ΔV: Wiki - User contributions [en]

Ore Chunks

2024-06-22T22:14:59Z

Spdx-dv: link to minerals

'Chunks' are the colloquial name for the nuggets of [[Minerals|mineral]]-rich ore that form in the cores of [[Ringroid|ringroids]]. They are so common that many spacecraft operating within the rings are exclusively designed with their spherical forms in mind.

The [[asteroid impact of 2184]] with the then-in-construction [[Enceladus Prime]] revealed anomalous mineral concentrations within the [[A Ring]], the primary elements of which are listed below. Note that all ore chunks contain a significant amount of ice, and that their average mass and purity increase as one goes deeper into the rings.
{| class="wikitable"
|+
!Element
!Frequency
!Average chunk mass
!Average price
per metric ton
|-
|Iron (Fe)
|Very common
|7,500 kg
|900 E$
|-
|Palladium (Pd)
|Common
|4,000 kg
|2,500 E$
|-
|Platinum (Pt)
|Common
|4,000 kg
|2,700 E$
|-
|Vanadium (V)
|Common
|3,000 kg
|3,000 E$
|-
|Tungsten (W)
|Infrequent
|3,000 kg
|6,500 E$
|-
|Beryllium (Be)
|Rare
|1,000 kg
|20,000 E$
|}

[[Category:Codex]]

A Ring

2024-06-22T16:34:31Z

Spdx-dv: added map

[[File:Annotated Saturn rings.jpeg|center|thumb|1068x1068px|''Annotated map of the Saturnian ring system'']]
The A Ring is the outermost section of Saturn's inner ring system, with a width of approximately 14,600 kilometres and an average thickness of 10 to 30 metres. It is bounded at its inner edge by the Cassini Division and B Ring, and at its outer edge by the Roche Division and F Ring.

There are two gaps within the A Ring. The larger of the two is the Encke Gap, 325 kilometres in width and around 2,500 kilometres deep, and within which is the walnut-shaped shepherd moon, Pan. The smaller is the Keeler Gap, 42 kilometres wide and only 250 kilometres deep, within which is the cigar-shaped shepherd moon Daphnis. Daphnis is briefly visible in the entry and exit cinematic, but is not currently a location the player can visit.

The A Ring is home to a major excavation industry that began with the [[asteroid impact of 2184]], when a [[Ringroids|ringroid]] struck the then-in-construction [[Enceladus Prime]]. Geological analysis revealed an [[Ore Chunks|anomalous concentration of rare-earth metals]] within the rings, which would spark the [[First Enceladian Gold Rush]] and subsequent industrial developments.

The region the player can currently access is the first 2,500 kilometres before the Encke Gap. Vessels can sometimes be seen operating beyond this depth.

== Propellers==
[[File:Propeller formations.png|thumb|Propeller formations within the A Ring.]]
As ringroids orbit within the ring environment, the forces they impose on other particles create a fine web of cascading particulates that collide and ricochet off one another. This careful dance is disturbed by large objects, however.

'Propeller' formations, simply referred to as propellers, are the colloquial term for the patterns of disturbance created by tiny moonlets within the A Ring.

The moonlets, with their significantly higher mass than other objects, gently draw ringroids towards them, disturbing their orbits around Saturn. As the particles collide with others, they create high-density regions that are stretched across the ring plane due to their relative orbital velocities, forming a distinctive shape similar to a two-bladed aircraft propeller.

Propellers are known to be especially rich in minerals and are ideal locations for mining.
==Waves==
[[File:Wave formation.png|thumb|The most prominent wave formation in the outer A Ring. Another exists at its edge, before the Keeler Gap.]]
Wave formations, also known as spiral density waves, are created by orbital resonance between Saturn's moons and moonlets. Gravitational forces acting over long distances draw particulates towards them, creating spiraling regions of high and low density that are visually distinguishable in high-resolution photographs.

As the moons responsible for these formations orbit, the forces they impart on any one area of the rings change continuously. Orbital resonance, then, is the regular interactions of these forces at predictable times as the moons align in their orbits. The regularity of the interactions is the reason why these structures are stable and consistent; over a long time, the effects average out, which maintains them and prevents them from breaking apart.
[[Category:Codex]]

File:Annotated Saturn rings.jpeg

2024-06-22T16:31:53Z

Spdx-dv: An annotated map of Saturn's rings, as shown in https://photojournal.jpl.nasa.gov/catalog/PIA08389 License: public domain as per https://www.jpl.nasa.gov/jpl-image-use-policy

== Summary ==
An annotated map of Saturn's rings, as shown in https://photojournal.jpl.nasa.gov/catalog/PIA08389

License: public domain as per https://www.jpl.nasa.gov/jpl-image-use-policy

A Ring

2024-06-22T16:17:23Z

Spdx-dv: finalised rewrite with some pictures

The A Ring is the outermost section of Saturn's inner ring system, with a width of approximately 14,600 kilometres and an average thickness of 10 to 30 metres. It is bounded at its inner edge by the Cassini Division and B Ring, and at its outer edge by the Roche Division and F Ring.

There are two gaps within the A Ring. The larger of the two is the Encke Gap, 325 kilometres in width and around 2,500 kilometres deep, and within which is the walnut-shaped shepherd moon, Pan. The smaller is the Keeler Gap, 42 kilometres wide and only 250 kilometres deep, within which is the cigar-shaped shepherd moon Daphnis. Daphnis is briefly visible in the entry and exit cinematic, but is not currently a location the player can visit.

The A Ring is home to a major excavation industry that began with the [[asteroid impact of 2184]], when a [[Ringroids|ringroid]] struck the then-in-construction [[Enceladus Prime]]. Geological analysis revealed an [[Ore Chunks|anomalous concentration of rare-earth metals]] within the rings, which would spark the [[First Enceladian Gold Rush]] and subsequent industrial developments.

The region the player can currently access is the first 2,500 kilometres before the Encke Gap. Vessels can sometimes be seen operating beyond this depth.

== Propellers==
[[File:Propeller formations.png|thumb|Propeller formations within the A Ring.]]
As ringroids orbit within the ring environment, the forces they impose on other particles create a fine web of cascading particulates that collide and ricochet off one another. This careful dance is disturbed by large objects, however.

'Propeller' formations, simply referred to as propellers, are the colloquial term for the patterns of disturbance created by tiny moonlets within the A Ring.

The moonlets, with their significantly higher mass than other objects, gently draw ringroids towards them, disturbing their orbits around Saturn. As the particles collide with others, they create high-density regions that are stretched across the ring plane due to their relative orbital velocities, forming a distinctive shape similar to a two-bladed aircraft propeller.

Propellers are known to be especially rich in minerals and are ideal locations for mining.
==Waves==
[[File:Wave formation.png|thumb|The most prominent wave formation in the outer A Ring. Another exists at its edge, before the Keeler Gap.]]
Wave formations, also known as spiral density waves, are created by orbital resonance between Saturn's moons and moonlets. Gravitational forces acting over long distances draw particulates towards them, creating spiraling regions of high and low density that are visually distinguishable in high-resolution photographs.

As the moons responsible for these formations orbit, the forces they impart on any one area of the rings change continuously. Orbital resonance, then, is the regular interactions of these forces at predictable times as the moons align in their orbits. The regularity of the interactions is the reason why these structures are stable and consistent; over a long time, the effects average out, which maintains them and prevents them from breaking apart.
[[Category:Codex]]

File:Wave formation.png

2024-06-22T14:19:13Z

Spdx-dv:

The wave formation created by orbital resonance between Prometheus, Pandora, and Pan.

File:Propeller formations.png

2024-06-22T14:14:44Z

Spdx-dv:

Propeller formations inside the A Ring.

A Ring

2024-06-22T14:06:59Z

Spdx-dv: save while i transfer to my pc lol

The A Ring is the outermost section of Saturn's inner ring system, with a width of approximately 14,600 kilometres and an average thickness of 10 to 30 metres. It is bounded at its inner edge by the Cassini Division and B Ring, and at its outer edge by the Roche Division and F Ring.

There are two gaps within the A Ring. The larger of the two is the Encke Gap, 325 kilometres in width and around 2,500 kilometres deep, and within which is the walnut-shaped shepherd moon, Pan. The smaller is the Keeler Gap, 42 kilometres wide and only 250 kilometres deep, within which is the cigar-shaped shepherd moon Daphnis. Daphnis is briefly visible in the entry and exit cinematic, but is not currently a location the player can visit.

The A Ring is home to a major excavation industry that began with the [[asteroid impact of 2184]], when a [[Ringroids|ringroid]] struck the then-in-construction [[Enceladus Prime]]. Geological analysis revealed an [[Ore Chunks|anomalous concentration of rare-earth metals]] within the rings, which would spark the [[First Enceladian Gold Rush]] and subsequent industrial developments.

The region the player can currently access is the first 2,500 kilometres before the Encke Gap. Vessels can sometimes be seen operating beyond this depth.

== Waves ==
Waves are formed by orbital resonances between Saturn's larger moons and moonlets.

== Propellers ==
As ringroids orbit within the ring environment, the forces they impose on other particles create a fine web of cascading particulates that collide and ricochet off one another. This careful dance is disturbed by large objects, however.

'Propeller' formations, or just propellers, are the colloquial term for the patterns of disturbance created by relatively tiny moonlets within the A Ring.

The moonlets, with their significantly higher mass than other objects, gently draw ringroids towards them, disturbing their orbits around Saturn. As the particles collide with others, they create high-density regions that are stretched across the ring plane due to their relative orbital velocities, forming distinctive shapes similar to that of two-bladed aircraft propellers.

Propellers are most prominent in the A Ring, though it is still unknown why.
[[Category:Codex]]

Ore Chunks

2024-06-21T22:54:13Z

Spdx-dv: minor change from observations thru gameplay, need to check internal parameters

'Chunks' are the colloquial name for the nuggets of mineral-rich ore that form in the cores of [[Ringroid|ringroids]]. They are so common that many spacecraft operating within the rings are exclusively designed with their spherical forms in mind.

The [[asteroid impact of 2184]] with the then-in-construction [[Enceladus Prime]] revealed anomalous mineral concentrations within the [[A Ring]], the primary elements of which are listed below. Note that all ore chunks contain a significant amount of ice, and that their average mass and purity increase as one goes deeper into the rings.
{| class="wikitable"
|+
!Element
!Frequency
!Average chunk mass
!Average price
per metric ton
|-
|Iron (Fe)
|Very common
|7,500 kg
|900 E$
|-
|Palladium (Pd)
|Common
|4,000 kg
|2,500 E$
|-
|Platinum (Pt)
|Common
|4,000 kg
|2,700 E$
|-
|Vanadium (V)
|Common
|3,000 kg
|3,000 E$
|-
|Tungsten (W)
|Infrequent
|3,000 kg
|6,500 E$
|-
|Beryllium (Be)
|Rare
|1,000 kg
|20,000 E$
|}

[[Category:Codex]]

Ore Chunks

2024-06-20T23:53:09Z

Spdx-dv: fixed the broken table and did an in-theme rewrite

'Chunks' are the colloquial name for the nuggets of mineral-rich ore that form in the cores of [[Ringroid|ringroids]]. They are so common that many spacecraft operating within the rings are exclusively designed with their spherical forms in mind.

The [[asteroid impact of 2184]] with the then-in-construction [[Enceladus Prime]] revealed anomalous mineral concentrations within the [[A Ring]], the primary elements of which are listed below. Note that all ore chunks contain a significant amount of ice, and that their average mass and purity increase as one goes deeper into the rings.
{| class="wikitable"
|+
!Element
!Frequency
!Average chunk mass
!Average price
per metric ton
|-
|Iron (Fe)
|Very common
|6,000 kg
|900 E$
|-
|Palladium (Pd)
|Common
|4,000 kg
|2,500 E$
|-
|Platinum (Pt)
|Common
|4,000 kg
|2,700 E$
|-
|Vanadium (V)
|Common
|4,000 kg
|3,000 E$
|-
|Tungsten (W)
|Infrequent
|3,000 kg
|6,500 E$
|-
|Beryllium (Be)
|Rare
|1,000 kg
|20,000 E$
|}

[[Category:Codex]]

Reactor Core

2024-06-19T18:30:40Z

Spdx-dv: added RCS link

Reactor cores are specialised containment vessels designed to facilitate controlled [[fission]], and are usually reinforced with strong, heat-resistant materials to contain the associated high pressures and temperatures.

[[Nuclear propulsion|Nuclear propulsion systems]] utilise the energy created by reactor cores to heat and accelerate propellant, which also acts as a coolant during periods of high thermal load. [[Radiator|Radiator panels]] mounted to the outer hull of a spacecraft help to cool the core when it's not being used, or when it's too hot.

If a reactor becomes too hot, the ship's computer will attempt to bleed off heat by venting it through the [[Reaction Control System|RCS thrusters]]. At higher temperatures, thrusters are more powerful, [[Powerplant|turbines]] and [[Auxiliary Power Unit|magnetoplasmadynamic electrical generators]] produce more power, and more thermal energy is immediately available for manoeuvring, but thrusters will wear out faster and turbines may experience galling, reducing their long-term effectiveness.

If a reactor reaches its failure temperature and continues to heat up, the core will lose structural integrity and experience an explosive meltdown, destroying the ship it's attached to and releasing radioactive materials into the environment. Some eagle-eyed pilots you encounter are able to detect the residues these materials leave on nearby [[ringroids]], which is often indicative of [[Ganymedean Anarchy|pirate activity]].

{{#invoke:Equipment|list|Reactor Core
|caption=Reactor Cores
|Name|Manufacturer
|Operating Temperature | Failure Point | Thermal Power
|Mass|Price}}

[[Category:Equipment]]

Fission

2024-06-19T18:28:30Z

Spdx-dv: changed link to direct to MPDGs

When radioactive atoms decay or are hit by neutrons, they produce lighter elements and release energy in a process known as fission. Fission can produce large amounts of energy over a long period, which makes it an ideal heat source for [[Nuclear Thermal Rocket|nuclear thermal rockets]], where radioactive fuel is contained within a [[Reactor Core|reactor core]] and cooled by [[Propellant Tank|propellant]].

The heat produced by fission is also ideal in power generation, which can be done through the use of a [[Powerplant|turbine]] or [[Auxiliary Power Unit#Magnetoplasmadynamic generators|magnetoplasmadynamic generator]].

== Fuel ==
Specific isotopes of elements such as uranium (in the case of the Yama-SSR series) and plutonium are the chosen fuel for nuclear reactors because they are fissile. While many radioactive isotopes are fissionable, meaning that they undergo fission when hit by neutrons of any energy level, fissile materials are especially responsive to low-energy "thermal" neutrons. Thermal neutrons are the result of high-energy neutrons scattering and losing energy in a moderator, which absorbs and dissipates their energy as heat.

Thorium may also be used (as is the case for the SO6 fuel rod series), but the most common isotope of thorium is not fissile; it is, however, fertile. When exposed to neutrons, fertile materials absorb them to create fissile materials, which can then undergo fission to produce energy.

Radioactive fuels last far longer than chemical fuels due to their incredible energy density. Fuel rods can operate continuously for months or even years before needing to be replaced, depending on how they're used.

== Controlling the Reaction ==
Fission can be controlled by adjusting the parameters of the reactor. Different approaches include:

* Control rods that absorb neutrons can be inserted between the fuel rods, reducing the amount of neutrons available to trigger fission.
* The fuel rods can be removed from the reactor, reducing the amount of fissile material for neutrons to hit.
* In liquid core reactors, the liquid fuel can be pumped away from the moderator, reducing the amount of thermal neutrons that can trigger fission.

[[Category:Codex]]

Powerplant

2024-06-19T18:27:26Z

Spdx-dv: put APU on new line

The primary power generator of [[Fission|fission-powered]] vessels is typically a thermal-gas turbine that converts the kinetic energy of reactor-heated propellant into electrical energy. Turbines as they exist in Delta-V rely on similar principles to steam turbines, but are much more advanced in their implementation and execution, using expanding supercritical propellant instead of boiling water.

Spacecraft turbines can operate in one of two modes: closed- and open-cycle. When travelling through [[astrogation]] or during interlunar transit, the turbine operates in a closed cycle, generating a small amount of electricity while returning the cold propellant gas to the reactor for reheating. When at work in the rings, the turbine operates in an open cycle, generating a large amount of electricity and exhausting the waste gas into space.

Turbines that are subject to high temperatures produce more immediate power, but are prone to galling. Galled turbines will produce less power overall at standard reactor temperatures, so it's important to maintain them.

Power generation can be increased or accentuated through the installation of an [[Auxiliary Power Unit|auxiliary power unit]].{{#invoke:Equipment|list|Powerplant
|caption=Available powerplants
|Name

|Power (nominal)
|Propellant Consumption
|Mass|Price}}

[[Category:Equipment]]

Auxiliary Power Unit

2024-06-19T18:23:39Z

Spdx-dv: rewrite, separated tables for readability, added links

An auxiliary power unit is an additional source of power generation separate from the [[powerplant]] that can be installed onto a vessel to satisfy additional power needs, or to increase power efficiency. There are two types: storage and generation.

Both types do not currently require maintenance, and any can be installed on all spacecraft, regardless of their size.

==Magnetoplasmadynamic Generators==
Magnetoplasmadynamic generators (or MPDGs) utilise the electromagnetic fields generated by flowing propellant plasma to generate electricity. They operate in a closed cycle, meaning that spent plasma is returned to the reactor for reheating.

MPDGs are desirable for captains who prefer propellant efficiency and immediate power production above all other factors. Exchanging a military-grade turbine for a single turbine and an MPDG can reduce the dry mass of the vessel while providing a similar or greater amount of power, all while increasing power generation efficiency by a factor of 5.

{{#invoke:Equipment|list|Auxiliary Power Generator|caption=Generators
|Name|Power Consumption|Thermal Consumption|Power (nominal)|Mass|Price}}

==Superconductive Magnetic Energy Storage==
Superconductive magnetic energy storage systems (SMESes) store energy in the magnetic field of a superconductive electromagnet. They can store massive amounts of power, but their charge and discharge rates are limited, unlike [[Ultracapacitor Array|ultracapacitors]].

SMESes are desirable for captains who prefer low dry mass, and whose ships occasionally outpace their power generation capacity. Vessels with mass drivers and other high-power devices tend to also need manoeuvring capability, and a SMES can provide a comfortable buffer during times of high power load.

Power capacity, like ultracapacitors, is measured in megajoules. One megajoule over one second is equal to one megawatt, as watts are joules over time.

{{#invoke:Equipment|list|Auxiliary Power Storage|caption=Storage
|Name|Energy capacity|Charge power draw|Discharge power (peak)|Mass|Price}}

[[Category:Equipment]]

Module:Equipment

2024-06-19T18:16:44Z

Spdx-dv: normalisation of APU column titles

local p = {}
local d = require('Module:Data')
local dv = require('Module:Data/View')

p.view = {}

p.view['Name'] = dv.text{'name'}
p.view['Title'] = dv.title{function(item) return item.title or item.name end, heading='Name', text='name'}
p.view['Price'] = dv.number{'price', unit='E$'}
p.view['Mass'] = dv.number{'mass', unit='kg'}
p.view['Manufacturer'] = dv.text{'manufacturer'}
p.view['Other'] = dv.text{'other'}

-- Hardpoints
p.view['High-Stress'] = dv.flag{'highStress'}
p.view['Low-Stress'] = dv.flag{'lowStress'}
p.view['Docking bay'] = dv.flag{'dockingBay'}
p.view['Drone hardpoint'] = dv.flag{'droneHardpoint'}

p.view['Effective range'] = dv.number{'effectiveRange', unit='m'}
p.view['Power draw'] = dv.number{'powerDraw', unit='MW'}

-- Drones
p.view['Drones per second'] = dv.number{'droneLaunchCapability'}
p.view['Drone wet mass'] = dv.number{'droneWetMass', unit='kg'}
p.view['Drone thrust'] = dv.number{'droneThrust', unit='kN'}

-- Projectile magazines, nanodrone components, and propellant tanks
p.view['Storage'] = dv.number{'storage', unit='kg'}
p.view['Delivery'] = dv.number{'delivery', unit='kg/s'}
p.view['Exclusive to'] = dv.list{'exclusiveTo', itemView=dv.title{nil}}

-- Ultracapacitors
p.view['Energy capacity'] = dv.number{'energyCapacity', unit='MJ'}
p.view['Peak power'] = dv.number{'peakPower', unit='GW'}

-- Autopilots
p.view['AAT'] = dv.flag{'aat', heading='[[Autopilot#AAT|AAT]]'}
p.view['ARL'] = dv.flag{'arl', heading='[[Autopilot#ARL|ARL]]'}
p.view['RTC'] = dv.flag{'rtc', heading='[[Autopilot#RTC|RTC]]'}
p.view['FBW'] = dv.flag{'fbw', heading='[[Autopilot#FBW|FBW]]'}
p.view['Autopilot capabilities'] = dv.list{'autopilotCapabilities', heading='Capabilities', itemView=dv.text{nil}}

-- Gimbals/Vectored
p.view['Vectored Thrust Angle'] = dv.number{'vectoredThrustAngle', unit='deg'}
p.view['Gimbal Angle'] = dv.number{'gimbalAngle', unit='deg'}
p.view['Gimbal Speed'] = dv.number{'gimbalSpeed', unit='deg/s'}

-- Main Propulsion and RCS
p.view['Thrust'] = dv.number{'thrust', unit='kN'}
p.view['Exhaust Velocity'] = dv.number{'exhaustVelocity', unit='km/s'}
p.view['Propellant Consumption'] = dv.number{'propellantConsumption', unit='kg/s'}
p.view['Power Consumption'] = dv.number{'powerConsumption', unit='MW'}
p.view['Thermal Consumption'] = dv.number{'thermalConsumption', unit='GW'}
p.view['Response Time'] = dv.number{'responseTime', unit='s'}
p.view['Operation Mode'] = dv.text{'operationMode'}
p.view['Propellant'] = dv.text{'propellant'}

-- Auxiliary Power System (& Turbines)
p.view['Power (nominal)'] = dv.number{'power', unit='MW'}
p.view['Charge power draw'] = dv.number{'chargePower', unit='MW'}
p.view['Discharge power (peak)'] = dv.number{'dischargePower', unit='MW'}
p.view['APU type'] = dv.number{'apsType', unit='MW'}
p.view['Category'] = dv.list{'categories', itemView=dv.title{nil}}

-- Reactor Cores
p.view['Operating Temperature'] = dv.number{'operatingTemperature', unit='K'}
p.view['Failure Point'] = dv.number{'failureTemperature', unit='K'}
p.view['Thermal Power'] = dv.number{'thermalPower', unit='GW'}

for k,v in pairs(p.view) do
v.heading = v.heading or k
end

p.defaultColumns = {
'Name', 'Price', 'Mass'
}

p.positionalArgs = function(f)
local posArgs = {}
for i,posArg in ipairs(f.args) do
-- positional arguments don't get trimmed
table.insert(posArgs, mw.text.trim(posArg))
end
return posArgs
end

p.list = function(f)
local posArgs = p.positionalArgs (f)
local slot = table.remove(posArgs, 1)
local columns = posArgs
if table.getn(columns) == 0 then
columns = p.defaultColumns
end

local data = mw.loadData('Module:Equipment/Data')
data = data[slot]

data = d.sort(data, {
d.on(d.path{'price'}, d.asc),
d.on(d.path{'name'}, d.asc),
})

local options = {
caption = f.args['caption']
}

return dv.displayTable(data, p.view, columns, options)
end

return p

Module:Equipment/Data

2024-06-19T17:44:36Z

Spdx-dv: separated storage from generator in APU

local equipment = {
Hardpoint = {
['EMD-14 mass driver'] = {
title = 'EMD-14 Mass Driver',
price = 10000,
powerConsumptionPeak = 750,
projectileMass = 10,
projectileVelocity = 4500,
rateOfFire = 2,
mass = 3000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['MPI Railgun MkI'] = {
title = 'MPI Railgun Mk I',
price = 20000,
powerConsumptionPeak = 800,
projectileMass = 2,
projectileVelocity = 7500,
rateOfFire = 10,
mass = 2000,
manufacturer = 'Nars Power Industries',
mounting = {'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['ERFMD-17 mass driver'] = {
title = 'ERFMD-17 Mass Driver',
price = 30000,
powerConsumptionPeak = 500,
projectileMass = 10,
projectileVelocity = 3000,
rateOfFire = 5,
mass = 5000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['AEMD-14 mass driver'] = {
title = 'AEMD-14 Mass Driver',
price = 32000,
powerConsumptionPeak = 750,
projectileMass = 10,
gimbalSpeed = 36,
projectileVelocity = 4500,
rateOfFire = 2,
mass = 3000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['AR-1500 Manipulator'] = {
price = 56000,
armStrength = 1500,
reach = 40,
powerDrawPeak = 180,
mounting = {'High-Stress'},
mass = 8000,
manufacturer = 'Triskelion-Armstrong'
},
['MWG microwave emitter'] = {
price = 70000,
effectiveRange = 600,
powerConsumption = 50,
outputPower = 45,
wavelength = 10000000,
mass = 100,
manufacturer = 'Nakamura Dynamics',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Electromagnetic'}
},
['EINAT Kzinti Lesson MkII'] = {
title = 'EINAT Kzinti Lesson Mk II',
price = 100000,
effectiveRange = 100,
powerConsumption = 200,
thermalConsumption = 18.4,
outputPower = 18400,
mounting = {'High-Stress'},
mass = 2750,
manufacturer = 'Elon Interstellar',
categories = {'Energy'},
damage = {'Kinetic', 'Thermal'}
},
['CL-150 mining laser'] = {
price = 150000,
effectiveRange = 8000,
powerConsumption = 150,
outputPower = 125,
wavelength = 490,
mass = 4000,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal'}
},
['Point Defence microwave emitter'] = {
price = 180000,
effectiveRange = 600,
targetingAI = 'Class-1',
powerConsumption = 50,
outputPower = 45,
wavelength = 10000000,
mass = 1600,
manufacturer = 'Obonto-Nakamura',
mounting = {'Docking bay', 'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Electromagnetic'}
},
['CL-200AP pulse mining laser'] = {
price = 200000,
effectiveRange = 8000,
powerConsumption = 220,
gimbalSpeed = 36,
outputPower = 200,
pulses = 24,
wavelength = 650,
mass = 5500,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Kinetic'}
},
['MPI Tug drones'] = {
price = 250000,
powerDraw = 50,
effectiveRange = 400,
droneLaunchCapability = 50,
droneWetMass = 0.1,
droneThrust = 1,
mass = 4000,
manufacturer = 'Mars Power Industries',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['NANI'] = {
price = 300000,
effectiveRange = 1000,
powerConsumption = 200,
thermalConsumption = 2,
outputPower = 230000,
mounting = {'High-Stress'},
mass = 10000,
manufacturer = 'Omaewamou-Shindeiru',
categories = {'Energy'},
damage = {'Kinetic', 'Thermal'}
},
['CL-600P pulse mining laser'] = {
price = 320000,
effectiveRange = 8000,
powerConsumption = 660,
outputPower = 600,
pulses = 12,
wavelength = 540,
mass = 7000,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Kinetic'}
},
['MLF Haul Drones'] = {
price = 350000,
powerDraw = 50,
effectiveRange = 400,
droneLaunchCapability = 50,
droneWetMass = 0.1,
droneThrust = 1,
mass = 4000,
manufacturer = 'Minding LF',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['OME Maintenance Drones'] = {
price = 400000,
powerDraw = 50,
droneLaunchCapability = 32,
mass = 4000,
manufacturer = 'Obonto Micro Engineering',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['External Impact Absorber'] = {
price = 4000,
mass = 8000,
cradleMass = 500,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress'}
},
['B8 Claim Beacon'] = {
price = 43000,
dryMass = 8000,
propellant = 8000,
autonomyClass = 'C1',
cradleMass = 500,
manufacturer = 'Triskelion-Armstrong',
mounting = {'Docking bay', 'Low-Stress'}
},
['THI Cargo Container'] = {
price = 74000,
processedCargoCapacity = 15000,
powerUsage = 20,
cradleMass = 500,
manufacturer = 'Titan Heavy Industries',
mounting = {'Docking bay', 'Low-Stress'},
categories = {'Cargo'}
},
['THI Monocargo Container'] = {
price = 111000,
processedCargoCapacitySingle = 90000,
powerUsage = 20,
cradleMass = 500,
manufacturer = 'Titan Heavy Industries',
mounting = {'Docking bay', 'Low-Stress'},
categories = {'Cargo'}
},
['NT Mining Companion'] = {
price = 115000,
autonomyClass = 'C2',
powerUsage = 10,
cradleMass = 500,
manufacturer = 'Nakamura-Titan',
mounting = {'Docking bay', 'Low-Stress'}
},
['SPC Gungnir'] = {
price = 270000,
powerConsumption = 400,
maximumCharge = 11.2,
fullChargeTime = 30,
projectileVelocity = 298805,
projectileMass = 0.000000011,
mounting = {'Low-Stress'},
mass = 15000,
manufacturer = 'Omaewamou-Shindeiru',
categories = {'Projectile'},
damage = {'Kinetic', 'Thermal', 'Electromagnetic'}
}
},
['Kinetic Ammunition'] = {
['Projectile magazine'] = {
price = 5000,
storage = 1000,
delivery = 100,
manufacturer = 'Conlido RVM'
},
['Dual projectile magazine'] = {
price = 10000,
storage = 2000,
delivery = 200,
manufacturer = 'Conlido RVM'
},
['Heavy projectile magazine'] = {
price = 25000,
storage = 5000,
delivery = 200,
manufacturer = 'Tetsuo Engineering'
},
['Military projectile magazine'] = {
price = 50000,
storage = 10000,
delivery = 200,
manufacturer = 'Nakamura Dynamics'
},
['Frigate-class projectile magazine'] = {
price = 100000,
storage = 20000,
delivery = 500,
manufacturer = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
['Destroyer-class projectile magazine'] = {
price = 250000,
storage = 50000,
projectileDelivery = 500,
delivery = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
},
['Nanodrone Components'] = {
['Basic nanodrone storage'] = {
price = 20000,
storage = 1000,
delivery = 20,
manufacturer = 'Mars Power Industries'
},
['Industrial nanodrone storage'] = {
price = 120000,
storage = 5000,
delivery = 20,
manufacturer = 'Conlido RVM',
},
['Military nanodrone storage'] = {
price = 250000,
storage = 10000,
delivery = 100,
manufacturer = 'Nakamura Dynamics',
},
['Harvester-class nanodrone storage'] = {
price = 500000,
storage = 20000,
delivery = 100,
manufacturer = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
['Station-class nanodrone storage'] = {
price = 1250000,
storage = 50000,
delivery = 100,
manufacturer = 'Obonto Microengineering',
exclusiveTo = {'K225', 'OCP-209'}
},
},
['Propellant Tanks'] = {
['Short-range propellant tank'] = {
price = 6000,
storage = 15000
},
['Standard propellant tank'] = {
price = 12000,
storage = 30000
},
['Extended propellant tank'] = {
price = 20000,
storage = 50000
},
['Long-range propellant tank'] = {
price = 32000,
storage = 80000
},
['Interplanetary propellant tank'] = {
price = 160000,
storage = 200000
},
['Freighter propellant tank'] = {
price = 400000,
storage = 500000,
exclusiveTo = {'K225', 'OCP-209'}
}
},
['Reaction Control System'] = {
['NDSTR thruster'] = {
price = 1250,
thrust = 600,
exhaustVelocity = 7,
propellantConsumption = 85.7,
powerConsumption = 1,
thermalConsumption = 2.1,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 20,
manufacturer = 'Nakamura Dynamics',
},
['NDVTT thruster'] = {
price = 2500,
thrust = 500,
exhaustVelocity = 7,
propellantConsumption = 71.4,
powerConsumption = 1,
thermalConsumption = 1.8,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 30,
manufacturer = 'Nakamura Dynamics',
},
['RA-K37 thruster'] = {
price = 3125,
thrust = 200,
exhaustVelocity = 15,
propellantConsumption = 13.3,
powerConsumption = 5,
thermalConsumption = 1.5,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 70,
manufacturer = 'Rusatom-Antonoff',
},
['MA150HO thruster'] = {
price = 4375,
thrust = 150,
exhaustVelocity = 30,
propellantConsumption = 5,
powerConsumption = 40,
thermalConsumption = 2.3,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 80,
manufacturer = 'Mitsudaya-Starbus',
},
['RA-K44 thruster'] = {
price = 6250,
thrust = 400,
exhaustVelocity = 15,
propellantConsumption = 26.6,
powerConsumption = 15,
thermalConsumption = 1.5,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 75,
manufacturer = 'Rusatom-Antonoff',
},
['Elon Interstellar Ion Thruster'] = {
price = 8000,
thrust = 120,
exhaustVelocity = 50,
propellantConsumption = 2.4,
powerConsumption = 40,
thermalConsumption = 3,
operationMode = 'Variable thrust',
propellant = 'Hydrogen plasma',
mass = 90,
manufacturer = 'Elon Interstellar',
},
['ERS-NAGHET 5020'] = {
price = 8500,
thrust = 210,
exhaustVelocity = 27,
propellantConsumption = 7.8,
powerConsumption = 50,
thermalConsumption = 2.8,
operationMode = 'Variable thrust',
gimbalAngle = 20,
gimbalSpeed = 360,
propellant = 'Oxygen-Hydrogen plasma',
mass = 130,
manufacturer = 'Electo Ride Systems',
},
['MA350HO thruster'] = {
price = 10000,
thrust = 350,
exhaustVelocity = 25,
propellantConsumption = 14,
powerConsumption = 60,
thermalConsumption = 4.4,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 120,
manufacturer = 'Mitsudaya-Starbus',
},
['Elon Interstellar AGILE Thruster'] = {
price = 12000,
thrust = 120,
exhaustVelocity = 40,
propellantConsumption = 3,
powerConsumption = 60,
thermalConsumption = 2.5,
operationMode = 'Variable thrust',
gimbalAngle = 35,
gimbalSpeed = 160,
propellant = 'Hydrogen plasma',
mass = 120,
manufacturer = 'Elon Interstellar',
},
['RA-K69V thruster'] = {
price = 6250,
thrust = 400,
exhaustVelocity = 12,
propellantConsumption = 33.3,
powerConsumption = 25,
thermalConsumption = 3.6,
operationMode = 'Pulsed thrust',
gimbalAngle = 25,
gimbalSpeed = 540,
propellant = 'Oxygen-Hydrogen plasma',
mass = 150,
manufacturer = 'Rusatom-Antonoff',
categories = {'Racing'}
},
},
['Main Propulsion'] = {
['ND-PNTR engine'] = {
price = 7000,
thrust = 1500,
exhaustVelocity = 8,
propellantConsumption = 187.5,
powerConsumption = 180,
thermalConsumption = 6,
vectoredThrustAngle = 90,
operationMode = 'Pulsed thrust',
responseTime = 2.1,
propellant = 'Oxygen-Hydrogen plasma',
mass = 450,
manufacturer = 'Nakamura Dynamics',
other = 'Vectored thrust (90°)',
},
['RA-TNTRL-K37 engine'] = {
price = 15000,
thrust = 750,
exhaustVelocity = 15,
propellantConsumption = 50,
powerConsumption = 100,
thermalConsumption = 5.6,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 1250,
manufacturer = 'Rusatom-Antonoff',
},
['ND-NTTR thruster'] = {
price = 30000,
thrust = 3500,
exhaustVelocity = 7,
propellantConsumption = 500,
powerConsumption = 20,
thermalConsumption = 12.2,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 650,
manufacturer = 'Nakamura Dynamics',
},
['RA-MHFTR-K44 engine'] = {
price = 40000,
thrust = 1500,
exhaustVelocity = 18,
propellantConsumption = 83.3,
powerConsumption = 100,
thermalConsumption = 13.5,
gimbalAngle = 9,
gimbalSpeed = 36,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 1650,
manufacturer = 'Rusatom-Antonoff',
other = 'Gimbaled (9°)',
},
['BWM-T535'] = {
price = 120000,
thrust = 535,
exhaustVelocity = 29,
propellantConsumption = 18.4,
powerConsumption = 0.040,
thermalConsumption = 8.2,
operationMode = 'Variable thrust',
responseTime = 0.9,
propellant = 'Oxygen-Hydrogen plasma',
mass = 2000,
manufacturer = 'BWM',
other = 'Integrated turbine',
},
['ERS-DFMHD-2205'] = {
price = 175000,
thrust = 2200,
exhaustVelocity = 14,
propellantConsumption = 157.1,
powerConsumption = 120,
thermalConsumption = 15.4,
operationMode = 'Variable thrust',
responseTime = 0.6,
propellant = 'Oxygen-Hydrogen plasma',
mass = 2450,
manufacturer = 'Electro Ride Systems',
},
['MA-NMPD42 engine'] = {
price = 300000,
thrust = 320,
exhaustVelocity = 115,
propellantConsumption = 2.8,
powerConsumption = 150,
thermalConsumption = 18.4,
operationMode = 'Variable thrust',
propellant = 'Hydrogen plasma',
mass = 1850,
manufacturer = 'Mitsudaya-Starbus',
},
['Experimental NPMP engine'] = {
price = 700000,
thrust = 1100,
exhaustVelocity = 45,
propellantConsumption = 24.4,
powerConsumption = 200,
thermalConsumption = 24.7,
operationMode = 'Pulsed thrust',
propellant = 'Hydrogen plasma',
mass = 2750,
manufacturer = 'Elon Interstellar',
},
['Z-Axial Pinch fusion torch'] = {
price = 1000000,
thrust = 800,
exhaustVelocity = 1250,
propellantConsumption = 0.6,
ignitionConsumption = 150,
operationMode = 'Variable thrust',
gimbalAngle = 30,
gimbalSpeed = 28,
propellant = 'Hydrogen plasma',
fusionFuel = '3He-D',
burnTime = 30,
mass = 3000,
manufacturer = 'Elon Interstellar',
other = 'Gimbaled (30°), fusion drive with 30min burn time',
},
},
['Reactor Core'] = {
['4x SO6 fuel rod'] = {
price = 80000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 2000,
thermalPower = 4,
manufacturer = 'Rusatom-Antonoff'
},
['8x SO6 fuel rod'] = {
price = 160000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 4000,
thermalPower = 8,
manufacturer = 'Rusatom-Antonoff'
},
['12x SO6 fuel rod'] = {
price = 240000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 6000,
thermalPower = 12,
manufacturer = 'Rusatom-Antonoff'
},
['16x SO6 fuel rod'] = {
price = 320000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 8000,
thermalPower = 16,
manufacturer = 'Rusatom-Antonoff'
},
['20x SO6 fuel rod'] = {
price = 400000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 10000,
thermalPower = 20,
manufacturer = 'Rusatom-Antonoff'
},
['Nakamura Dynamics Yama-SSR12'] = {
price = 750000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 5000,
thermalPower = 30,
manufacturer = 'Nakamura Dynamics'
},
['Nakamura Dynamics Yama-SSR16'] = {
price = 1000000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 5500,
thermalPower = 40,
manufacturer = 'Nakamura Dynamics'
},
['Nakamura Dynamics Yama-SSR16S'] = {
price = 1500000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 6000,
thermalPower = 50,
manufacturer = 'Nakamura Dynamics',
categories = {'Racing'}
},
},
['Ultracapacitor Array'] = {
['Ultracapacitor'] = {
price = 25000,
energyCapacity = 500,
peakPower = 10,
mass = 2000,
manufacturer = 'Obonto Micro Engineering'
},
['Dual Ultracapacitor'] = {
price = 55000,
energyCapacity = 1000,
peakPower = 10,
mass = 4000,
manufacturer = 'Obonto Micro Engineering'
},
['Triple Ultracapacitor'] = {
price = 90000,
energyCapacity = 1500,
peakPower = 10,
mass = 6000,
manufacturer = 'Obonto Micro Engineering'
},
},
['Powerplant'] = {
['Turbine'] = {
price = 30000,
power = 100,
propellantConsumption = 0.1,
mass = 500,
manufacturer = 'Rusatom-Antonoff'
},
['Twin Turbine'] = {
price = 60000,
power = 200,
propellantConsumption = 0.2,
mass = 1000,
manufacturer = 'Rusatom-Antonoff'
},
['Military-Grade Turbine'] = {
price = 150000,
power = 500,
propellantConsumption = 0.5,
mass = 5000,
manufacturer = 'Rusatom-Antonoff'
}
},
['Auxiliary Power Generator'] = {
['MPD5035'] = {
price = 300000,
powerConsumption = 50,
thermalConsumption = 0.5,
power = 350,
mass = 2500,
apsType = 'MPDG',
manufacturer = 'Mitsudaya-Starbus',
categories = {'MPDG'}
},
['EIPFG MkIV Big Furnace Generator'] = {
price = 500000,
powerConsumption = 100,
thermalConsumption = 1,
power = 700,
mass = 4000,
apsType = 'MPDG',
manufacturer = 'Elon Interstellar',
categories = {'MPDG'}
},
['MPI Town-class MPDG'] = {
price = 800000,
powerConsumption = 150,
thermalConsumption = 1.5,
power = 1000,
mass = 8000,
apsType = 'MPDG',
manufacturer = 'Mars Power Industries',
categories = {'MPDG'}
}
},
['Auxiliary Power Storage'] = {
['NDAPS'] = {
price = 400000,
energyCapacity = 18000,
chargePower = 100,
dischargePower = 3000,
mass = 1000,
apsType = 'SMES',
manufacturer = 'Nakamura Dynamics',
categories = {'SMES'}
},
['MPI Town-class storage'] = {
price = 800000,
energyCapacity = 32000,
chargePower = 150,
dischargePower = 3000,
mass = 2000,
apsType = 'SMES',
manufacturer = 'Mars Power Industries',
categories = {'SMES'}
},
['EIUP MkII Unlimited Power'] = {
price = 1200000,
energyCapacity = 50000,
chargePower = 200,
dischargePower = 6000,
mass = 3500,
apsType = 'SMES',
manufacturer = 'Elon Interstellar',
categories = {'SMES'}
}
},
['Cargo Bay'] = {
['Standard cargo bay'] = {
price = 0
},
['Cargo bay baffles'] = {
price = 2000
},
['Rusatom-Antonoff MPU'] = {
price = 350000,
processingCapacity = 20,
processingPower = 2,
mineralProcessingEfficiency = 40,
remassProcessingEfficiency = 40,
mass = 1700,
manufacturer = 'Rusatom-Antonoff',
categories = {'MPU'}
},
['Nakamura MPU'] = {
price = 500000,
processingCapacity = 50,
processingPower = 25,
mineralProcessingEfficiency = 70,
remassProcessingEfficiency = 30,
mass = 4200,
manufacturer = 'Nakamura Dynamics',
categories = {'MPU'}
},
['Mitsudaya Starbus MSU'] = {
price = 900000,
processingCapacity = 100,
processingPower = 150,
mineralProcessingEfficiency = 90,
mass = 2500,
manufacturer = 'Mitsudaya-Starbus',
categories = {'MPU'}
},
['Voyager RSLS Fabrication Plant'] = {
price = 1500000,
processingCapacity = 40,
processingPower = 20,
powerConsumption = 70,
mineralProcessingEfficiency = 50,
remassProcessingEfficiency = 60,
mass = 6000,
manufacturer = 'Nakamura-Obonto',
categories = {'MPU'}
},
},
['Autopilot'] = {
['MLF Autopilot'] = {
price = 10000,
manufacturer = 'Minding LF',
arl = true,
autopilotCapabilities = {
'LIDAR highlight'
}
},
['MA-337 Autopilot'] = {
price = 27000,
manufacturer = 'Mitsudaya-Starbus',
arl = true,
aat = true,
autopilotCapabilities = {
'LIDAR overlay'
}
},
['NDCI Autopilot'] = {
price = 60000,
manufacturer = 'Nakamura Dynamics',
rtc = true,
fbw = true,
autopilotCapabilities = {
'Firing solutions',
'Collision warnings'
}
},
['ER-42 Autopilot'] = {
price = 100000,
manufacturer = 'Electro Ride Systems',
arl = true,
aat = true,
rtc = true,
fbw = true,
autopilotCapabilities = {
'Trajectory prediction'
}
},
['EIAA-1337 Autopilot'] = {
price = 150000,
manufacturer = 'Elon Interstellar',
arl = true,
aat = true,
rtc = true,
fbw = true,
autopilotCapabilities = {
'Autonomic'
}
}
},
['Head-Up Display'] = {
['HAL9000'] = {
price = 500
},
['Eagle Prospector'] = {
price = 3000
},
['K37 TNTRL'] = {
price = 4000
},
['AT-K225'] = {
price = 6000
},
['Eagle Prospector (metric mod)'] = {
price = 10000
},
['OCP-209'] = {
price = 15000,
},
['Elon Interstellar Model E'] = {
price = 25000,
},
['Bald Eagle Racing HUD'] = {
price = 50000,
categories = {'Racing'}
}
},
['Reconnaissance Craft'] = {
['Obonto USV-R'] = {
price = 10000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5
},
['Runasimi Gravimetric USV'] = {
price = 40000,
manufacturer = 'Runasimi Inc.',
reconRange = 5,
reconCapability = 'Gravitational map',
},
['Obonto USV-D Microseismic Series'] = {
price = 60000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5,
reconCapability = 'Ore identification',
},
['Obonto USV-GOT'] = {
price = 200000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5,
reconCapability = 'Drone priority queue',
}
}
}

local hardpointTypes = {
['High-Stress'] = 'highStress',
['Low-Stress'] = 'lowStress',
['Drone'] = 'droneHardpoint',
['Docking bay'] = 'dockingBay'
}

local categories = {}
local addCategory = function(cats, cat, item)
cats[cat] = cats[cat] or {}
table.insert(cats[cat], item)
end

for equipmentType,items in pairs(equipment) do
for name,item in pairs(items) do
item.equipmentType = equipmentType
item.name = item.name or name

for i,hardpointType in ipairs(item.mounting or {}) do
if hardpointTypes[hardpointType] then
item[hardpointTypes[hardpointType]] = true
end

addCategory(categories, hardpointType, item)
end

if item.highStress and not item.lowStress then
addCategory(categories, 'High-Stress only', item)
end
if item.lowStress and not item.dockingBay then
addCategory(categories, 'Low-Stress required', item)
end
if item.dockingBay and not item.droneHardpoint then
addCategory(categories, 'Docking bay required', item)
end

for i,category in ipairs(item.categories or {}) do
addCategory(categories, category, item)
end
end
end

for k,items in pairs(categories) do
equipment[k] = items
end

for name,item in pairs(equipment['Head-Up Display']) do
item.title = item.title or ('Head-Up Display#' .. item.name)
end

return equipment

Powerplant

2024-06-19T17:18:27Z

Spdx-dv: removed fluff

The primary power generator of [[Fission|fission-powered]] vessels is typically a thermal-gas turbine that converts the kinetic energy of reactor-heated propellant into electrical energy. Turbines as they exist in Delta-V rely on similar principles to steam turbines, but are much more advanced in their implementation and execution, using expanding supercritical propellant instead of boiling water.

Spacecraft turbines can operate in one of two modes: closed- and open-cycle. When travelling through [[astrogation]] or during interlunar transit, the turbine operates in a closed cycle, generating a small amount of electricity while returning the cold propellant gas to the reactor for reheating. When at work in the rings, the turbine operates in an open cycle, generating a large amount of electricity and exhausting the waste gas into space.

Turbines that are subject to high temperatures produce more immediate power, but are prone to galling. Galled turbines will produce less power overall at standard reactor temperatures, so it's important to maintain them, especially if you're running an [[Auxiliary Power Unit|auxiliary power unit]].{{#invoke:Equipment|list|Powerplant
|caption=Available powerplants
|Name

|Power (nominal)
|Propellant Consumption
|Mass|Price}}

[[Category:Equipment]]

Powerplant

2024-06-19T00:04:00Z

Spdx-dv: initial modification, need to work this one out

The primary power generator of [[Fission|fission-powered]] vessels is typically a thermal-gas turbine that converts the kinetic energy of reactor-heated propellant into electrical energy. The principle behind thermal-gas turbines has been understood for a very long time, the first example in recorded history having been the steam-powered aeolipile described in Roman engineer Vitruvius' ''De architectura'', a treatise on contemporary architecture that was published before the Common Era.

Turbines as they exist in Delta-V rely on similar principles to steam turbines, but are much more advanced in their implementation and execution.{{#invoke:Equipment|list|Powerplant
|caption=Available powerplants
|Name

|Power (nominal)
|Propellant Consumption
|Mass|Price}}

[[Category:Equipment]]

Reactor Core

2024-06-18T21:42:47Z

Spdx-dv: rewrote this and added some links

Reactor cores are specialised containment vessels designed to facilitate controlled [[fission]], and are usually reinforced with strong, heat-resistant materials to contain the associated high pressures and temperatures.

[[Nuclear propulsion|Nuclear propulsion systems]] utilise the energy created by reactor cores to heat and accelerate propellant, which also acts as a coolant during periods of high thermal load. [[Radiator|Radiator panels]] mounted to the outer hull of a spacecraft help to cool the core when it's not being used, or when it's too hot.

If a reactor becomes too hot, the ship's computer will attempt to bleed off heat by venting it through the RCS thrusters. At higher temperatures, thrusters are more powerful, [[Powerplant|turbines]] and [[Auxiliary Power Unit|magnetoplasmadynamic electrical generators]] produce more power, and more thermal energy is immediately available for manoeuvring, but thrusters will wear out faster and turbines may experience galling, reducing their long-term effectiveness.

If a reactor reaches its failure temperature and continues to heat up, the core will lose structural integrity and experience an explosive meltdown, destroying the ship it's attached to and releasing radioactive materials into the environment. Some eagle-eyed pilots you encounter are able to detect the residues these materials leave on nearby [[ringroids]], which is often indicative of [[Ganymedean Anarchy|pirate activity]].

{{#invoke:Equipment|list|Reactor Core
|caption=Reactor Cores
|Name|Manufacturer
|Operating Temperature | Failure Point | Thermal Power
|Mass|Price}}

[[Category:Equipment]]

Module:Equipment/Data

2024-06-18T21:42:06Z

Spdx-dv: price correction on 8x SO6

local equipment = {
Hardpoint = {
['EMD-14 mass driver'] = {
title = 'EMD-14 Mass Driver',
price = 10000,
powerConsumptionPeak = 750,
projectileMass = 10,
projectileVelocity = 4500,
rateOfFire = 2,
mass = 3000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['MPI Railgun MkI'] = {
title = 'MPI Railgun Mk I',
price = 20000,
powerConsumptionPeak = 800,
projectileMass = 2,
projectileVelocity = 7500,
rateOfFire = 10,
mass = 2000,
manufacturer = 'Nars Power Industries',
mounting = {'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['ERFMD-17 mass driver'] = {
title = 'ERFMD-17 Mass Driver',
price = 30000,
powerConsumptionPeak = 500,
projectileMass = 10,
projectileVelocity = 3000,
rateOfFire = 5,
mass = 5000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['AEMD-14 mass driver'] = {
title = 'AEMD-14 Mass Driver',
price = 32000,
powerConsumptionPeak = 750,
projectileMass = 10,
gimbalSpeed = 36,
projectileVelocity = 4500,
rateOfFire = 2,
mass = 3000,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Projectile'},
damage = {'Kinetic'}
},
['AR-1500 Manipulator'] = {
price = 56000,
armStrength = 1500,
reach = 40,
powerDrawPeak = 180,
mounting = {'High-Stress'},
mass = 8000,
manufacturer = 'Triskelion-Armstrong'
},
['MWG microwave emitter'] = {
price = 70000,
effectiveRange = 600,
powerConsumption = 50,
outputPower = 45,
wavelength = 10000000,
mass = 100,
manufacturer = 'Nakamura Dynamics',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Electromagnetic'}
},
['EINAT Kzinti Lesson MkII'] = {
title = 'EINAT Kzinti Lesson Mk II',
price = 100000,
effectiveRange = 100,
powerConsumption = 200,
thermalConsumption = 18.4,
outputPower = 18400,
mounting = {'High-Stress'},
mass = 2750,
manufacturer = 'Elon Interstellar',
categories = {'Energy'},
damage = {'Kinetic', 'Thermal'}
},
['CL-150 mining laser'] = {
price = 150000,
effectiveRange = 8000,
powerConsumption = 150,
outputPower = 125,
wavelength = 490,
mass = 4000,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal'}
},
['Point Defence microwave emitter'] = {
price = 180000,
effectiveRange = 600,
targetingAI = 'Class-1',
powerConsumption = 50,
outputPower = 45,
wavelength = 10000000,
mass = 1600,
manufacturer = 'Obonto-Nakamura',
mounting = {'Docking bay', 'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Electromagnetic'}
},
['CL-200AP pulse mining laser'] = {
price = 200000,
effectiveRange = 8000,
powerConsumption = 220,
gimbalSpeed = 36,
outputPower = 200,
pulses = 24,
wavelength = 650,
mass = 5500,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Kinetic'}
},
['MPI Tug drones'] = {
price = 250000,
powerDraw = 50,
effectiveRange = 400,
droneLaunchCapability = 50,
droneWetMass = 0.1,
droneThrust = 1,
mass = 4000,
manufacturer = 'Mars Power Industries',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['NANI'] = {
price = 300000,
effectiveRange = 1000,
powerConsumption = 200,
thermalConsumption = 2,
outputPower = 230000,
mounting = {'High-Stress'},
mass = 10000,
manufacturer = 'Omaewamou-Shindeiru',
categories = {'Energy'},
damage = {'Kinetic', 'Thermal'}
},
['CL-600P pulse mining laser'] = {
price = 320000,
effectiveRange = 8000,
powerConsumption = 660,
outputPower = 600,
pulses = 12,
wavelength = 540,
mass = 7000,
manufacturer = 'Coherent Light',
mounting = {'Low-Stress', 'High-Stress'},
categories = {'Energy'},
damage = {'Thermal', 'Kinetic'}
},
['MLF Haul Drones'] = {
price = 350000,
powerDraw = 50,
effectiveRange = 400,
droneLaunchCapability = 50,
droneWetMass = 0.1,
droneThrust = 1,
mass = 4000,
manufacturer = 'Minding LF',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['OME Maintenance Drones'] = {
price = 400000,
powerDraw = 50,
droneLaunchCapability = 32,
mass = 4000,
manufacturer = 'Obonto Micro Engineering',
mounting = {'Docking bay', 'Drone', 'Low-Stress', 'High-Stress'}
},
['External Impact Absorber'] = {
price = 4000,
mass = 8000,
cradleMass = 500,
manufacturer = 'Conlido RVM',
mounting = {'Low-Stress'}
},
['B8 Claim Beacon'] = {
price = 43000,
dryMass = 8000,
propellant = 8000,
autonomyClass = 'C1',
cradleMass = 500,
manufacturer = 'Triskelion-Armstrong',
mounting = {'Docking bay', 'Low-Stress'}
},
['THI Cargo Container'] = {
price = 74000,
processedCargoCapacity = 15000,
powerUsage = 20,
cradleMass = 500,
manufacturer = 'Titan Heavy Industries',
mounting = {'Docking bay', 'Low-Stress'},
categories = {'Cargo'}
},
['THI Monocargo Container'] = {
price = 111000,
processedCargoCapacitySingle = 90000,
powerUsage = 20,
cradleMass = 500,
manufacturer = 'Titan Heavy Industries',
mounting = {'Docking bay', 'Low-Stress'},
categories = {'Cargo'}
},
['NT Mining Companion'] = {
price = 115000,
autonomyClass = 'C2',
powerUsage = 10,
cradleMass = 500,
manufacturer = 'Nakamura-Titan',
mounting = {'Docking bay', 'Low-Stress'}
},
['SPC Gungnir'] = {
price = 270000,
powerConsumption = 400,
maximumCharge = 11.2,
fullChargeTime = 30,
projectileVelocity = 298805,
projectileMass = 0.000000011,
mounting = {'Low-Stress'},
mass = 15000,
manufacturer = 'Omaewamou-Shindeiru',
categories = {'Projectile'},
damage = {'Kinetic', 'Thermal', 'Electromagnetic'}
}
},
['Kinetic Ammunition'] = {
['Projectile magazine'] = {
price = 5000,
storage = 1000,
delivery = 100,
manufacturer = 'Conlido RVM'
},
['Dual projectile magazine'] = {
price = 10000,
storage = 2000,
delivery = 200,
manufacturer = 'Conlido RVM'
},
['Heavy projectile magazine'] = {
price = 25000,
storage = 5000,
delivery = 200,
manufacturer = 'Tetsuo Engineering'
},
['Military projectile magazine'] = {
price = 50000,
storage = 10000,
delivery = 200,
manufacturer = 'Nakamura Dynamics'
},
['Frigate-class projectile magazine'] = {
price = 100000,
storage = 20000,
delivery = 500,
manufacturer = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
['Destroyer-class projectile magazine'] = {
price = 250000,
storage = 50000,
projectileDelivery = 500,
delivery = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
},
['Nanodrone Components'] = {
['Basic nanodrone storage'] = {
price = 20000,
storage = 1000,
delivery = 20,
manufacturer = 'Mars Power Industries'
},
['Industrial nanodrone storage'] = {
price = 120000,
storage = 5000,
delivery = 20,
manufacturer = 'Conlido RVM',
},
['Military nanodrone storage'] = {
price = 250000,
storage = 10000,
delivery = 100,
manufacturer = 'Nakamura Dynamics',
},
['Harvester-class nanodrone storage'] = {
price = 500000,
storage = 20000,
delivery = 100,
manufacturer = 'Nakamura Dynamics',
exclusiveTo = {'K225', 'OCP-209'}
},
['Station-class nanodrone storage'] = {
price = 1250000,
storage = 50000,
delivery = 100,
manufacturer = 'Obonto Microengineering',
exclusiveTo = {'K225', 'OCP-209'}
},
},
['Propellant Tanks'] = {
['Short-range propellant tank'] = {
price = 6000,
storage = 15000
},
['Standard propellant tank'] = {
price = 12000,
storage = 30000
},
['Extended propellant tank'] = {
price = 20000,
storage = 50000
},
['Long-range propellant tank'] = {
price = 32000,
storage = 80000
},
['Interplanetary propellant tank'] = {
price = 160000,
storage = 200000
},
['Freighter propellant tank'] = {
price = 400000,
storage = 500000,
exclusiveTo = {'K225', 'OCP-209'}
}
},
['Reaction Control System'] = {
['NDSTR thruster'] = {
price = 1250,
thrust = 600,
exhaustVelocity = 7,
propellantConsumption = 85.7,
powerConsumption = 1,
thermalConsumption = 2.1,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 20,
manufacturer = 'Nakamura Dynamics',
},
['NDVTT thruster'] = {
price = 2500,
thrust = 500,
exhaustVelocity = 7,
propellantConsumption = 71.4,
powerConsumption = 1,
thermalConsumption = 1.8,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 30,
manufacturer = 'Nakamura Dynamics',
},
['RA-K37 thruster'] = {
price = 3125,
thrust = 200,
exhaustVelocity = 15,
propellantConsumption = 13.3,
powerConsumption = 5,
thermalConsumption = 1.5,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 70,
manufacturer = 'Rusatom-Antonoff',
},
['MA150HO thruster'] = {
price = 4375,
thrust = 150,
exhaustVelocity = 30,
propellantConsumption = 5,
powerConsumption = 40,
thermalConsumption = 2.3,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 80,
manufacturer = 'Mitsudaya-Starbus',
},
['RA-K44 thruster'] = {
price = 6250,
thrust = 400,
exhaustVelocity = 15,
propellantConsumption = 26.6,
powerConsumption = 15,
thermalConsumption = 1.5,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 75,
manufacturer = 'Rusatom-Antonoff',
},
['Elon Interstellar Ion Thruster'] = {
price = 8000,
thrust = 120,
exhaustVelocity = 50,
propellantConsumption = 2.4,
powerConsumption = 40,
thermalConsumption = 3,
operationMode = 'Variable thrust',
propellant = 'Hydrogen plasma',
mass = 90,
manufacturer = 'Elon Interstellar',
},
['ERS-NAGHET 5020'] = {
price = 8500,
thrust = 210,
exhaustVelocity = 27,
propellantConsumption = 7.8,
powerConsumption = 50,
thermalConsumption = 2.8,
operationMode = 'Variable thrust',
gimbalAngle = 20,
gimbalSpeed = 360,
propellant = 'Oxygen-Hydrogen plasma',
mass = 130,
manufacturer = 'Electo Ride Systems',
},
['MA350HO thruster'] = {
price = 10000,
thrust = 350,
exhaustVelocity = 25,
propellantConsumption = 14,
powerConsumption = 60,
thermalConsumption = 4.4,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 120,
manufacturer = 'Mitsudaya-Starbus',
},
['Elon Interstellar AGILE Thruster'] = {
price = 12000,
thrust = 120,
exhaustVelocity = 40,
propellantConsumption = 3,
powerConsumption = 60,
thermalConsumption = 2.5,
operationMode = 'Variable thrust',
gimbalAngle = 35,
gimbalSpeed = 160,
propellant = 'Hydrogen plasma',
mass = 120,
manufacturer = 'Elon Interstellar',
},
['RA-K69V thruster'] = {
price = 6250,
thrust = 400,
exhaustVelocity = 12,
propellantConsumption = 33.3,
powerConsumption = 25,
thermalConsumption = 3.6,
operationMode = 'Pulsed thrust',
gimbalAngle = 25,
gimbalSpeed = 540,
propellant = 'Oxygen-Hydrogen plasma',
mass = 150,
manufacturer = 'Rusatom-Antonoff',
categories = {'Racing'}
},
},
['Main Propulsion'] = {
['ND-PNTR engine'] = {
price = 7000,
thrust = 1500,
exhaustVelocity = 8,
propellantConsumption = 187.5,
powerConsumption = 180,
thermalConsumption = 6,
vectoredThrustAngle = 90,
operationMode = 'Pulsed thrust',
responseTime = 2.1,
propellant = 'Oxygen-Hydrogen plasma',
mass = 450,
manufacturer = 'Nakamura Dynamics',
other = 'Vectored thrust (90°)',
},
['RA-TNTRL-K37 engine'] = {
price = 15000,
thrust = 750,
exhaustVelocity = 15,
propellantConsumption = 50,
powerConsumption = 100,
thermalConsumption = 5.6,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 1250,
manufacturer = 'Rusatom-Antonoff',
},
['ND-NTTR thruster'] = {
price = 30000,
thrust = 3500,
exhaustVelocity = 7,
propellantConsumption = 500,
powerConsumption = 20,
thermalConsumption = 12.2,
operationMode = 'Variable thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 650,
manufacturer = 'Nakamura Dynamics',
},
['RA-MHFTR-K44 engine'] = {
price = 40000,
thrust = 1500,
exhaustVelocity = 18,
propellantConsumption = 83.3,
powerConsumption = 100,
thermalConsumption = 13.5,
gimbalAngle = 9,
gimbalSpeed = 36,
operationMode = 'Pulsed thrust',
propellant = 'Oxygen-Hydrogen plasma',
mass = 1650,
manufacturer = 'Rusatom-Antonoff',
other = 'Gimbaled (9°)',
},
['BWM-T535'] = {
price = 120000,
thrust = 535,
exhaustVelocity = 29,
propellantConsumption = 18.4,
powerConsumption = 0.040,
thermalConsumption = 8.2,
operationMode = 'Variable thrust',
responseTime = 0.9,
propellant = 'Oxygen-Hydrogen plasma',
mass = 2000,
manufacturer = 'BWM',
other = 'Integrated turbine',
},
['ERS-DFMHD-2205'] = {
price = 175000,
thrust = 2200,
exhaustVelocity = 14,
propellantConsumption = 157.1,
powerConsumption = 120,
thermalConsumption = 15.4,
operationMode = 'Variable thrust',
responseTime = 0.6,
propellant = 'Oxygen-Hydrogen plasma',
mass = 2450,
manufacturer = 'Electro Ride Systems',
},
['MA-NMPD42 engine'] = {
price = 300000,
thrust = 320,
exhaustVelocity = 115,
propellantConsumption = 2.8,
powerConsumption = 150,
thermalConsumption = 18.4,
operationMode = 'Variable thrust',
propellant = 'Hydrogen plasma',
mass = 1850,
manufacturer = 'Mitsudaya-Starbus',
},
['Experimental NPMP engine'] = {
price = 700000,
thrust = 1100,
exhaustVelocity = 45,
propellantConsumption = 24.4,
powerConsumption = 200,
thermalConsumption = 24.7,
operationMode = 'Pulsed thrust',
propellant = 'Hydrogen plasma',
mass = 2750,
manufacturer = 'Elon Interstellar',
},
['Z-Axial Pinch fusion torch'] = {
price = 1000000,
thrust = 800,
exhaustVelocity = 1250,
propellantConsumption = 0.6,
ignitionConsumption = 150,
operationMode = 'Variable thrust',
gimbalAngle = 30,
gimbalSpeed = 28,
propellant = 'Hydrogen plasma',
fusionFuel = '3He-D',
burnTime = 30,
mass = 3000,
manufacturer = 'Elon Interstellar',
other = 'Gimbaled (30°), fusion drive with 30min burn time',
},
},
['Reactor Core'] = {
['4x SO6 fuel rod'] = {
price = 80000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 2000,
thermalPower = 4,
manufacturer = 'Rusatom-Antonoff'
},
['8x SO6 fuel rod'] = {
price = 160000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 4000,
thermalPower = 8,
manufacturer = 'Rusatom-Antonoff'
},
['12x SO6 fuel rod'] = {
price = 240000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 6000,
thermalPower = 12,
manufacturer = 'Rusatom-Antonoff'
},
['16x SO6 fuel rod'] = {
price = 320000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 8000,
thermalPower = 16,
manufacturer = 'Rusatom-Antonoff'
},
['20x SO6 fuel rod'] = {
price = 400000,
operatingTemperature = 3500,
failureTemperature = 4500,
mass = 10000,
thermalPower = 20,
manufacturer = 'Rusatom-Antonoff'
},
['Nakamura Dynamics Yama-SSR12'] = {
price = 750000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 5000,
thermalPower = 30,
manufacturer = 'Nakamura Dynamics'
},
['Nakamura Dynamics Yama-SSR16'] = {
price = 1000000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 5500,
thermalPower = 40,
manufacturer = 'Nakamura Dynamics'
},
['Nakamura Dynamics Yama-SSR16S'] = {
price = 1500000,
operatingTemperature = 3000,
failureTemperature = 4500,
mass = 6000,
thermalPower = 50,
manufacturer = 'Nakamura Dynamics',
categories = {'Racing'}
},
},
['Ultracapacitor Array'] = {
['Ultracapacitor'] = {
price = 25000,
energyCapacity = 500,
peakPower = 10,
mass = 2000,
manufacturer = 'Obonto Micro Engineering'
},
['Dual Ultracapacitor'] = {
price = 55000,
energyCapacity = 1000,
peakPower = 10,
mass = 4000,
manufacturer = 'Obonto Micro Engineering'
},
['Triple Ultracapacitor'] = {
price = 90000,
energyCapacity = 1500,
peakPower = 10,
mass = 6000,
manufacturer = 'Obonto Micro Engineering'
},
},
['Powerplant'] = {
['Turbine'] = {
price = 30000,
power = 100,
propellantConsumption = 0.1,
mass = 500,
manufacturer = 'Rusatom-Antonoff'
},
['Twin Turbine'] = {
price = 60000,
power = 200,
propellantConsumption = 0.2,
mass = 1000,
manufacturer = 'Rusatom-Antonoff'
},
['Military-Grade Turbine'] = {
price = 150000,
power = 500,
propellantConsumption = 0.5,
mass = 5000,
manufacturer = 'Rusatom-Antonoff'
}
},
['Auxiliary Power System'] = {
['MPD5035'] = {
price = 300000,
powerConsumption = 50,
thermalConsumption = 0.5,
power = 350,
mass = 2500,
apsType = 'MPDG',
manufacturer = 'Mitsudaya-Starbus',
categories = {'MPDG'}
},
['EIPFG MkIV Big Furnace Generator'] = {
price = 500000,
powerConsumption = 100,
thermalConsumption = 1,
power = 700,
mass = 4000,
apsType = 'MPDG',
manufacturer = 'Elon Interstellar',
categories = {'MPDG'}
},
['MPI Town-class MPDG'] = {
price = 800000,
powerConsumption = 150,
thermalConsumption = 1.5,
power = 1000,
mass = 8000,
apsType = 'MPDG',
manufacturer = 'Mars Power Industries',
categories = {'MPDG'}
},
['NDAPS'] = {
price = 400000,
energyCapacity = 18000,
chargePower = 100,
dischargePower = 3000,
mass = 1000,
apsType = 'SMES',
manufacturer = 'Nakamura Dynamics',
categories = {'SMES'}
},
['MPI Town-class storage'] = {
price = 800000,
energyCapacity = 32000,
chargePower = 150,
dischargePower = 3000,
mass = 2000,
apsType = 'SMES',
manufacturer = 'Mars Power Industries',
categories = {'SMES'}
},
['EIUP MkII Unlimited Power'] = {
price = 1200000,
energyCapacity = 50000,
chargePower = 200,
dischargePower = 6000,
mass = 3500,
apsType = 'SMES',
manufacturer = 'Elon Interstellar',
categories = {'SMES'}
}
},
['Cargo Bay'] = {
['Standard cargo bay'] = {
price = 0
},
['Cargo bay baffles'] = {
price = 2000
},
['Rusatom-Antonoff MPU'] = {
price = 350000,
processingCapacity = 20,
processingPower = 2,
mineralProcessingEfficiency = 40,
remassProcessingEfficiency = 40,
mass = 1700,
manufacturer = 'Rusatom-Antonoff',
categories = {'MPU'}
},
['Nakamura MPU'] = {
price = 500000,
processingCapacity = 50,
processingPower = 25,
mineralProcessingEfficiency = 70,
remassProcessingEfficiency = 30,
mass = 4200,
manufacturer = 'Nakamura Dynamics',
categories = {'MPU'}
},
['Mitsudaya Starbus MSU'] = {
price = 900000,
processingCapacity = 100,
processingPower = 150,
mineralProcessingEfficiency = 90,
mass = 2500,
manufacturer = 'Mitsudaya-Starbus',
categories = {'MPU'}
},
['Voyager RSLS Fabrication Plant'] = {
price = 1500000,
processingCapacity = 40,
processingPower = 20,
powerConsumption = 70,
mineralProcessingEfficiency = 50,
remassProcessingEfficiency = 60,
mass = 6000,
manufacturer = 'Nakamura-Obonto',
categories = {'MPU'}
},
},
['Autopilot'] = {
['MLF Autopilot'] = {
price = 10000,
manufacturer = 'Minding LF',
arl = true,
autopilotCapabilities = {
'LIDAR highlight'
}
},
['MA-337 Autopilot'] = {
price = 27000,
manufacturer = 'Mitsudaya-Starbus',
arl = true,
aat = true,
autopilotCapabilities = {
'LIDAR overlay'
}
},
['NDCI Autopilot'] = {
price = 60000,
manufacturer = 'Nakamura Dynamics',
rtc = true,
fbw = true,
autopilotCapabilities = {
'Firing solutions',
'Collision warnings'
}
},
['ER-42 Autopilot'] = {
price = 100000,
manufacturer = 'Electro Ride Systems',
arl = true,
aat = true,
rtc = true,
fbw = true,
autopilotCapabilities = {
'Trajectory prediction'
}
},
['EIAA-1337 Autopilot'] = {
price = 150000,
manufacturer = 'Elon Interstellar',
arl = true,
aat = true,
rtc = true,
fbw = true,
autopilotCapabilities = {
'Autonomic'
}
}
},
['Head-Up Display'] = {
['HAL9000'] = {
price = 500
},
['Eagle Prospector'] = {
price = 3000
},
['K37 TNTRL'] = {
price = 4000
},
['AT-K225'] = {
price = 6000
},
['Eagle Prospector (metric mod)'] = {
price = 10000
},
['OCP-209'] = {
price = 15000,
},
['Elon Interstellar Model E'] = {
price = 25000,
},
['Bald Eagle Racing HUD'] = {
price = 50000,
categories = {'Racing'}
}
},
['Reconnaissance Craft'] = {
['Obonto USV-R'] = {
price = 10000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5
},
['Runasimi Gravimetric USV'] = {
price = 40000,
manufacturer = 'Runasimi Inc.',
reconRange = 5,
reconCapability = 'Gravitational map',
},
['Obonto USV-D Microseismic Series'] = {
price = 60000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5,
reconCapability = 'Ore identification',
},
['Obonto USV-GOT'] = {
price = 200000,
manufacturer = 'Obonto Micro Engineering',
reconRange = 5,
reconCapability = 'Drone priority queue',
}
}
}

local hardpointTypes = {
['High-Stress'] = 'highStress',
['Low-Stress'] = 'lowStress',
['Drone'] = 'droneHardpoint',
['Docking bay'] = 'dockingBay'
}

local categories = {}
local addCategory = function(cats, cat, item)
cats[cat] = cats[cat] or {}
table.insert(cats[cat], item)
end

for equipmentType,items in pairs(equipment) do
for name,item in pairs(items) do
item.equipmentType = equipmentType
item.name = item.name or name

for i,hardpointType in ipairs(item.mounting or {}) do
if hardpointTypes[hardpointType] then
item[hardpointTypes[hardpointType]] = true
end

addCategory(categories, hardpointType, item)
end

if item.highStress and not item.lowStress then
addCategory(categories, 'High-Stress only', item)
end
if item.lowStress and not item.dockingBay then
addCategory(categories, 'Low-Stress required', item)
end
if item.dockingBay and not item.droneHardpoint then
addCategory(categories, 'Docking bay required', item)
end

for i,category in ipairs(item.categories or {}) do
addCategory(categories, category, item)
end
end
end

for k,items in pairs(categories) do
equipment[k] = items
end

for name,item in pairs(equipment['Head-Up Display']) do
item.title = item.title or ('Head-Up Display#' .. item.name)
end

return equipment

Nuclear propulsion

2024-06-18T07:56:24Z

Spdx-dv: minor correction for readability

<blockquote>''For a breakdown of main torch specifications, see [[Main Propulsion]]. For RCS thruster specifications, see [[Reaction Control System]].''</blockquote>Nuclear propulsion generally converts the heat energy of [[fission]] into kinetic energy by flowing propellant through a [[Reactor Core|reactor core]]. The propellant expands and plasmafies, then can be further accelerated by other devices such as magnetoplasmadynamic accelerators before exiting the spacecraft through a thruster nozzle at high speed.

Counterintuitively, thrusters with high efficiencies and low propellant flow tend to use more reactor heat than less efficient thrusters. This is because heat usage is less dependent on propellant flow and moreso on [[exhaust velocity]]; efficient thrusters need to accelerate the propellant to higher speeds before it leaves the nozzle, so they draw more heat from the reactor to do so.

== Nuclear Thermal Engines ==
Nuclear thermal engines directly turn fission's heat energy into kinetic energy by exhausting reactor-heated propellant out of a nozzle. They are the simplest kind of nuclear propulsion, and the cheapest to procure and maintain.

Nuclear thermal engines achieve better thrust per unit mass than other modes of nuclear propulsion, but are much less efficient on account of their low exhaust velocities.

== Nuclear-Assisted Magnetoplasmadynamic Engines ==
Nuclear-assisted magnetoplasmadynamic (MPD) engines have one or more stages after the propellant exits the reactor. These stages use superconducting electromagnets to further excite and accelerate the plasma before it leaves the nozzle.

Engines utilising MPD technology offer good efficiency and thrust at the expense of electrical power, with the one exception being the BWM-T535 and its integrated turbine and generator, and thermal consumption.

The technology is extended by [[Auxiliary Power Unit|closed-cycle MPD electrical generators]] commonly used in colony infrastructure and large spacecraft.

=== Magnetohydrodynamic Engines ===
Nuclear-assisted magnetohydrodynamic (MHD) engines employ the same fundamental principles as their plasma-focused counterparts, but instead treat the plasma flowing through them as a unified body that is influenced by a moving magnetic field. Higher propellant flow, and thus greater thrust, can therefore be achieved with minimal efficiency losses compared to MPD engines.

== Ion Thruster ==
Ion thrusters use copious amounts of electrical energy to strip the electrons from atoms, creating ions that can then be accelerated to remarkable exhaust velocities. Generally, they are either electrostatic, accelerating propellant through the Coulomb force along the direction of an electric field, or electromagnetic, accelerating propellant through the Lorentz force along the direction of a magnetic field.

Their high efficiency is offset by their low thrust, per-unit mass, and power consumption.

== Fusion Engines ==
Fusion engines are a largely-theoretical type of engine that has only recently seen adoption with the introduction of [[Corporations#Elon Interstellar|Elon Interstellar's]] proprietary "ZAP" torch. By confining fusion inside some means of containment, propellant and fusion products can be accelerated to astronomical velocities with equal efficiency.

Fusion engines offer better efficiency than any other type of nuclear propulsion system, but are markedly fragile and require massive amounts of power to ignite.

=== Z-Pinch ===
The Z-Axial Pinch fusion torch works on the basis of Z-pinch inertial confinement fusion. Fusion fuel is held within a glob of plasma, which is then simultaneously imploded and inductively heated by a powerful magnetic field, triggering fusion and creating a long, narrow line of fusing plasma known as a filament.

Z-pinch fusion is notoriously prone to kink instability, where slight peturbations in the shape of the filament result in exponential destabilisation and cessation of the fusion reaction. This issue is resolved in the ZAP through use of sheared-flow stabilisation. Propellant plasma is introduced to the filament, creating rapidly-flowing annular layers that continuously maintain the filament's form.
[[Category:Codex]]

Nuclear Thermal Rocket

2024-06-18T07:53:57Z

Spdx-dv: added redirect

#REDIRECT [[Nuclear propulsion#Nuclear%20thermal%20engines]]

====== Nuclear Thermal Rocket ======

Thermal Rockets work by heating up [[propellant]] in reactor core, vaporizing it and giving it both high temperature and velocity - and ejecting it behind the [[spaceship]], propelling it forward. Nuclear Thermal Rockets use nuclear reactor to produce heat. While they consume fissile material when operating, typical nuclear reactor can [[burn]] for months to years before refuel becomes the issue.

Counter intuitively, heating up propellant will cool down the [[reactor]]. Most reactors are designed to compensate for that by speeding up the [[codex:fission]] by speeding up the [[fission]]. Damage to [[reactor]] might lead to slower response and higher temperature fluctuations, resulting with both [[overcooling]] and [[overheating]].

While powerful, easy to operate and maintain, Nuclear Thermal Rockets have poor [[propellant economy]] due to low [[codex:exhaust velocity]] and [[specific impulse]]s.

[[Category:Codex]]

Nuclear propulsion

2024-06-17T22:23:18Z

Spdx-dv: initial creation

<blockquote>''For a breakdown of main torch specifications, see [[Main Propulsion]]. For RCS thruster specifications, see [[Reaction Control System]].''</blockquote>Nuclear propulsion generally utilises the heat energy of [[fission]] into kinetic energy by flowing propellant through a [[Reactor Core|reactor core]]. The propellant expands and plasmafies, then can be further accelerated by other devices such as magnetoplasmadynamic accelerators before exiting the spacecraft through a thruster nozzle at high speed.

Counterintuitively, thrusters with high efficiencies and low propellant flow tend to use more reactor heat than less efficient thrusters. This is because heat usage is less dependent on propellant flow and moreso on [[exhaust velocity]]; efficient thrusters need to accelerate the propellant to higher speeds before it leaves the nozzle, so they draw more heat from the reactor to do so.

== Nuclear Thermal Engines ==
Nuclear thermal engines directly turn fission's heat energy into kinetic energy by exhausting reactor-heated propellant out of a nozzle. They are the simplest kind of nuclear propulsion, and the cheapest to procure and maintain.

Nuclear thermal engines achieve better thrust per unit mass than other modes of nuclear propulsion, but are much less efficient on account of their low exhaust velocities.

== Nuclear-Assisted Magnetoplasmadynamic Engines ==
Nuclear-assisted magnetoplasmadynamic (MPD) engines have one or more stages after the propellant exits the reactor. These stages use superconducting electromagnets to further excite and accelerate the plasma before it leaves the nozzle.

Engines utilising MPD technology offer good efficiency and thrust at the expense of electrical power, with the one exception being the BWM-T535 and its integrated turbine and generator, and thermal consumption.

The technology is extended by [[Auxiliary Power Unit|closed-cycle MPD electrical generators]] commonly used in colony infrastructure and large spacecraft.

=== Magnetohydrodynamic Engines ===
Nuclear-assisted magnetohydrodynamic (MHD) engines employ the same fundamental principles as their plasma-focused counterparts, but instead treat the plasma flowing through them as a unified body that is influenced by a moving magnetic field. Higher propellant flow, and thus greater thrust, can therefore be achieved with minimal efficiency losses compared to MPD engines.

== Ion Thruster ==
Ion thrusters use copious amounts of electrical energy to strip the electrons from atoms, creating ions that can then be accelerated to remarkable exhaust velocities. Generally, they are either electrostatic, accelerating propellant through the Coulomb force along the direction of an electric field, or electromagnetic, accelerating propellant through the Lorentz force along the direction of a magnetic field.

Their high efficiency is offset by their low thrust, per-unit mass, and power consumption.

== Fusion Engines ==
Fusion engines are a largely-theoretical type of engine that has only recently seen adoption with the introduction of [[Corporations#Elon Interstellar|Elon Interstellar's]] proprietary "ZAP" torch. By confining fusion inside some means of containment, propellant and fusion products can be accelerated to astronomical velocities with equal efficiency.

Fusion engines offer better efficiency than any other type of nuclear propulsion system, but are markedly fragile and require massive amounts of power to ignite.

=== Z-Pinch ===
The Z-Axial Pinch fusion torch works on the basis of Z-pinch inertial confinement fusion. Fusion fuel is held within a glob of plasma, which is then simultaneously imploded and inductively heated by a powerful magnetic field, triggering fusion and creating a long, narrow line of fusing plasma known as a filament.

Z-pinch fusion is notoriously prone to kink instability, where slight peturbations in the shape of the filament result in exponential destabilisation and cessation of the fusion reaction. This issue is resolved in the ZAP through use of sheared-flow stabilisation. Propellant plasma is introduced to the filament, creating rapidly-flowing annular layers that continuously maintain the filament's form.
[[Category:Codex]]

Fission

2024-06-17T17:39:19Z

Spdx-dv: added part about longevity

When radioactive atoms decay or are hit by neutrons, they produce lighter elements and release energy in a process known as fission. Fission can produce large amounts of energy over a long period, which makes it an ideal heat source for [[Nuclear Thermal Rocket|nuclear thermal rockets]], where radioactive fuel is contained within a [[Reactor Core|reactor core]] and cooled by [[Propellant Tank|propellant]].

The heat produced by fission is also ideal in power generation, which can be done through the use of a [[Powerplant|turbine]] or [[Auxiliary Power Unit|magnetoplasmadynamic generator]].

== Fuel ==
Specific isotopes of elements such as uranium (in the case of the Yama-SSR series) and plutonium are the chosen fuel for nuclear reactors because they are fissile. While many radioactive isotopes are fissionable, meaning that they undergo fission when hit by neutrons of any energy level, fissile materials are especially responsive to low-energy "thermal" neutrons. Thermal neutrons are the result of high-energy neutrons scattering and losing energy in a moderator, which absorbs and dissipates their energy as heat.

Thorium may also be used (as is the case for the SO6 fuel rod series), but the most common isotope of thorium is not fissile; it is, however, fertile. When exposed to neutrons, fertile materials absorb them to create fissile materials, which can then undergo fission to produce energy.

Radioactive fuels last far longer than chemical fuels due to their incredible energy density. Fuel rods can operate continuously for months or even years before needing to be replaced, depending on how they're used.

== Controlling the Reaction ==
Fission can be controlled by adjusting the parameters of the reactor. Different approaches include:

* Control rods that absorb neutrons can be inserted between the fuel rods, reducing the amount of neutrons available to trigger fission.
* The fuel rods can be removed from the reactor, reducing the amount of fissile material for neutrons to hit.
* In liquid core reactors, the liquid fuel can be pumped away from the moderator, reducing the amount of thermal neutrons that can trigger fission.

[[Category:Codex]]

Fission

2024-06-17T17:19:08Z

Spdx-dv: rewrite with some cool science

When radioactive atoms decay or are hit by neutrons, they produce lighter elements and release energy in a process known as fission. Fission can produce large amounts of energy over a long period, which makes it an ideal heat source for [[Nuclear Thermal Rocket|nuclear thermal rockets]], where radioactive fuel is contained within a [[Reactor Core|reactor core]] and cooled by [[Propellant Tank|propellant]].

The heat produced by fission is also ideal in power generation, which can be done through the use of a [[Powerplant|turbine]] or [[Auxiliary Power Unit|magnetoplasmadynamic generator]].

== Fuel ==
Specific isotopes of elements such as uranium (in the case of the Yama-SSR series) and plutonium are the chosen fuel for nuclear reactors because they are fissile. While many radioactive isotopes are fissionable, meaning that they undergo fission when hit by neutrons of any energy level, fissile materials are especially responsive to low-energy "thermal" neutrons. Thermal neutrons are the result of high-energy neutrons scattering and losing energy in a moderator, which absorbs and dissipates their energy as heat.

Thorium may also be used (as is the case for the SO6 fuel rod series), but the most common isotope of thorium is not fissile; it is, however, fertile. When exposed to neutrons, fertile materials absorb them to create fissile materials, which can then undergo fission to produce energy.

== Controlling the Reaction ==
Fission can be controlled by adjusting the parameters of the reactor. Different approaches include:

* Control rods that absorb neutrons can be inserted between the fuel rods, reducing the amount of neutrons available to trigger fission.
* The fuel rods can be removed from the reactor, reducing the amount of fissile material for neutrons to hit.
* In liquid core reactors, the liquid fuel can be pumped away from the moderator, reducing the amount of thermal neutrons that can trigger fission.

[[Category:Codex]]

Main Page

2024-06-17T15:34:20Z

Spdx-dv: /* Browse... */ added Modding tab

__NOTOC__
=Welcome to the '''ΔV: Rings of Saturn''' Wiki=
[[file:Header.png|frame|center]]

= Browse... =
<p class="gamep">
[[:Category:Ships|Ships]]
[[:Category:Equipment |Equipment]]
[[:Category:Events |Events]]
[[Crew]]
[[:Category:Codex |Codex]]
[[Guides]]
[[FAQ|Frequently Asked Questions]]
[[Troubleshooting]] [[Modding]]
</p>

=== The year is 2273 ===
The unexpected discovery of valuable minerals within the rings of Saturn has sparked a thriving '''space excavation''' industry. You control an asteroid excavation ship hoping to make it rich out on the rings.

You take trips out to the rings to mine minerals by breaking up the "iceteroids". Different areas of the rings provide different gameplay, and they have some surprises in store...
Gameplay is focused on the top-down control of your ship in the asteroid field, featuring scientifically-accurate flying. An object in motion stays in motion!

Back at the base of Enceladus Prime, you can sell your minerals, upgrade and fine-tune your ship (or buy a new one!) and manage your crew and their morale.

The game places a large focus on realistic & science-backed simulation: Every sensor on your ship is simulated, from reactor control to your HUD readouts.

= Featured Article =

[[File:k37-tntrl.png|border|left|150px|The K-37, the ideal starter ship]]

[[Guides#Getting_Started|Guide: Getting Started]]

= Did You Know... =

...that tuning a thruster's output down won't increase its fuel efficiency?

...that Saturn's rings are about 1 kilometre thick?

==Editors Wanted!==
[[Getting Started with Editing]]

[[Tips & Tricks]]

= Links =
<div id="home-card-discord" class="home-card home-card--col2 home-card--button">[https://discord.gg/dv [[File:Discord wordmark white.svg|x30px|link=|alt=Discord]]]</div>

[https://store.steampowered.com/app/846030/V_Rings_of_Saturn/ [[File:Steam.svg|x30px|link=|alt=Steam]]]

Corporations

2024-06-16T16:21:39Z

Spdx-dv: quickly added sorting

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings. They are the presumed manufacturer of the nuclear-pumped XASER array that clears areas of the rings for miners.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering, but has recently lost influence in the market on account of their aging fleet.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamformed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable sortable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", the Mars-based Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
| +700 MW (100 MW + 1 GW thermal)
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|50,000 MJ (200 MW charge draw)
|3,500 kg
|-
|EIAA-1337 autopilot
|Semi-autonomous autopilot
|150,000 E$
|n/a
|n/a
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}

== Enceladus Corp. ==
The Enceladus Corporation is the local government of the massive O'Neill cylinder station Enceladus Prime, which orbits Enceladus. It holds an effective monopoly over all miners within the Saturnian system, as Enceladus is the only moon close enough to the rings for rapid cost-effective transit. In 2184, it was the focal point of the First Enceladian Gold Rush after an asteroid impacted the then-in-construction station, revealing an abundance of rare elements within the A-Ring.

While the corporation recognises the need for policing in the A-Ring on account of pirate activity, it does not have an active military, nor a wish to field one. The rule of law is instead enforced through the weregild system, where compensatory fines are issued to ships dependent on the severity of their transgressions. The Vilcy, an organised group of bounty hunters, have taken great interest in the system, and are the rings' de-facto police force.

Enceladus Corp. registers ships that operate in their region of space under the "SE1" designation.
{| class="wikitable sortable"
|+
!Service
!Type
!Cost
!Time
!Cooldown
!Benefit
|-
|Affordable Capsule Hotel
|Lodging
|100 E$ / person
|1 day
|n/a
|n/a
|-
|The Twins
|Recreational establishment
|400 E$ / person
|4 hours
|24 hours
|Slight crew morale increase
|-
|Moonview Capsule Hotel
|Lodging
|300 E$ / person
|1 day
|n/a
|Minor crew morale increase
|-
|The Underside Inn
|Long-term lodging
|3,500 E$ / person
|7 days
|n/a
|Moderate crew morale increase
|-
|Skydome Resort
|Recreational lodging
|5,000 E$ booking + 2,000 E$ / person
|3 days
|n/a
|Major crew morale increase
|-
|Jameson Insurance
|Repair insurance
|50,000 E$
|1 hour
|30 days
| +100,000 E$ insurance budget
|-
|Local Vilcy Branch
|Fine management
|60% total weregild
|1 hour
|n/a
|Clears Vilcy faction hostility
|-
|The Miner's Guild
|Fine management
|Varies, max 140,000 E$
|1 hour
|n/a
|Clears civilian faction hostility
|-
|Obonto Habitats
|Fine management
|Varies, max 320,000 E$
|1 hour
|n/a
|Clears Obonto faction hostility
|}

== Mars Power Industries ==
Mars Power Industries is a Mars-based corporation whose tagline is "Bringing Light Where Darkness Reigns". Their main focus is in the development of industrial infrastructure for Martian colonies, such as power generation and resource extraction.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|MPI Railgun MkI
|Railgun
|20,000 E$
|800 MW
|2,000 kg
|-
|MPI Tug drones
|Disposable nanodrone assembler and launcher
|250,000 E$
|50 MW
|4,000 kg
|-
|Basic nanodrone storage
|Nanodrone component storage
|20,000 E$
|n/a
|1,000 kg (storage)
|-
|MPI Town-class MPDG
|Magnetoplasmadynamic electrical generator
|800,000 E$
| +1000 MW (150 MW + 1.5 GW thermal)
|8,000 kg
|-
|MPI Town-class storage
|Superconducting magnetic energy storage
|800,000 E$
|32,000 MJ (150 MW charge draw)
|2,000 kg
|}

== Minding LF ==
Minding LF specialises in simulation and statistical analysis, and provide the Virtual Flight Service available in the Dealer.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass`
|-
|MLF long-wave RADAR
|Ice-penetrating ranging RADAR
|5,000 E$
|n/a
|n/a
|-
|MLF autopilot
|Basic autopilot: ARL, LIDAR highlight
|10,000 E$
|n/a
|n/a
|-
|MLF Haul drones
|Disposable nanodrone assembler and launcher
|350,000 E$
|50 MW
|4,000 kg
|}

== Mitsudaya-Starbus ==
Mitsudaya-Starbus is a relatively recent player in the advanced propulsion systems and spacecraft market, only having formed within the last 50 years from a merger between Japanese conglomerate Mitsudaya Group and European aerospace manufacturer Starbus. Their Prospector line, manufactured for the Free States of Earth, is prized in the outer solar system for both its utility and agility as mining vessels.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|MA150HO thruster
|Nuclear thermal magnetoplasmadynamic thruster
|4,375 E$
|40 MW
|80 kg
|-
|MA350HO thruster
|Nuclear thermal magnetoplasmadynamic thruster
|10,000 E$
|60 MW
|120 kg
|-
|MA-NMPD42 engine
|Nuclear thermal magnetoplasmadynamic thruster
|300,000 E$
|150 MW + 18.4 GW thermal
|1,850 kg
|-
|Mitsudaya-Starbus MSU
|Mineral processing unit
|900,000 E$
|150 MW / chunk
|2,500 kg
|-
|MPD5035
|Magnetoplasmadynamic electrical generator
|300,000 E$
| +350 MW (50 MW + 0.5 GW thermal)
|2,500 kg
|}
{| class="wikitable sortable"
|+
!Ship name
!Type
!Dry mass
|-
|Eagle Prospector
|Mining clipper
|27,500 kg
|-
|Vulture Prospector
|Utility clipper
|37,500 kg
|-
|Peacock Prospector
|Luxury clipper
|27,500 kg
|-
|Pelican Prospector
|Mining barge
|62,000 kg
|}

== Nakamura Dynamics ==
Nakamura Dynamics is the largest military contractor in the solar system, and offers a range of advanced technologies to the civilian market.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|NDVTT thruster
|Nuclear thermal thruster
|2,500 E$
|1 MW + 1.8 GW thermal
|30 kg
|-
|NDSTR thruster
|Pulsed nuclear thermal thruster
|1,250 E$
|1 MW + 2.1 GW thermal
|20 kg
|-
|ND-NTTR engine
|Nuclear thermal thruster
|30,000 E$
|20 MW + 12.2 GW thermal
|650 kg
|-
|ND-PNTR engine
|Pulsed nuclear thermal thruster
|7,000 E$
|180 MW + 6 GW thermal
|450 kg
|-
|MWG microwave emitter
|1 cm microwave emitter
|70,000 E$
|50 MW
|100 kg
|-
|Point defence microwave generator
|Automatic swivel-mount 1 cm microwave emitter
|180,000 E$
|50 MW
|1,600 kg
|-
|NDPT-4205 point defence turret
|Semi-automatic swivel-mount railgun
|135,000 E$
|400 MW
|2,500 kg
|-
|NT Mining Companion
|Automated mining drone
|115,000 E$
|10 MW
|4,500 kg (approx)
|-
|Military projectile magazine
|Ammunition storage
|50,000 E$
|n/a
|10,000 kg (storage)
|-
|Frigate-class projectile magazine
|Ammunition storage
|100,000 E$
|n/a
|20,000 kg (storage)
|-
|Destroyer-class projectile magazine
|Ammunition storage
|250,000 E$
|n/a
|50,000 kg (storage)
|-
|Military nanodrone storage
|Nanodrone component storage
|250,000 E$
|n/a
|10,000 kg (storage)
|-
|Station-class nanodrone storage
|Nanodrone component storage
|1,250,000 E$
|n/a
|50,000 kg (storage)
|-
|Harvester-class nanodrone storage
|Nanodrone component storage
|500,000 E$
|n/a
|20,000 kg (storage)
|-
|Nakamura MPU
|Mineral processing unit
|500,000 E$
|25 MW / chunk
|4,200 kg
|-
|Voyager RSLS fabrication plant
|Mineral processing unit / consumables printer
|1,500,000 E$
|20 MW / chunk (70 MW print draw)
|6,000 kg
|-
|Nakamura Dynamics Yama-SSR12
|Reactor core
|750,000 E$
| +30 GW thermal
|5,000 kg
|-
|Nakamura Dynamics Yama-SSR16
|Reactor core
|1,000,000 E$
| +40 GW thermal
|5,500 kg
|-
|Nakamura Dynamics Yama-SSR16S
|Reactor core
|1,500,000 E$
| +50 GW thermal
|6,000 kg
|-
|Military-grade turbine
|Gas turbine
|150,000 E$
| +500 MW
|5,000 kg
|-
|NDAPS
|Superconducting magnetic energy storage
|400,000 E$
|18,000 MJ (100 MW charge draw)
|1,000 kg
|}
{| class="wikitable sortable"
|+
!Ship
!Type
!Dry mass
|-
|ND-LIS Kitsune
|Light shuttle
|4,000 kg
|-
|Tsukuyomi-class frigate
|Tactical frigate
|Unknown
|-
|Phage-class mineral processing station
|Autonomous mining drone
|Unknown
|}
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-16T16:15:42Z

Spdx-dv: nakamura

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings. They are the presumed manufacturer of the nuclear-pumped XASER array that clears areas of the rings for miners.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering, but has recently lost influence in the market on account of their aging fleet.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamformed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable sortable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", the Mars-based Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
| +700 MW (100 MW + 1 GW thermal)
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|50,000 MJ (200 MW charge draw)
|3,500 kg
|-
|EIAA-1337 autopilot
|Semi-autonomous autopilot
|150,000 E$
|n/a
|n/a
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}

== Enceladus Corp. ==
The Enceladus Corporation is the local government of the massive O'Neill cylinder station Enceladus Prime, which orbits Enceladus. It holds an effective monopoly over all miners within the Saturnian system, as Enceladus is the only moon close enough to the rings for rapid cost-effective transit. In 2184, it was the focal point of the First Enceladian Gold Rush after an asteroid impacted the then-in-construction station, revealing an abundance of rare elements within the A-Ring.

While the corporation recognises the need for policing in the A-Ring on account of pirate activity, it does not have an active military, nor a wish to field one. The rule of law is instead enforced through the weregild system, where compensatory fines are issued to ships dependent on the severity of their transgressions. The Vilcy, an organised group of bounty hunters, have taken great interest in the system, and are the rings' de-facto police force.

Enceladus Corp. registers ships that operate in their region of space under the "SE1" designation.
{| class="wikitable"
|+
!Service
!Type
!Cost
!Time
!Cooldown
!Benefit
|-
|Affordable Capsule Hotel
|Lodging
|100 E$ / person
|1 day
|n/a
|n/a
|-
|The Twins
|Recreational establishment
|400 E$ / person
|4 hours
|24 hours
|Slight crew morale increase
|-
|Moonview Capsule Hotel
|Lodging
|300 E$ / person
|1 day
|n/a
|Minor crew morale increase
|-
|The Underside Inn
|Long-term lodging
|3,500 E$ / person
|7 days
|n/a
|Moderate crew morale increase
|-
|Skydome Resort
|Recreational lodging
|5,000 E$ booking + 2,000 E$ / person
|3 days
|n/a
|Major crew morale increase
|-
|Jameson Insurance
|Repair insurance
|50,000 E$
|1 hour
|30 days
| +100,000 E$ insurance budget
|-
|Local Vilcy Branch
|Fine management
|60% total weregild
|1 hour
|n/a
|Clears Vilcy faction hostility
|-
|The Miner's Guild
|Fine management
|Varies, max 140,000 E$
|1 hour
|n/a
|Clears civilian faction hostility
|-
|Obonto Habitats
|Fine management
|Varies, max 320,000 E$
|1 hour
|n/a
|Clears Obonto faction hostility
|}

== Mars Power Industries ==
Mars Power Industries is a Mars-based corporation whose tagline is "Bringing Light Where Darkness Reigns". Their main focus is in the development of industrial infrastructure for Martian colonies, such as power generation and resource extraction.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|MPI Railgun MkI
|Railgun
|20,000 E$
|800 MW
|2,000 kg
|-
|MPI Tug drones
|Disposable nanodrone assembler and launcher
|250,000 E$
|50 MW
|4,000 kg
|-
|Basic nanodrone storage
|Nanodrone component storage
|20,000 E$
|n/a
|1,000 kg (storage)
|-
|MPI Town-class MPDG
|Magnetoplasmadynamic electrical generator
|800,000 E$
| +1000 MW (150 MW + 1.5 GW thermal)
|8,000 kg
|-
|MPI Town-class storage
|Superconducting magnetic energy storage
|800,000 E$
|32,000 MJ (150 MW charge draw)
|2,000 kg
|}

== Minding LF ==
Minding LF specialises in simulation and statistical analysis, and provide the Virtual Flight Service available in the Dealer.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power
!Mass`
|-
|MLF long-wave RADAR
|Ice-penetrating ranging RADAR
|5,000 E$
|n/a
|n/a
|-
|MLF autopilot
|Basic autopilot: ARL, LIDAR highlight
|10,000 E$
|n/a
|n/a
|-
|MLF Haul drones
|Disposable nanodrone assembler and launcher
|350,000 E$
|50 MW
|4,000 kg
|}

== Mitsudaya-Starbus ==
Mitsudaya-Starbus is a relatively recent player in the advanced propulsion systems and spacecraft market, only having formed within the last 50 years from a merger between Japanese conglomerate Mitsudaya Group and European aerospace manufacturer Starbus. Their Prospector line, manufactured for the Free States of Earth, is prized in the outer solar system for both its utility and agility as mining vessels.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|MA150HO thruster
|Nuclear thermal magnetoplasmadynamic thruster
|4,375 E$
|40 MW
|80 kg
|-
|MA350HO thruster
|Nuclear thermal magnetoplasmadynamic thruster
|10,000 E$
|60 MW
|120 kg
|-
|MA-NMPD42 engine
|Nuclear thermal magnetoplasmadynamic thruster
|300,000 E$
|150 MW + 18.4 GW thermal
|1,850 kg
|-
|Mitsudaya-Starbus MSU
|Mineral processing unit
|900,000 E$
|150 MW / chunk
|2,500 kg
|-
|MPD5035
|Magnetoplasmadynamic electrical generator
|300,000 E$
| +350 MW (50 MW + 0.5 GW thermal)
|2,500 kg
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Eagle Prospector
|Mining clipper
|27,500 kg
|-
|Vulture Prospector
|Utility clipper
|37,500 kg
|-
|Peacock Prospector
|Luxury clipper
|27,500 kg
|-
|Pelican Prospector
|Mining barge
|62,000 kg
|}

== Nakamura Dynamics ==
Nakamura Dynamics is the largest military contractor in the solar system, and offers a range of advanced technologies to the civilian market.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power
!Mass
|-
|NDVTT thruster
|Nuclear thermal thruster
|2,500 E$
|1 MW + 1.8 GW thermal
|30 kg
|-
|NDSTR thruster
|Pulsed nuclear thermal thruster
|1,250 E$
|1 MW + 2.1 GW thermal
|20 kg
|-
|ND-NTTR engine
|Nuclear thermal thruster
|30,000 E$
|20 MW + 12.2 GW thermal
|650 kg
|-
|ND-PNTR engine
|Pulsed nuclear thermal thruster
|7,000 E$
|180 MW + 6 GW thermal
|450 kg
|-
|MWG microwave emitter
|1 cm microwave emitter
|70,000 E$
|50 MW
|100 kg
|-
|Point defence microwave generator
|Automatic swivel-mount 1 cm microwave emitter
|180,000 E$
|50 MW
|1,600 kg
|-
|NDPT-4205 point defence turret
|Semi-automatic swivel-mount railgun
|135,000 E$
|400 MW
|2,500 kg
|-
|NT Mining Companion
|Automated mining drone
|115,000 E$
|10 MW
|4,500 kg (approx)
|-
|Military projectile magazine
|Ammunition storage
|50,000 E$
|n/a
|10,000 kg (storage)
|-
|Frigate-class projectile magazine
|Ammunition storage
|100,000 E$
|n/a
|20,000 kg (storage)
|-
|Destroyer-class projectile magazine
|Ammunition storage
|250,000 E$
|n/a
|50,000 kg (storage)
|-
|Military nanodrone storage
|Nanodrone component storage
|250,000 E$
|n/a
|10,000 kg (storage)
|-
|Station-class nanodrone storage
|Nanodrone component storage
|1,250,000 E$
|n/a
|50,000 kg (storage)
|-
|Harvester-class nanodrone storage
|Nanodrone component storage
|500,000 E$
|n/a
|20,000 kg (storage)
|-
|Nakamura MPU
|Mineral processing unit
|500,000 E$
|25 MW / chunk
|4,200 kg
|-
|Voyager RSLS fabrication plant
|Mineral processing unit / consumables printer
|1,500,000 E$
|20 MW / chunk (70 MW print draw)
|6,000 kg
|-
|Nakamura Dynamics Yama-SSR12
|Reactor core
|750,000 E$
| +30 GW thermal
|5,000 kg
|-
|Nakamura Dynamics Yama-SSR16
|Reactor core
|1,000,000 E$
| +40 GW thermal
|5,500 kg
|-
|Nakamura Dynamics Yama-SSR16S
|Reactor core
|1,500,000 E$
| +50 GW thermal
|6,000 kg
|-
|Military-grade turbine
|Gas turbine
|150,000 E$
| +500 MW
|5,000 kg
|-
|NDAPS
|Superconducting magnetic energy storage
|400,000 E$
|18,000 MJ (100 MW charge draw)
|1,000 kg
|}
{| class="wikitable"
|+
!Ship
!Type
!Dry mass
|-
|ND-LIS Kitsune
|Light shuttle
|4,000 kg
|-
|Tsukuyomi-class frigate
|Tactical frigate
|Unknown
|-
|Phage-class mineral processing station
|Autonomous mining drone
|Unknown
|}
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-15T20:12:30Z

Spdx-dv: Enceladus, Mitsudaya, Minding

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings. They are the presumed manufacturer of the nuclear-pumped XASER array that clears areas of the rings for miners.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering, but has recently lost influence in the market on account of their aging fleet.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamformed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable sortable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", the Mars-based Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
|100 MW + 1 GW thermal
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|200 MW charge draw
|3,500 kg
|-
|EIAA-1337 autopilot
|Semi-autonomous autopilot
|150,000 E$
|n/a
|n/a
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}

== Enceladus Corp. ==
The Enceladus Corporation is the local government of the massive O'Neill cylinder station Enceladus Prime, which orbits Enceladus. It holds an effective monopoly over all miners within the Saturnian system, as Enceladus is the only moon close enough to the rings for rapid cost-effective transit. In 2184, it was the focal point of the First Enceladian Gold Rush after an asteroid impacted the then-in-construction station, revealing an abundance of rare elements within the A-Ring.

While the corporation recognises the need for policing in the A-Ring on account of pirate activity, it does not have an active military, nor a wish to field one. The rule of law is instead enforced through the weregild system, where compensatory fines are issued to ships dependent on the severity of their transgressions. The Vilcy, an organised group of bounty hunters, have taken great interest in the system, and are the rings' de-facto police force.

Enceladus Corp. registers ships that operate in their region of space under the "SE1" designation.
{| class="wikitable"
|+
!Service
!Type
!Cost
!Time
!Cooldown
!Benefit
|-
|Affordable Capsule Hotel
|Lodging
|100 E$ / person
|1 day
|n/a
|n/a
|-
|The Twins
|Recreational establishment
|400 E$ / person
|4 hours
|24 hours
|Slight crew morale increase
|-
|Moonview Capsule Hotel
|Lodging
|300 E$ / person
|1 day
|n/a
|Minor crew morale increase
|-
|The Underside Inn
|Long-term lodging
|3,500 E$ / person
|7 days
|n/a
|Moderate crew morale increase
|-
|Skydome Resort
|Recreational lodging
|5,000 E$ booking + 2,000 E$ / person
|3 days
|n/a
|Major crew morale increase
|-
|Jameson Insurance
|Repair insurance
|50,000 E$
|1 hour
|30 days
| +100,000 E$ insurance budget
|-
|Local Vilcy Branch
|Fine management
|60% total weregild
|1 hour
|n/a
|Clears Vilcy faction hostility
|-
|The Miner's Guild
|Fine management
|Varies, max 140,000 E$
|1 hour
|n/a
|Clears civilian faction hostility
|-
|Obonto Habitats
|Fine management
|Varies, max 320,000 E$
|1 hour
|n/a
|Clears Obonto faction hostility
|}

== Mars Power Industries ==
Mars Power Industries is a Mars-based corporation whose tagline is "Bringing Light Where Darkness Reigns". Their main focus is in the development of industrial infrastructure for Martian colonies, such as power generation and resource extraction.
{| class="wikitable sortable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|MPI Railgun MkI
|Railgun
|20,000 E$
|800 MW
|2,000 kg
|-
|MPI Tug drones
|Disposable nanodrone assembler and launcher
|250,000 E$
|50 MW
|4,000 kg
|-
|Basic nanodrone storage
|Nanodrone component storage
|20,000 E$
|n/a
|1,000 kg (storage)
|-
|MPI Town-class MPDG
|Magnetoplasmadynamic electrical generator
|800,000 E$
|150 MW + 1.5 GW thermal
|8,000 kg
|-
|MPI Town-class storage
|Superconducting magnetic energy storage
|800,000 E$
|150 MW charge draw
|2,000 kg
|}

== Minding LF ==
Minding LF specialises in simulation and statistical analysis, and provide the Virtual Flight Service available in the Dealer.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass`
|-
|MLF long-wave RADAR
|Ice-penetrating ranging RADAR
|5,000 E$
|n/a
|n/a
|-
|MLF autopilot
|Basic autopilot: ARL, LIDAR highlight
|10,000 E$
|n/a
|n/a
|-
|MLF Haul drones
|Disposable nanodrone assembler and launcher
|350,000 E$
|50 MW
|4,000 kg
|}

== Mitsudaya-Starbus ==
Mitsudaya-Starbus is a relatively recent player in the advanced propulsion systems and spacecraft market, only having formed within the last 50 years from a merger between Japanese conglomerate Mitsudaya Group and European aerospace manufacturer Starbus. Their Prospector line, manufactured for the Free States of Earth, is prized in the outer solar system for both its utility and agility as mining vessels.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|MA150HO thruster
|Nuclear-thermal magnetoplasmadynamic thruster
|4,375 E$
|40 MW
|80 kg
|-
|MA350HO thruster
|Nuclear-thermal magnetoplasmadynamic thruster
|10,000 E$
|60 MW
|120 kg
|-
|MA-NMPD42 engine
|Nuclear-thermal magnetoplasmadynamic thruster
|300,000 E$
|150 MW + 18.4 GW thermal
|1,850 kg
|-
|Mitsudaya-Starbus MSU
|Mineral processing unit
|900,000 E$
|150 MW / chunk
|2,500 kg
|-
|MPD5035
|Magnetoplasmadynamic electrical generator
|300,000 E$
|50 MW + 0.5 GW thermal
|2,500 kg
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Eagle Prospector
|Mining clipper
|27,500 kg
|-
|Vulture Prospector
|Utility clipper
|37,500 kg
|-
|Peacock Prospector
|Luxury clipper
|27,500 kg
|-
|Pelican Prospector
|Mining barge
|62,000 kg
|}
* Nakamura Dynamics
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-14T15:54:40Z

Spdx-dv: /* Conlido RVM */

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering, appealing to the lower-end market with a range of inexpensive products.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamfromed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", the Mars-based Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
|100 MW + 1 GW thermal
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|200 MW charge draw
|3,500 kg
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}

== Mars Power Industries ==
Mars Power Industries is a Mars-based corporation whose tagline is "Bringing Light Where Darkness Reigns". Their main focus is in the development of industrial infrastructure for Martian colonies, such as power generation and resource extraction.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|MPI Railgun MkI
|Railgun
|20,000 E$
|800 MW
|2,000 kg
|-
|MPI Tug drones
|Disposable nanodrone assembler and launcher
|250,000 E$
|50 MW
|4,000 kg
|-
|Basic nanodrone storage
|Nanodrone component storage
|20,000 E$
|n/a
|1,000 kg (storage)
|-
|MPI Town-class MPDG
|Magnetoplasmadynamic electrical generator
|800,000 E$
|150 MW + 1.5 GW thermal
|8,000 kg
|-
|MPI Town-class storage
|Superconducting magnetic energy storage
|800,000 E$
|150 MW charge draw
|2,000 kg
|}
* Minding LF
* Mitsubishi-Airbus
* Nakamura Dynamics
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-14T15:53:31Z

Spdx-dv: MPI

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering that appeals to the lower-end market with a range of inexpensive products.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamfromed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", the Mars-based Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
|100 MW + 1 GW thermal
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|200 MW charge draw
|3,500 kg
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}

== Mars Power Industries ==
Mars Power Industries is a Mars-based corporation whose tagline is "Bringing Light Where Darkness Reigns". Their main focus is in the development of industrial infrastructure for Martian colonies, such as power generation and resource extraction.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|MPI Railgun MkI
|Railgun
|20,000 E$
|800 MW
|2,000 kg
|-
|MPI Tug drones
|Disposable nanodrone assembler and launcher
|250,000 E$
|50 MW
|4,000 kg
|-
|Basic nanodrone storage
|Nanodrone component storage
|20,000 E$
|n/a
|1,000 kg (storage)
|-
|MPI Town-class MPDG
|Magnetoplasmadynamic electrical generator
|800,000 E$
|150 MW + 1.5 GW thermal
|8,000 kg
|-
|MPI Town-class storage
|Superconducting magnetic energy storage
|800,000 E$
|150 MW charge draw
|2,000 kg
|}
* Minding LF
* Mitsubishi-Airbus
* Nakamura Dynamics
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-14T15:07:15Z

Spdx-dv: added EI

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering that appeals to the lower-end market with a range of inexpensive products.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamfromed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}

== Elon Interstellar ==
Host of popular social media platform "Bitter", Elon Interstellar dedicates itself to high-technology gadgets with (theoretically) broad applications targeting the luxury market.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|EINAT Kzinti Lesson MkII
|Magnetoplasma thrower
|100,000 E$
|200 MW + 18.4 GW thermal
|2,750 kg
|-
|Elon Interstellar ion thruster
|Nuclear-assisted ion thruster
|8,000 E$
|40 MW + 3 GW thermal
|90 kg
|-
|Elon Interstellar AGILE ion thruster
|Gimballing nuclear-assisted ion thruster
|12,000 E$
|60 MW + 2.5 GW thermal
|120 kg
|-
|Experimental NPMP engine
|Nuclear pulsed MPD thruster
|700,000 E$
|200 MW + 24.7 GW thermal
|2,750 kg
|-
|Z-axial pinch fusion torch
|Z-pinch fusion thruster
|1,000,000 E$
|150 MJ / 0.1 s
|3,000 kg
|-
|EIBFG MkIV Big Furnace Generator
|Magnetoplasmadynamic electrical generator
|500,000 E$
|100 MW + 1 GW thermal
|4,000 kg
|-
|EIUP MkII Unlimited Power
|Superconducting magnetic energy storage
|1,200,000 E$
|200 MW charge draw
|3,500 kg
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Elon Interstellar Model E
|Luxury yacht
|27,000 kg
|}
* Mars Power Industries
* Minding LF
* Mitsubishi-Airbus
* Nakamura Dynamics
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Corporations

2024-06-14T14:38:21Z

Spdx-dv: rework in progress

== Coherent Light ==
Coherent Light focuses on the applications of directed energy in mining, producing laser optics and systems appropriate for breaking up ice formations in the rings.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|CL-144PLA phased LIDAR array
|Omnidirectional infrared ranging LIDAR
|120,000 E$
|n/a
|n/a
|-
|CL-150 mining laser
|490 nm (blue) laser
|150,000 E$
|150 MW
|4,000 kg
|-
|CL-200AP pulse mining laser
|650 nm (red) pulse laser
|220,000 E$
|220 MW
|5,500 kg
|-
|CL-600P pulse mining laser
|540 nm (green) pulse laser
|320,000 E$
|660 MW
|7,000 kg
|}

== Conlido RVM ==
Conlido RVM is a ship and hardware manufacturer that has long been a mainstay of orbital engineering that appeals to the lower-end market with a range of inexpensive products.
{| class="wikitable"
|+
!Product
!Type
!Price
!Power requirements
!Mass
|-
|IRL-360 infrared LIDAR
|Infrared ranging/doppler LIDAR
|15,000 E$
|n/a
|n/a
|-
|IRL-30-BF beamfromed infrared LIDAR
|Narrow-cone infrared ranging/doppler LIDAR
|25,000 E$
|n/a
|n/a
|-
|External impact absorber
|Side-mounted protective shield
|4,000 E$
|n/a
|8,500 kg
|-
|EMD-14 mass driver
|Mass driver, 10kg slug
|10,000 E$
|750 MW
|3,000 kg
|-
|ERFMD-14 mass driver
|Rapid-fire mass driver, 10kg slug
|30,000 E$
|500 MW
|5,000 kg
|-
|AEMD-14 mass driver
|Auto-aiming mass driver, 10kg slug
|32,000 E$
|750 MW
|4,500 kg
|-
|Projectile magazine
|Ammunition storage
|5,000 E$
|n/a
|1,000 kg (storage)
|-
|Dual projectile magazine
|Ammunition storage
|10,000 E$
|n/a
|2,000 kg (storage)
|-
|Industrial nanodrone storage
|Nanodrone component storage
|120,000 E$
|n/a
|5,000 kg (storage)
|}
{| class="wikitable"
|+
!Ship name
!Type
!Dry mass
|-
|Cothon-211 "Chonker"
|Asteroid mining barge
|83,700 kg
|-
|Cothon-212
|Interlunar cargo hauler
|83,700 kg
|-
|Cothon-213 "Triplet"
|Interlunar lander / hauler
|84,700 kg
|-
|Cothon-217 "Bender"
|Experimental hauler
|103,700 kg
|}
* Coherent Light
* Conlido RVM
* Elon Interstellar
* Mars Power Industries
* Minding LF
* Mitsubishi-Airbus
* Nakamura Dynamics
* Obonto Micro Engineering
* Rosatom-Antonov
* Tetsuo Engineering
* (enceladus holding Corp?)

[[Category:Codex]]

Modding

2024-06-14T10:36:30Z

Spdx-dv: initial creation

Delta-V: Rings of Saturn supports mods, and has provided modding support since 2022. The game's modloader, when active, loads mods as .zip files from a 'mods' folder within the game's directory.

Mods can execute unsafe or dangerous code on your computer, and may carry bugs or game-breaking issues. Contact the mod author if you have problems, as Kodera Software can't help with problems caused by mods.

== Getting Started ==

=== Installing Mods ===
Installing Delta-V mods is a simple process:

# Open the game's installation directory and create a folder called <code>mods</code>. This folder should be alongside the game's executable and .pck file.
# Download a mod. You'll receive a .zip file. Don't extract it, as the modloader will do that for you when the game runs.
# Place the mod's .zip inside the mods folder.
# Add the argument <code>--enable-mods</code> to your game's launch parameters.
#* On Steam, either right-click on your game in the Library menu or select it and click on the gear button on the right side of the window, then select "Properties...". In the popup window's "General" tab, place the argument into the "Launch Options" box, then close the popup.
#* On the Epic Games launcher, go to the Library menu, click on the "..." button next or near to the game's icon and select "Manage". In the popup window, Enable "Launch Options" and put the argument into the box that appears, then close the popup.
#* On GOG Galaxy, go to the Installed menu, then either right-click on the game's panel or select it and click the settings button next to Play, then navigate to "Manage installation" > "Configure...". In the popup window, go to the "Features" tab and enable the "Launch parameters" option. Select "Duplicate" for File 1, then put the argument into the "Arguments" box. Set it as the default executable, customise the label if you want to, and then press "OK".
#* If you don't have a launcher, go to your game's directory and create a shortcut from its executable file. On Windows, you do this by right-clicking the executable and selecting "Create shortcut". Right-click on the shortcut and, in the "Target" box, add the argument to the end. You'll need to open the game from this shortcut for it to work.
# Run the game. Delta-V doesn't currently have a mod menu, so you won't see changes until they appear in the game.

=== Backing Up Save Files ===

==== Windows ====
Delta-V's save files are stored in the dV folder in AppData. This is accessible by typing <code>%appdata%/dV</code> into the address bar. From there, copy the <code>savegame.dv</code> files into a separate folder. You can restore backed-up save files by replacing the ones in your AppData folder with your backed-up versions.

It's a good idea to back up save files before installing mods, even if they don't need new saves to work.