minor corrections

ecs notes 2.txt

@@ -13,3 +13,13 @@ NO Grabs all position and orbit components with a specific system.
   - note: L4/L5 positions are stored as their own orbits
 * id:
 * x,y,system_id: position in a system
+
+# Notes
+
+- Model populations as their own entities.
+- Minerals on a body can be mined.
+- Minerals on a population have already been mined, and can be used.
+- Consider splitting MapDisplay's version of bodies from the reality?
+  - Reason A: It will also need to store contacts, and should not always have all info
+  - Reason B: Orbital positions should only be updated by an orbital processor when needed
+  - Reason C: Reduce duplication by making the orbital processor the only thing that updates positions?

src/generators/MapDisplay.moon

@@ -1,34 +0,0 @@
-import graphics from love
-import cos, sin from math
-
-w, h = graphics.getDimensions!
-
-tiny = require "tiny"
-IDTracker = require "systems/IDTracker"
-
-MapDisplay = (system_id) ->
-  return tiny.sortedSystem {
-    compare: (a, b) =>
-      if a.orbit and b.orbit
-        a.orbit.hierarchy <= b.orbit.hierarchy
-      else
-        true
-    filter: tiny.requireAny "orbit", tiny.requireAll("x", "y", system_id)
-    draw: (t) =>
-      graphics.translate w / 2, h / 2
-      for entity in *@entities
-        if orbit = entity.orbit
-          orbit = entity.orbit
-          -- orbital period
-          --  real: T = 2pi * sqrt(a^3 / G*M)
-          --  sim:  T = 2pi * speed_parameter
-          entity.x = orbit.radius * cos(t / orbit.speed_parameter) + orbit.offset
-          entity.y = orbit.radius * sin(t / orbit.speed_parameter) + orbit.offset
-          if orbit.parent_id
-            parent = IDTracker[orbit.parent_id]
-            entity.x += parent.x
-            entity.y += parent.y
-        graphics.circle "fill", entity.x, entity.y, 5 -- TEMP radius
-  }
-
-return MapDisplay

src/generators/stellar_body.moon

@@ -0,0 +1,19 @@
+-- TODO defined globals need to be created somewhere else
+export stefan_boltzmann_constant = 5.670374419e-8 -- W / (m^2 * K^4)
+
+parameters = {
+  temperature: love.math.randomNormal 1000, 6000 -- [2000 to 10000] K
+}
+
+parameters.absolute_magnitude = 35.4631241560502 * math.exp(-0.000353006569939 * parameters.temperature) -- Mv
+parameters.luminosity = 100 * math.exp -0.943865141164545 * (parameters.absolute_magnitude - 0.99^parameters.absolute_magnitude) -- L(sun)
+-- TODO calculate B-V value ? Or color directly? Or spectrum?
+
+-- TODO this needs to be multiplied by the star's surface area to get its total power emission
+parameters.surface_power_emission = stefan_boltzmann_constant * parameters.temperature^4 -- W / m^2
+-- NOTE then for measuring power input into a planet, find the surface area of
+-- its orbital radius, divide total power by that, then multiply that by the
+-- circular cross-section of that planet to get the total power being emitted
+-- into that planet, which must equal its emission, allowing you to calculate
+-- its surface temperature*
+-- * if it had no atmosphere, or albedo

src/generators/terrestrial_body.moon

@@ -0,0 +1,29 @@
+-- TODO defined globals need to be created somewhere else
+export gravitational_constant = 6.6743e-11 -- m^3 / (kg * s^2)
+export magic_pressure_constant = 1.1701572e-4 -- s^2 / m^2
+
+parameters = {
+  surface_radius: love.math.randomNormal 1100, 5500 -- [1.1e3, 9.9e3  km]
+  solid_density: love.math.randomNormal 0.675, 5.2 -- [2.5, 7.9 g/cm^3]
+}
+
+parameters.solid_volume = 4/3 * math.pi * parameters.surface_radius^3 -- km^3
+parameters.solid_mass = parameters.solid_density * parameters.solid_volume * 1e12 -- kg
+parameters.surface_gravity = gravitational_constant * parameters.solid_mass / parameters.surface_radius^2 * 1e-6 -- m/s^2
+parameters.atmosphere_reduction_rate = parameters.surface_gravity * magic_pressure_constant -- m^-1
+parameters.atmosphere_halving_height = math.log(2) / parameters.atmosphere_reduction_rate -- m
+-- volume containing the first half of the entire atmosphere is assumed to be
+-- half of the volume of the entire atmosphere if it was at surface pressure
+parameters.simulated_atmosphere_volume = (4/3 * math.pi * (parameters.surface_radius + parameters.atmosphere_halving_height / 1000)^3 - parameters.solid_volume) * 2 -- km^3
+
+-- TODO better (based on distance from star / temperature from star)
+parameters.surface_atmosphere_pressure = 101325 * math.max 0, love.math.randomNormal 0.125, 0.5 -- [0, 202650 kPa]
+-- TODO verify this will generate in meters
+parameters.minimum_orbital_height = math.log(1.4e-11 / parameters.surface_atmosphere_pressure) / parameters.atmosphere_reduction_rate -- m
+parameters.atmosphere_volume = 4/3 * math.pi * (parameters.surface_radius + parameters.minimum_orbital_height / 1000)^3 - parameters.solid_volume -- km^3
+-- TODO atmospheric composition?
+-- TODO albedo
+-- TODO surface_average_temperature (based on greenhouse gases or lack thereof, albedo, and base temperature from distance to star)
+
+-- unused at this time?
+parameters.surface_area = 4 * math.pi * parameters.surface_radius^2

src/main.moon

@@ -1,5 +1,4 @@
 tiny = require "tiny"
-MapDisplay = require "generators/MapDisplay"
 
 systems = {}
 for name in *love.filesystem.getDirectoryItems "systems"
@@ -18,16 +17,14 @@ makeEntity = (tab) ->
   return tab
 
 world = tiny.world game, unpack systems
-local map
 
 system = ->
-  system_id = "someuuidthing"
   sun = makeEntity {
-    x: 0,
-    y: 0
-    [system_id]: true
+    x: 0, y: 0
+    radius: 5
   }
   planet = makeEntity {
+    radius: 1
     orbit: {
       hierarchy: 1
       radius: 20
@@ -35,11 +32,8 @@ system = ->
       offset: love.math.random!
       speed_parameter: 0.5
     }
-    [system_id]: true
   }
-  map = MapDisplay system_id
   world\add sun, planet
-  world\add map
 
 system!
 
@@ -47,7 +41,7 @@ love.update = (dt) ->
   world\update dt
 
 love.draw = ->
-  map\draw game.time
+  systems.MapDisplay\draw game.time
 
 love.keypressed = (key) ->
   if key == "escape" love.event.quit!

src/systems/MapDisplay.moon

@@ -20,14 +20,14 @@ MapDisplay = tiny.sortedSystem {
         orbit = entity.orbit
         -- orbital period
         --  real: T = 2pi * sqrt(a^3 / G*M)
-        --  sim:  T = 2pi * speed_parameter
-        entity.x = orbit.radius * cos(t / orbit.speed_parameter) + orbit.offset
-        entity.y = orbit.radius * sin(t / orbit.speed_parameter) + orbit.offset
+        --  sim:  T = 2pi / speed_parameter
+        entity.x = orbit.radius * cos(t * orbit.speed_parameter) + orbit.offset
+        entity.y = orbit.radius * sin(t * orbit.speed_parameter) + orbit.offset
         if orbit.parent_id
           parent = IDTracker[orbit.parent_id]
           entity.x += parent.x
           entity.y += parent.y
-      graphics.circle "fill", entity.x, entity.y, 5 -- TEMP radius
+      graphics.circle "fill", entity.x, entity.y, entity.radius
 }
 
 return MapDisplay

src/systems/disabled/MapDisplayManager.moon

@@ -1,59 +0,0 @@
-import graphics from love
-import cos, sin from math
-
-w, h = graphics.getDimensions!
-
-tiny = require "tiny"
-IDTracker = require "systems/IDTracker"
-
-
-
-MapDisplayManager = tiny.system {
-  known: {}
-  filter: tiny.requireAll "system_id"
-  onAdd: (entity) =>
-    unless @known[entity.system_id]
-      @known[entity.system_id] = true
-      makeDisplay entity.system_id
-  onRemove: (entity) =>
-}
-
-
-
-IDTracker = tiny.system {
-  filter: tiny.requireAll "id"
-  onAdd: (entity) =>
-    @[entity.id] = entity
-  onRemove: (entity) =>
-    @[entity.id] = nil
-}
-return MapDisplayManager
-
-
-
-
-MapDisplay = tiny.sortedSystem {
-  compare: (a, b) =>
-    if a.orbit and b.orbit
-      a.orbit.hierarchy <= b.orbit.hierarchy
-    else
-      true
-  filter: tiny.requireAny "orbit", tiny.requireAll("x", "y")
-  draw: (t) =>
-    graphics.translate w / 2, h / 2
-    for entity in *@entities
-      if orbit = entity.orbit
-        orbit = entity.orbit
-        -- orbital period
-        --  real: T = 2pi * sqrt(a^3 / G*M)
-        --  sim:  T = 2pi * speed_parameter
-        entity.x = orbit.radius * cos(t / orbit.speed_parameter) + orbit.offset
-        entity.y = orbit.radius * sin(t / orbit.speed_parameter) + orbit.offset
-        if orbit.parent_id
-          parent = IDTracker[orbit.parent_id]
-          entity.x += parent.x
-          entity.y += parent.y
-      graphics.circle "fill", entity.x, entity.y, 5 -- TEMP radius
-}
-
-return MapDisplay