Spieldesign - Neo-Feudal system: Unterschied zwischen den Versionen

Aktuelle Version vom 6. Dezember 2014, 21:31 Uhr

Inhaltsverzeichnis

1 Feudal hierarchy
2 Religion
3 Solar systems

Feudal hierarchy[Bearbeiten | edit source]

Emperor[Bearbeiten | edit source]

Controls multiple star systems.

To proclaim yourself an Emperor, you have to be the sovereign (King) of at least two star systems. There is a social pressure to do so, in fact. You don't automatically lose your Emperor title when you're down to just one star system, but those who conquer the last one from you can strip you off it by force.

King[Bearbeiten | edit source]

Controls a star system.

To proclaim yourself a King, you have to be the sovereign (Duke) of at least half of the habitable planets of the star system if there is no other King of that system, else at least two-thirds of the star system if there is one, to wrestle control from him.

Duke[Bearbeiten | edit source]

Controls a habitable planet (+ territories subordinate to that)

Baron[Bearbeiten | edit source]

Controls a planetoid or major asteroid, a habitable planet's moon or a habitable planet's state

Religion[Bearbeiten | edit source]

(TBD)

Solar systems[Bearbeiten | edit source]

Interstellar[Bearbeiten | edit source]

Planetary systems - as well as everything on that scale in the game - are positioned to a precision of 0.001 ly (63.240 AU) and treated as stationary for the course of the game. A jump into the system happens inside this precision's limits. Major planets are assumed to be all inside these limits (and thus the max distance from the baricentre should not exceed 63.240 AU, but there's no check to prevent that).

Comparison of the solar system:

Outermost planet (Neptune): 30.332-29.810 AU
Outermost planetoid (Sedna): 937-76 AU (0.015-0.001 ly)
inner doughnut-shaped (Hills) Oort cloud 2k-20k AU (0.032-0.316 ly), outer (spherical) Oort cloud 20k-50k AU (0.316-0.791 ly).

Interplanetary[Bearbeiten | edit source]

Inside a system, stars, planets, planetoids, asteroids, moons and so on have distances measured to the precision of 0.001 AU (=about 150 Mm). The first four all orbit the barycentre of the system itself, moons orbit the barycentre of their planetary system. The distances are all mean distances (for now).

Objects outside of 63.240 AU mean radius should be avoided.

Planets have a max mass of 25,000,000 Yg (a bit over 13 times that of Jupiter) or 1/25th of the main star, whatever is lower.

Moons should have a diameter of at least 200 km (100km radius) or a mass of at least 0.01 Yg.

Binary systems count as two separate areas.

Stellar effective temperature table[Bearbeiten | edit source]

Reference temperature for main sequence stars in K
	Temperature bracket
	0	1	2	3	4	5	6	7	8	9
O	60000	55000	52000	48000	45000	42000	39000	36000	33000	30000
B	27000	24000	20000	17000	14500	12500	11700	11100	10600	10200
A	9800	9500	9200	8900	8700	8500	8300	8100	7900	7700
F	7500	7300	7100	6900	6700	6500	6400	6300	6200	6100
G	6000	5900	5800	5700	5600	5500	5400	5350	5300	5250
K	5200	5100	5000	4900	4800	4650	4500	4300	4100	3900
M	3700	3550	3400	3250	3100	2950	2800	2650	2500	2400
L	2300	2200	2100	2000	1900	1800	1700	1600	1500	1400
T	1300	1200	1100	1000	900	800	700	650	600	550
Y	500	450	400	470	440	410	380	360	340	320

Generation details[Bearbeiten | edit source]

The generation starts with the main star and proceeds from the most massive to the least massive main planet, then through their moons and minor planets.

Minimum distance to the star depends on star type (and thus radius). Since planets can migrate around as the star ages, the generation typically considers the current star size only, not what it looked like in the past. Biggest star known is VY Canis Majoris [M3] at about 6.1 AU radius.

Stellar class and radius/density table. The radius can vary up to 20% in either direction (= for the generation, make that a Normal distribution with sigma=10%). The mass and radius are nearly linear: Radios is proportional to Mass^0.78 respective the Mass to Radius^1.282. This only breaks down for the smallest stars, but we can ignore that. Mass can also vary by up to 30% (sigma=15% Normal distribution) after calculating the average one. Temperature depends solely on the star type.

Luminosity can be calculated from the radius and temperature by the Stefan-Boltzmann law:

L = 4πσR²T_eff⁴

Table of main-sequence stellar parameters
Stellar classification\|Stellar Class	Radius		Example Density	Example Mass		Calculated Mass		Luminosity	Temperature	Examples
Stellar classification\|Stellar Class	R/R_☉	R (AU)	kg/m³	M/M_☉	M (Yg)	M/M_☉	M (Yg)	L/L_☉	K	Examples
O6	18	0.084	110	40	79 600 000 000	40.7	-	500,000	38,000	θ¹ Orionis C
B0	7.4	0.034	62.5	18	35 800 000 000	13.0	-	20,000	30,000	Phi¹ Orionis
B5	3.8	0.018	167	6.5	12 900 000 000	5.54	-	800	16,400	Pi Andromedae A
A0	2.5	0.012	288	3.2	6 390 000 000	3.24	-	80	10,800	Alpha Coronae Borealis A
A5	1.7	0.008	602	2.1	4 180 000 000	1.97	-	20	8,620	Beta Pictoris
F0	1.3	0.006	1090	1.7	3 380 000 000	1.40	-	6	7,240	Gamma Virginis
F5	1.2	0.006	1060	1.3	2 590 000 000	1.26	-	2.5	6,540	Eta Arietis
G0	1.05	0.005	1340	1.10	2 190 000 000	1.06	-	1.26	5,920	Beta Comae Berenices
G2	1.00	0.005	1400	1.00	1 990 000 000	1.00	-	1.00	5,780	Sol
G5	0.93	0.004	1630	0.93	1 850 000 000	0.91	-	0.79	5,610	Alpha Mensae
K0	0.85	0.004	1790	0.78	1 550 000 000	0.81	-	0.40	5,240	70 Ophiuchi A
K5	0.74	0.003	2400	0.69	1 370 000 000	0.68	-	0.16	4,410	61 Cygni A
M0	0.63	0.003	2650	0.47	935 000 000	0.55	-	0.063	3,920	Gliese 185
M5	0.32	0.001	9020	0.21	418 000 000	0.232	-	0.0079	3,120	EZ Aquarii
M8	0.13	0.001	64100	0.10	199 000 000	0.073	-	0.0008	2,660	Van Biesbroeck's star

TODO: Star generation charts, Giant stars generation.

Second step is to generate the planets. Their maximum mass depends on the mass of the main star. It can never be more than 1/25th of the star mass (... or else we'll run into problems with L4/L5 zones being unstable), but that limit is only relevant to very small stars. Their amount also varies by the star size. Suggested average amounts:

Table of main-sequence planet numbers
Classification	Average major planets	Sigma
O	15	6
B	12	5
A	10	4.5
F	8	4
G	7	3
K	6	2.5
M	5	2

The position of the planets can be nearly random, since "Hot Jupiters" exist due to how planets can wander around the star system before settling in orbits. The limits are:

The distance from the star to the nearest planet needs to be bigger than the sun's radius + L1 point distance/Hill's sphere's radius of R_H (semi-major axis) x ((planet's mass) / (3 x (star's mass)))^1/3.
- This check is done after the planet generation
- The check also determines the distance given a specific eccentricity e with the distance to check being made against the pericentre of (1-e) x (semi-major axis)
Once a planet is created, the Hill's distance is recorded. No planetoid can lie within up to 5x this distance in both directions. Planets should have even exclusion bigger radii (10x?) with exceptions made for common non-destructive resonance bands like 3x2, 5x2, 5x3, 7x2, 7x3, 7x5 and similar.
The planet's moons can at most lie within the radius of its sphere of influence: (semi-major axis) x ((planet's mass) / (star's mass))^2/5

References:

Example of the solar system (in AU)

	->	<-	Mercury	->	<-	Venus	->	<-	Terra	->	<-	Mars	->	(Ceres)	<-	Jupiter	->	<-	Saturn	->	<-	Uranus	->	<-	Neptune	->	(2002-XW93)
HSR			0.00148			0.00674			0.01001			0.00724				0.34697			0.42881			0.46494			0.77035
Distance in HSR		261.5x		218.3x	49.9x		41.1x	27.7x		52.3x	72.4x		171.5x		7.0x		12.5x	10.1x		22.5x	20.8x		23.4x	14.1x		9.8x
2xHSR	(0.005)	0.384		0.390	0.710		0.736	0.980		0.1020	1.510		1.538	(2.766)	4.504		5.892	8.679		10.397	16.866		20.121	28.528		31.610	(37.645)
5xHSR	(0.005)	0.380		0.394	0.689		0.757	0.950		0.1050	1.488		1.560	(2.766)	3.463		6.933	7.393		11.681	18.261		23.841	26.217		33.921	(37.645)

TODO: Check values, might need a bigger exclusion radius.

System examples[Bearbeiten | edit source]

Solar system[Bearbeiten | edit source]

1 star, 8 planets, 41 planetoids (one double system), 23 major moons

0.005 AU Sol [Star, G2V]
0.387 AU Mercury [Planet]
0.723 AU Venus [Planet]
1.000 AU Terra [Planet]
- 0.002 AU Luna [Moon]
1.524 AU Mars [Planet]
2.766 AU Ceres [Planetoid]
5.198 AU Jupiter [Planet]
- 0.001 AU Amalthea [Moon]
- 0.003 AU Io [Moon]
- 0.004 AU Europe [Moon]
- 0.007 AU Ganymede [Moon]
- 0.013 AU Callisto [Moon]
9.537 AU Saturn [Planet]
- 0.001 AU Mimas [Moon]
- 0.002 AU Enceladus [Moon]
- 0.002 AU Tethys [Moon]
- 0.003 AU Dione [Moon]
- 0.004 AU Rhea [Moon]
- 0.008 AU Titan [Moon]
- 0.010 AU Hyperion [Moon]
- 0.024 AU Iapetus [Moon]
- 0.086 AU Phoebe [Moon]
19.191 AU Uranus [Planet]
- 0.001 AU Miranda [Moon]
- 0.001 AU Ariel [Moon]
- 0.002 AU Umbriel [Moon]
- 0.003 AU Titania [Moon]
- 0.004 AU Oberon [Moon]
30.069 AU Neptune [Planet]
- 0.001 AU Proteus [Moon]
- 0.002 AU Triton [Moon]
- 0.037 AU Nereid [Moon]
37.645 AU 2002-XW93 [Planetoid]
38.743 AU 2004-TY364 [Planetoid]
39.266 AU 2003-VS2 [Planetoid]
39.290 AU 2003-UZ413 [Planetoid]
39.330 AU 2002-XV93 [Planetoid]
39.406 AU 2003-AZ84 [Planetoid]
39.419 AU Orcus [Planetoid]
39.482 AU Pluto-Charon [Planetoid binary]
39.565 AU 2007-JH43 [Planetoid]
39.680 AU Ixion [Planetoid]
41.589 AU 2005-RN43 [Planetoid]
41.930 AU 2002-MS4 [Planetoid]
41.934 AU 2004-GV9 [Planetoid]
42.190 AU Salacia [Planetoid]
42.869 AU 2002-UX25 [Planetoid]
43.130 AU Varuna [Planetoid]
43.280 AU 2010-VK201 [Planetoid]
43.310 AU 2005-UQ513 [Planetoid]
43.335 AU Haumea [Planetoid]
43.600 AU Quaoar [Planetoid]
43.657 AU 2004-NT33 [Planetoid]
45.000 AU 2010-KZ39 [Planetoid]
45.792 AU Makemake [Planetoid]
45.599 AU Chaos [Planetoid]
45.697 AU 2014-UM33 [Planetoid]
45.953 AU Varda [Planetoid]
46.690 AU 2010-FX86 [Planetoid]
46.980 AU 2004-XA192 [Planetoid]
47.284 AU 2002-AW197 [Planetoid]
47.783 AU 2005-RS43 [Planetoid]
47.820 AU 2007-JJ43 [Planetoid]
48.300 AU 2013-FZ27 [Planetoid]
49.620 AU 2010-RF43 [Planetoid]
49.871 AU 2003-QX113 [Planetoid]
51.431 AU 2001-UR163 [Planetoid]
55.535 AU 2002-TC302 [Planetoid]
57.740 AU 2004-XR190 [Planetoid]
59.100 AU 2013-FY27 [Planetoid]
62.100 AU 2010-RE64 [Planetoid]

Gliese 876[Bearbeiten | edit source]

0.000 AU Gliese 876 [Star, M4V]
0.021 AU Gliese 876 d [Planet]
0.130 AU Gliese 876 c [Planet]
0.208 AU Gliese 876 b [Planet]
0.334 AU Gliese 876 e [Planet]

82 G. Eridani[Bearbeiten | edit source]

0.000 AU 82 G. Eridani [Star, G8V]
0.121 AU 82 G. Eridani b [Planet]
0.204 AU 82 G. Eridani c [Planet]
0.350 AU 82 G. Eridani d [Planet]

Gliese 581[Bearbeiten | edit source]

0.000 AU Gliese 581 [Star, M3V]
0.028 AU Gliese 581 e [Planet]
0.041 AU Gliese 581 b [Planet]
0.072 AU Gliese 581 c [Planet]

Gliese 667 C[Bearbeiten | edit source]

0.000 AU Gliese 667 C [Star, M1.5]
0.050 AU Gliese 667 Cb [Planet]
0.125 AU Gliese 667 Cc [Planet]

61 Virginis[Bearbeiten | edit source]

0.000 AU 61 Virginis [Star, G7V]
0.050 AU 61 Virginis b [Planet]
0.218 AU 61 Virginis c [Planet]
0.576 AU 61 Virginis d [Planet]