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Summary
There are many types of stars and planets, each of which has their own advantage, and disadvantages in terms of gameplay value. This page is dedicated to categorize all astronomical objects and phenomena, and describe them.
When picking a star to construct a dyson sphere around, it's highly recommended to do it around a star with the highest luminosity (L☉), as many stars can have more than double (~2 L☉) if not triple (~3 L☉) the energy output than the starter system's star (~1 L☉), which is much less time consuming, and more effective than building one or even two additional dyson spheres orbiting neighboring stars.
Some rare veins and ores can only be found on certain types of planets, but on the other hand, it can also be impossible for those materials to naturally occur in other planets.
Types of planets
According to this reddit post, all terrestrial planets appear to follow the same grid layout:
5x20 (Including the pole, forms a 9 diameter disk around the pole)
5x40
5x80
5x100
10x160
10x200
15x300
15x400
25x500
25x600
50x800
80x1000
Equator (1x1000)
When building on a seam between the different bands, buildings will snap to the band closest to the equator.
| Name | Description | Image | Surface view |
|---|---|---|---|
| Mediterranean | Lush, tropical, and covered with oceans, they're abundant with basic resources. There is only one of these planet types in the cluster. It is the player's starter home planet. They're also a great source of crude oil. | ||
| Lava | Inhospitable, covered with lava lakes, they usually contain silicon ore and titanium ore. | ||
| Barren desert | Similar to the moon, its surface is covered with craters, since there's no atmosphere, wind turbines are useless, there are no oceans either, but it has the biggest construction area, and can be a decent source for soil piles. Veins of fire ice can be found around such planets. | ||
| Prairie | Similar to mediterranean planets, they're habitable lush oceanic planets, has less oceans, and more grasslands. They're also a good source of crude oil. Organic crystal veins can also be found there. | ||
| Gobi | Another planet fully devoid of any life or water, but does contain mountains, so they're a great source for soil piles. | ||
| Ashen gelisol | Similar to a Gobi desert planet, but this time a frozen one. Veins of fire ice can be found around such planets. | ||
| Volcanic ash | Similar to a lava planet, it's devoid of anything but volcanic activity, however, these planets are also a great source of sulfuric acid, and oceans of such are found around such planets. | ||
| Arid desert | Another desert planet, but compared to others, these planets are a great source for capturing wind energy. | ||
| Ice field gelisol | Planets covered with ice, and may have pockets of water scattered around the surface, veins of fire ice can be found around such planets. Since they're usually far away from their orbiting star, and have weak winds, they're terrible sources for renewable energy, the use of thermal power stations is recommended. | ||
| Oceanic jungle | Similar to Mediterranean and Prairie planets, they're lush planets, and they commonly contain sources of spiniform stalagmite crystals, crude oil, and organic crystals. | ||
| Ocean world | almost entirelly covered with oceans, it's very impractical to construct any infrastructure on it. It's another source of spiniform stalagmite crystals, but it's highly recommended you bring foundations and plenty of soil piles before you have anything to do with such planets. | ||
| Red stone | Similar to Mediterranean planets, but the soil is more reddish, and the surface is covered with mushrooms. | ||
| Gas Giant | Gas Giants are commonly found around the universe, and are a good source of Deuterium and Hydrogen by using Orbital Collectors. | ||
| Ice Giant | Ice giants are less commonly found around the universe, but are a good source of Fire Ice and Hydrogen by using Orbital Collectors. |
Stellar objects
| Class | Image | Description |
|---|---|---|
| Class M star |  |
The lowest mass stars are commonly referred to as Red Dwarf stars. They are the most abundant class of star, however, their luminosity is very low, making it very impractical to construct Dyson Spheres or even Dyson Swarms around them. |
| Class K star |  |
A low mass star, they typically have a luminosity of < 1 L☉, making them poor sites for construction of Dyson Spheres. Dyson Swarms may however still be of some use with their much lower resource requirements. |
| Class G star |  |
This is the class of star of which the Sun is a standard member. They typically have a luminosity of ~1 L☉. While they can make good use of Dyson Spheres and Dyson Swarms, higher luminosity stars may be a better location for Dyson Sphere construction.
The starting system is always around a class G star. |
| Class F star |  |
These stars have a higher luminosity while being of similar size to Class G stars. This makes them better sites for construction of Dyson Spheres, should no Class A or above stars be nearby. |
| Class A star |  |
This class have fairly high luminosity, while not being particularly large. This makes them good sites for construction of Dyson Spheres if materials are more limited, or there are no nearby Class B or O stars. |
| Class B star |  |
This class have a high luminosity, while not being as large as Class O. This makes them excellent sites for construction of Dyson Spheres if materials are more limited. |
| Class O star |  |
The brightest star type, ideal for constructing Dyson Spheres around them. However, they also tend to be the largest, and so require more materials to do so. |
| Giant star |  |
Can be of any spectral class that main sequence stars belong to. Giants are >10R⊙ and have higher luminosity than their main sequence counterparts. Depending on spectral class, they are referred to as Red, Yellow, White and Blue giants. |
| White Dwarf |  |
A stellar remnant following a nova, composed of electron-degenerate matter. Low luminosity makes them poor sites for construction of Dyson Spheres. Dyson Swarms may however still be of some use with their much lower resource requirements. |
| Neutron Star |  |
A stellar remnant following a supernova, composed of neutrons with a shell of electron-degenerate matter. Low luminosity makes them poor sites for construction of Dyson Spheres. Dyson Swarms may however still be of some use with their much lower resource requirements.
It is one of the rarest stars, only one will be generated in a cluster. Unipolar Magnets can only be found on host planets orbiting a Neuton Star or Black Hole. |
| Black Hole |  |
A massive stellar remnant following a supernova, it has collapsed behind an event horizon. Usually surrounded by an accretion disc. Their extremely low luminosity makes construction of Dyson Spheres or Dyson Swarms a vanity project, as they will produce little power.
It is one of the rarest stars, only one will be generated in a cluster. Unipolar Magnets can only be found on host planets orbiting a Neuton Star or Black Hole. |
Sources of rare veins
| Commonly found on habitable planets (mediterranean, oceanic jungle, red mushroom, and prairie planets). | |
| Commonly found on freezing planets (ice field gelisol and ice giants). Also occurs on ashen vgelisol and barren desert planets. | |
| Commonly found on habitable and oceanic planets (mediterranean, ocean world, oceanic jungle, red mushroom, and prairie planets). | |
| Commonly found on habitable and oceanic planets (mediterranean, oceanic jungle, red mushroom, prairie, and ocean world). | |
| Only found on volcanic ash planets. | |
| Commonly found on red mushroom planets. | |
| Commonly found on freezing planets (ashen gelisol and ice planets). | |
| Only found on planets orbiting neutron stars or black holes. | |
| Has been found on ice field gelisol, oceanic jungle, barren and lava planets. Commonly found on planets orbiting black holes, neutron stars and white dwarves. | |
| Only found on gas giants. |
State of stellar objects
Planets can have multiple physical attributes and states, which are listed below.
| Name | Description | Image |
|---|---|---|
| Tidal locking (TL) | Planets that has the same rotational period as orbital period, and consequently has one side permanently facing its host star or planet. Very useful to capture the host star's energy via solar panels and/or ray receivers | |
| Sattelite (SAT) | Astronomical objects that orbit another object that isn't a star, or in simpler terms, a moon. The starter planet is one example of such object. However, building EM-rail ejectors would be problematic, as the orbiting parent can block the sun, rendering them useless until the orbiting object passes, this decreases the time the EM-rail ejectors can fire sails, and decreases their effeciency. | |
| Reverse Rotation (RR) | The astronomical object in question rotates in the reverse direction, or clockwise when viewed from one of the poles. | |
| Horizontal Rotation (HR) | The planet has an axial inclination close to 90° causing it to rotatate around a horizontal axis when viewed from the stellar poles. Still experiences seasons. |