Calculations
Even more Lego Star Wars calcs. Again, across multiple Lego Star Wars titles (The Force Awakens, The Skywalker Saga and Lego Star Wars: The Freemaker Adventures).

1. Random person survives Hosnian Prime exploding

If anyone tries to say that the Stormtrooper surviving the first Death Star exploding is an outlier, then my response is...no it isn't. :NOnon


22:00



A random person survives the destruction of the Hosnian System while on the toilet. I couldn't find an official value for the diameter of Hosnian Prime, so we'll have to figure this out some. Thankfully, we can see that Hosnian Prime has an atmosphere in the movies, so from that we can determine a minimum size. To copy and paste the work I did in an earlier calc, according to this link, the smallest habitable planet would have 0.0268% the mass of the Earth (that being 6 x 10^24kg). That page also has a nice diagram, so let's scale the minimum size too. The diameter of the Earth is 12756.2km.
wk8BUIT.png
261 pixels = 12756.2km
1 pixel = 12756.2km/261 = 48.8743295km
48.8743295km X 114 = 5571.67356km

M = 6.0e24kg X 0.0268%
= 1.60800e21kg

Now...to scaling the explosion.
tsJ3vEL.png
274 pixels = 5571.67356km
5571.67356km/274 = 20.334575km
DCDBO7z.png
20.334575km X 471 = 9577.58483km

We have our distance, but it's useless without a timeframe.
UfzSsbc.png

XU4a8cl.png
Timeframe is 3 seconds and 1 frame.

T = 1s/24
= 41.6666667ms + 3s
= 3.04166667s

T = 9577.58483km/3.04166667s
= 3148795.01m/s

KE = (0.5)mv^2
= (0.5) X 1.60800e21 X 3148795.01^2
= 7.97158765e33 joules

Now we have that, we'll need to find the surface area of the planet so we can find the amount of energy our friend tanked.

R = 5571.67356km/2
= 2785.83678km (2785836.78m)

A = 4πr^2
= 4 X π X 2785836.78^2
= 9.75261769e13m^2

As for the surface area of our minifigure, we've already got all of the scaling figured out last time! The surface area of the head is 0.109472705m^2, the surface area of the torso is 0.266548605m^2, the surface area of the hips is 0.0562548643m^2 (0.0425102986m^2 + 0.0137445657m^2) and the surface area of the legs is 0.27302389m^2.

A = 0.109472705 + 0.266548605 + 0.27302389 + 0.0562548643
= 0.705300064m^2

E = 0.705300064/2785836.78
= 2.53173506e-7 X 7.97158765e33
= 2.01819479e27 joules
= 482.36013145315490647 petatons

Now let's go with a high end of an Earth-sized planet. The Earth has a diameter of 12,756km. Once again we refer to the above scaling...

274 pixels = 12,756km
1 pixel = 12,756km/274 = 46.5547445km
46.5547445km X 471 = 21927.2847km

T = 21927.2847km/3.04166667s
= 7208970.3m/s

The mass of the Earth is 6.0e24kg.

KE = (0.5)mv^2
= (0.5) X 6.0e24 X 7208970.3^2
= 1.55907758e38 joules

E = 0.705300064/2785836.78
= 2.53173506e-7 X 1.55907758e38
= 3.94717137e31 joules
= 9.4339659894837470944 zettatons

2. Yoda calls down lightning

Now we have ample power feats. What about speed feats?



Yoda calls down a lightning strike, which sets the Jedi tree on fire. This causes an explosion bigger than the tree. As previously calculated, the average height of a Star Wars minifigure is 1.59511582m.
W35MaZa.jpg
278 pixels = 1.59511582m
1 pixel = 1.59511582m/278 = 0.00573782669m
0.00573782669m X 1470 = 8.43460523m
GTgUSqC.png
28 pixels = 8.43460523m
1 pixel = 8.43460523m/28 = 0.301235901m
0.301235901m X 862 = 259.665347m
ZiQPcKE.png
v5dDlTD.png
The timerame is 1 frame.

T = 259.665347m/41.6666667ms
= 6231.96832/340.29
= Mach 18.3136981

3. Holy fucking shit



Naare using the Kyber Saber cuts a moon in half. First things first, let's get the timeframe.
Cqr0VG3.png

hXIkfvD.png
Timeframe is 1 second and 1 frame.

T = 41.6666667ms + 1s
= 1.04166667s
With that in our hands, we go to the much harder task of finding the size and mass of that moon. According to this link here, the absolute low end minimum size of a rocky round planetoid is 600km in diameter.

208 pixels = 600km
1 pixel = 600km/208 = 2.88461538km
object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
= 2*atan(208/(600/tan(70/2)))
= 0.325604053 rad
= 18.6557380293002488 degrees

Entering that into the angscaler calculator and we get a distance of 1826.4km.

T = 1826.4km/1.04166667s
= 1753343.99/340.29
= Mach 5152.49931

Now we need the mass of the moon, using inverse-square law from our own moon, which has a mass of 7.35e22kg (as per above).

M2 = (H2/H1)^3*M1
= (600000/3474800)^3*7.35e22
= 3.78400457e20kg
izQYLEj.png

yl07EQY.png

Timeframe is 1 second and 10 frames.

T = 41.6666667ms X 10
= 0.416666667s + 1s
= 1.41666667s

2.88461538km X 100 = 288.461538km

T = 288.461538km/1.41666667s
= 203619.909m/s

KE = (0.5) X 3.78400457e20 X 203619.909^2
= 7.84444341e30 joules
= 1.8748669717973232007 zettatons

Let's also go with a high end with the dimensions of our moon, which has a diameter of 3475km. Entering that into the angscaler again and we get a distance of 10578km.

T = 10578km/1.04166667s
= 10154880/340.29
= Mach 29841.8408

T = 3475km/1.41666667s
= 2452941.17m/s

KE = (0.5)mv^2
= (0.5) X 7.35e22 X 2452941.17^2
= 2.21121824e35 joules
= 52.849384321223709549 yottatons

The high end is most likely, as the first-most one is well within the Roche limit (for both an Earth-sized planet and a Mars-sized planet).

4. Baird Kantoo slices a Moon in half

3:23
99j7L3.gif
Baird Kantoo slices a moon in half by accident with the Kyber Saber, and is so horrified that he splits it apart so it can never do any harm again. We already have the values for our size and mass, so let's just get our values for distance.
tgIgHqb.png
object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
= 2*atan(97/(670/tan(70/2)))
= 0.136979527 rad
= 7.8483487768177751 degrees

That gives us a distance of 4373.4km for our low end and 25329km for our high end.
FwihSMz.png

4hHrXYd.png
Timeframe is 3.46 seconds.

(Low end)
T = 4373.4km/3.46s
= 1263988.44/340.29
= Mach 3714.44486

(High end)
T = 25329km/3.46s
= 7320520.23/340.29
= Mach 21512.5929

Now with our speed, let's also get our energy.
SGuPbNf.png
IHZOpHT.png
Timeframe is 1.21 seconds. We'll need to half the distance, as that's the distance each half travelled.

(Low end)
54 pixels = 600km
1 pixel = 600km/54 = 11.1111111km
11.1111111km X 63 = 699.999999km
699.999999km/2 = 350km

T = 350km/1.21s
= 289256.198m/s

KE = (0.5)mv^2
= (0.5) X 3.78400457e20 X 289256.198^2
= 1.58302219e31 joules
= 3.7835138384321225224 zettatons

(High end)

54 pixels = 3475km
1 pixel = 3475km/54 = 64.3518519km
64.3518519km X 63 = 4054.16667km
4054.16667km/2 = 2027.08334km

T = 2027.08334km/1.21s
= 1675275.49m/s

KE = (0.5)mv^2
= (0.5) X 7.35e22 X 1675275.49^2
= 1.03140638e35 joules
= 24.651204110898664368 yottatons

Final Results
Generic minifigure survives the destruction of Hosnian Prime (low end) = 482.360 petatons
Generic minifigure survives the destruction of Hosnian Prime (high end) = 9.434 zettatons
Yoda calls down lightning = Mach 18.314
Naare slices a moon in half (speed - low end) = Mach 5152.499
Naare slices a moon in half (speed - high end) = Mach 29841.841
Naare slices a moon in half (energy - low end) = 1.875 zettatons
Naare slices a moon in half (energy - high end) = 52.849 yottatons
Baird Kantoo slices a Moon in half (speed - low end) = Mach 3714.445
Baird Kantoo slices a Moon in half (speed - high end) = Mach 21512.593
Baird Kantoo slices a Moon in half (energy - low end) = 3.784 zettatons
Baird Kantoo slices a Moon in half (energy - high end) = 24.651 yottatons
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