vast distances. Its usage is contingent on precise calculations, the availability of a mass reactor, and power allocation. The potential for extended travel distances provides flexibility and adaptability in exploring the cosmos. However, the need for recharging after each journey ensures responsible and strategic use of this groundbreaking technology.
Drivespace Submergence Whenever a ship engages its StarDrive, it enters drivespace, which is a distinct dimension closely linked to our universe. Each drivespace submergence lasts precisely 30 Cycle , roughly equivalent to 2.5 rotation . During this period, the ship is effectively cut off from normal space, rendering it unable to maneuver or be affected by external forces until it reaches its destination.
Power Source The key component to activate a StarDrive is a mass reactor. No other power system can generate the energy required for this technology. Mass reactors harness the energy released when dark matter undergoes decay into normal matter, producing a vast amount of power needed to engage the StarDrive.
Navigation and Plotting Careful navigation and plotting are essential for a ship equipped with a StarDrive. Once a ship enters drivespace, it loses its ability to change course or maneuver. Therefore, precise calculations and trajectory planning are necessary to ensure the ship reaches its intended destination without any complications or deviations.
Distance and Ship Class The distance a ship can travel in a single jump using the StarDrive is primarily determined by its class. The following table provides a base guideline for each ship class:
Small: 5 light-years Light: 10 light-years Medium: 20 light-years Heavy: 30 light-years Super-heavy (S-heavy): 50 light-years These distances are achieved during a single jump and serve as the foundation for StarDrive technology.
Energy Requirements Activating a StarDrive consumes a significant amount of power. Specifically, it requires 5 percent of the ship's hull and 3 power points for each hull point of the system. For example, a ship with 80 hull points necessitates a 4-hull point StarDrive and 12 power points to initiate starfall.
It's possible to extend the distances beyond the base values by allocating additional power. For every 10 power points allocated beyond the minimum requirement, the ship can extend its starfall distance by one light-year. For instance, a battleship with 1,000 hull points initially requires 150 power points for its StarDrive. However, if 300 power points are allocated, it can now starfall up to 45 light-years instead of the standard 30 light-years.
Recharging After completing a drivespace journey, the StarDrive system requires several days to recharge for the next starfall. Typically, it takes around 15 Cycle for the system to replenish its energy and be ready for the next interstellar jump.
In summary, StarDrive technology has revolutionized space travel by allowing ships to navigate through a parallel dimension and cover vast distances. Its usage is contingent on precise calculations, the availability of a mass reactor, and power allocation. The potential for extended travel distances provides flexibility and adaptability in exploring the cosmos. However, the need for recharging after each journey ensures responsible and strategic use of this groundbreaking technology.
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