Topic: FAO: Fora - Important 16bitch Update Regarding Recent Events.
16bitch !BMhSp1fpyA started this discussion 8 years ago #73,548
C = CircumferenceA = Surface Area
V = Volume
M = Mass
R = Radius
G = Surface Gravity
D = Density
E = Escape Velocity
L = Luminosity
S = Surface Temperature
T = Lifespan
Z = Goldilocks Zone
F = Frost Line
SPHERE MATH:
2 pi R = C
4 pi R^2 = A
4/3 pi R^3 = V
PLANETARY EQUATIONS:
AU = 149,597,871 km
G = M/R^2 = R(D)
EARTH:
M = 5.9724 x 10^24 kg
R = 6,378.1 km
G = 9.807 m/s^2
D = 5.514 g/cm^3
E = 11.19 km/s
C = 40,075 km
A = 510.1 million km^2
V = 108.321 x 10^10 km^3
JUPITER:
M = 1.89819 x 10^27 kg
R = 69,911.5 km
G = 24.79 m/s^2
D = 1.326 g/cm^3
E = 59.5 km/s
C = 439,264 km
A = 61.42 billion km^2
V = 143.128 x 10^13 km^3
STARS:
L = M^4
S = M^0.505
T = M^-2.5
Z = sq. rt. of L. The edges are 95% and 137% of Z.
F = 4.85 x sq. rt. of L
Sun:
M = 1.99 x 10^30 kg
R = 695,700 km
G = 274 m/s^2
D = 1.41 g.cm^3
E = 617.5 km/s
C = 4,366,803.66 km
A = 6.09 × 10^12 km^2
V = 1.41 x 10^33 cm^3
L = 3.828 × 10^26 watts
S = 5,800 kelvin
T =
TERRESTRIAL PLANETS:
M = 0.1 - 3.5
R = 0.5 - 1.5
G = 0.4 - 1.6
DWARF PLANETS:
M = 0.1 - 0.0001
R > 0.03
GAS GIANTS:
M = 10e - 13j
If (M = 2j - 13j), then R = 1j
Classical forms beyond 1 au past the frost line
Super forms 0.04 au from star to 1 au past frost line
Dwarfs form between 1 au past frost line and outer limit, usually more distant
ORBITS:
Semi-major axis (S) = avg. distance from planet to star
Eccentricity (E) = how circular the orbit is
Periapsis (P) = closest point to the star the orbit will be
Apoapsis (A) = farthest point from the star the orbit will be
Orbital Period (O) = length of time of orbit
Orbital Velocity (V) = speed of orbit
Inclination (I) = degree of orbit from orbital plane
Outer and inner limits are 0.1 the mass and 40 times the mass
Earth:
O = 365.24
I =
E = 0.0167086
P = 288.1
S =
A =
V =
0.584 x N^-1.2 = avg. E where N = number of planets
P = S(1 - E)
A = s(1 + E)
0 < E < 0.25
O = sq. rt. of (S^3 / M)
V = sq. rt. of (M / S)
For hot gas giants, A = 0.04 - 0.5 au, E = 0 - 0.05, O > 3 days
Semi-minor axis = S x sq. rt. of (1 - e^2)
Orbits ratios 1.4 -2, distance < 0.15 au
DWARF ORBITS:
Groups: resonant, classical, SDO, detatched, sednoids
Resonant orbits can be represented by two singly digit integers
Objects must be resonant with last gas giant and others in their order
Mostly: E < 0.25, I = 10 - 25
Anonymous C joined in and replied with this 8 years ago, 14 minutes later[^] [v] #875,378
Catherine !TGirlYJKXM joined in and replied with this 8 years ago, 12 minutes later, 26 minutes after the original post[^] [v] #875,381
Doesn’t m represent slope?
Grrrrrr replied with this 8 years ago, 7 minutes later, 33 minutes after the original post[^] [v] #875,382
Anonymous E joined in and replied with this 8 years ago, 5 minutes later, 39 minutes after the original post[^] [v] #875,384
@875,381 (Catherine !TGirlYJKXM)
Yes, you are 100% correct! There are only 26 characters in the alphabet with which to represent variables and by sheer coincidence there are also only 26 possible things in the universe which you want to represent in an equation. God is great!
Yes, you are 100% correct! There are only 26 characters in the alphabet with which to represent variables and by sheer coincidence there are also only 26 possible things in the universe which you want to represent in an equation. God is great!
Anonymous F joined in and replied with this 8 years ago, 25 seconds later, 39 minutes after the original post[^] [v] #875,385
Anonymous G joined in and replied with this 8 years ago, 9 minutes later, 48 minutes after the original post[^] [v] #875,390
@875,384 (E)
That is why English is such a piss poor language. Cambodia has 74 letters so there are 74 possible things in the universe which can be represented in an equation. God is still an hermaphrodite.
That is why English is such a piss poor language. Cambodia has 74 letters so there are 74 possible things in the universe which can be represented in an equation. God is still an hermaphrodite.
Anonymous H joined in and replied with this 8 years ago, 1 hour later, 2 hours after the original post[^] [v] #875,422
tripcode joined in and replied with this 8 years ago, 5 days later, 5 days after the original post[^] [v] #876,673
tripcode double-posted this 8 years ago, 20 seconds later, 5 days after the original post[^] [v] #876,674
Big Daddy Derek™ !Uvm54ORbmo joined in and replied with this 8 years ago, 6 hours later, 6 days after the original post[^] [v] #876,731
@OP
> Fora
Thanks for using my may-may™ (pronounced as one word)!
> C = Circumference
> A = Surface Area
> V = Volume
> M = Mass
> R = Radius
> G = Surface Gravity
> D = Density
> E = Escape Velocity
> L = Luminosity
> S = Surface Temperature
> T = Lifespan
> Z = Goldilocks Zone
> F = Frost Line
>
> SPHERE MATH:
>
> 2 pi R = C
> 4 pi R^2 = A
> 4/3 pi R^3 = V
>
> PLANETARY EQUATIONS:
>
> AU = 149,597,871 km
> G = M/R^2 = R(D)
>
> EARTH:
>
> M = 5.9724 x 10^24 kg
> R = 6,378.1 km
> G = 9.807 m/s^2
> D = 5.514 g/cm^3
> E = 11.19 km/s
> C = 40,075 km
> A = 510.1 million km^2
> V = 108.321 x 10^10 km^3
>
> JUPITER:
>
> M = 1.89819 x 10^27 kg
> R = 69,911.5 km
> G = 24.79 m/s^2
> D = 1.326 g/cm^3
> E = 59.5 km/s
> C = 439,264 km
> A = 61.42 billion km^2
> V = 143.128 x 10^13 km^3
>
> STARS:
>
> L = M^4
> S = M^0.505
> T = M^-2.5
> Z = sq. rt. of L. The edges are 95% and 137% of Z.
> F = 4.85 x sq. rt. of L
>
> Sun:
> M = 1.99 x 10^30 kg
> R = 695,700 km
> G = 274 m/s^2
> D = 1.41 g.cm^3
> E = 617.5 km/s
> C = 4,366,803.66 km
> A = 6.09 × 10^12 km^2
> V = 1.41 x 10^33 cm^3
> L = 3.828 × 10^26 watts
> S = 5,800 kelvin
> T =
>
> TERRESTRIAL PLANETS:
>
> M = 0.1 - 3.5
> R = 0.5 - 1.5
> G = 0.4 - 1.6
>
> DWARF PLANETS:
>
> M = 0.1 - 0.0001
> R > 0.03
>
> GAS GIANTS:
>
> M = 10e - 13j
> If (M = 2j - 13j), then R = 1j
> Classical forms beyond 1 au past the frost line
> Super forms 0.04 au from star to 1 au past frost line
> Dwarfs form between 1 au past frost line and outer limit, usually more distant
>
> ORBITS:
>
> Semi-major axis (S) = avg. distance from planet to star
> Eccentricity (E) = how circular the orbit is
> Periapsis (P) = closest point to the star the orbit will be
> Apoapsis (A) = farthest point from the star the orbit will be
> Orbital Period (O) = length of time of orbit
> Orbital Velocity (V) = speed of orbit
> Inclination (I) = degree of orbit from orbital plane
> Outer and inner limits are 0.1 the mass and 40 times the mass
>
> Earth:
> O = 365.24
> I =
> E = 0.0167086
> P = 288.1
> S =
> A =
> V =
>
> 0.584 x N^-1.2 = avg. E where N = number of planets
>
> P = S(1 - E)
> A = s(1 + E)
> 0 < E < 0.25
> O = sq. rt. of (S^3 / M)
> V = sq. rt. of (M / S)
>
> For hot gas giants, A = 0.04 - 0.5 au, E = 0 - 0.05, O > 3 days
>
> Semi-minor axis = S x sq. rt. of (1 - e^2)
>
> Orbits ratios 1.4 -2, distance < 0.15 au
>
> DWARF ORBITS:
>
> Groups: resonant, classical, SDO, detatched, sednoids
>
> Resonant orbits can be represented by two singly digit integers
> Objects must be resonant with last gas giant and others in their order
> Mostly: E < 0.25, I = 10 - 25
tl;dr
> Fora
Thanks for using my may-may™ (pronounced as one word)!
> C = Circumference
> A = Surface Area
> V = Volume
> M = Mass
> R = Radius
> G = Surface Gravity
> D = Density
> E = Escape Velocity
> L = Luminosity
> S = Surface Temperature
> T = Lifespan
> Z = Goldilocks Zone
> F = Frost Line
>
> SPHERE MATH:
>
> 2 pi R = C
> 4 pi R^2 = A
> 4/3 pi R^3 = V
>
> PLANETARY EQUATIONS:
>
> AU = 149,597,871 km
> G = M/R^2 = R(D)
>
> EARTH:
>
> M = 5.9724 x 10^24 kg
> R = 6,378.1 km
> G = 9.807 m/s^2
> D = 5.514 g/cm^3
> E = 11.19 km/s
> C = 40,075 km
> A = 510.1 million km^2
> V = 108.321 x 10^10 km^3
>
> JUPITER:
>
> M = 1.89819 x 10^27 kg
> R = 69,911.5 km
> G = 24.79 m/s^2
> D = 1.326 g/cm^3
> E = 59.5 km/s
> C = 439,264 km
> A = 61.42 billion km^2
> V = 143.128 x 10^13 km^3
>
> STARS:
>
> L = M^4
> S = M^0.505
> T = M^-2.5
> Z = sq. rt. of L. The edges are 95% and 137% of Z.
> F = 4.85 x sq. rt. of L
>
> Sun:
> M = 1.99 x 10^30 kg
> R = 695,700 km
> G = 274 m/s^2
> D = 1.41 g.cm^3
> E = 617.5 km/s
> C = 4,366,803.66 km
> A = 6.09 × 10^12 km^2
> V = 1.41 x 10^33 cm^3
> L = 3.828 × 10^26 watts
> S = 5,800 kelvin
> T =
>
> TERRESTRIAL PLANETS:
>
> M = 0.1 - 3.5
> R = 0.5 - 1.5
> G = 0.4 - 1.6
>
> DWARF PLANETS:
>
> M = 0.1 - 0.0001
> R > 0.03
>
> GAS GIANTS:
>
> M = 10e - 13j
> If (M = 2j - 13j), then R = 1j
> Classical forms beyond 1 au past the frost line
> Super forms 0.04 au from star to 1 au past frost line
> Dwarfs form between 1 au past frost line and outer limit, usually more distant
>
> ORBITS:
>
> Semi-major axis (S) = avg. distance from planet to star
> Eccentricity (E) = how circular the orbit is
> Periapsis (P) = closest point to the star the orbit will be
> Apoapsis (A) = farthest point from the star the orbit will be
> Orbital Period (O) = length of time of orbit
> Orbital Velocity (V) = speed of orbit
> Inclination (I) = degree of orbit from orbital plane
> Outer and inner limits are 0.1 the mass and 40 times the mass
>
> Earth:
> O = 365.24
> I =
> E = 0.0167086
> P = 288.1
> S =
> A =
> V =
>
> 0.584 x N^-1.2 = avg. E where N = number of planets
>
> P = S(1 - E)
> A = s(1 + E)
> 0 < E < 0.25
> O = sq. rt. of (S^3 / M)
> V = sq. rt. of (M / S)
>
> For hot gas giants, A = 0.04 - 0.5 au, E = 0 - 0.05, O > 3 days
>
> Semi-minor axis = S x sq. rt. of (1 - e^2)
>
> Orbits ratios 1.4 -2, distance < 0.15 au
>
> DWARF ORBITS:
>
> Groups: resonant, classical, SDO, detatched, sednoids
>
> Resonant orbits can be represented by two singly digit integers
> Objects must be resonant with last gas giant and others in their order
> Mostly: E < 0.25, I = 10 - 25
tl;dr