While 15.077m is technically above 10m, it's always alright to also go with a low end. Scaling the height of the Barn and the surrounding cliffs based off the above scans...LFO
It is a huge humanoid mobile machine with a total height of more than 10m, and its official name is Light Finding Operation. A humanoid object called an archetype excavated from the ground is used as a movable skeleton, and machinery and armour are attached to enable human control. In addition to being able to fly in the air using a rift board type flight unit, there are many aircraft that can be transformed into the beagle mode, which is a ground travelling form.
= 2*atan(3081/(1577/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
= 2*atan(145/(1421/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
= 2*atan(332/(492/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
= 2*atan(372/(492/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
A boarding ship of the Ageha Corps led by Dewey. She is a huge cone-shaped battleship with a total length of more than 1.5km, equipped with many powerful weapons, and has excellent offensive and defensive performance such as a powerful barrier that repells the main gun of the Moonlight. She carries Tye-THEEND and several Monsoono Type VC-10s.
As it's a complete whiteout, I think it's safe to use the luminousity of the Sun (that being 100,000 lux). The conversion factor from lux to apparent magnitude is -2.5 log I - 14.2.M(star) is the apparent magnitude of the light source
m= is the apparent magnitude of the sun (-26.73)
L(star) is the Luminosity
L= Luminosity of the sun (3.486*10^26)
d= Distance to the sun from earth (0.000004731537734207877 parsecs)
d(star)= distance to the light source
= 2*atan(7740.98162/(1772/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
Nirvash Type-Zero Spec-1 in it's vehicle mode can travel at 300km/h (although in mecha mode it can go faster, or at least in sustained bursts). 300km/h is 83.3333333m/s, so that's our calc done for us! But that's not all, we also have the mass of Nirvash (21.4 tons, or 21400kg), so we can also get kinetic energy.
- Overall Height: 14.7m (LFO mode), 2.8m (vehicle mode)
- Weight: 21.4t
- Maximum Output: 4000/ 120~ 150 9PS/bpm
- Maximum Speed: 300 km/h (vehicle mode)
- Seating Capacity: 2 persons
KE = (0.5)mv^2
- Overall height: 13.7m (LFO mode), 2.6m (vehicle mode)
- Weight: 21.3t
- Maximum Output: 3400/110~140 (PS/bpm)
- Maximum Velocity: 280 km (vechicle mode)
- Seating Capacity: 2 persons
KE = (0.5)mv^2
- Overall Height: 14.2 (LFO mode), 2.7m (vehicle mode)
- Weight: 23.1t
- Maximum Output: 4100/110~130(PS/bpm)
- Maximum Velocity: 260 km (vehicle mode)
- Seating Capacity: 1 person
KE = (0.5)mv^2
- Overall Height: 14.2m (LFO mode), 2.7m (vehicle mode)
- Weight: 23.3t
- Maximum Output: 3800/110~160 (PS/bpm)
- Maximum Velocity: 300 km (vehicle mode)
- Seating Capacity: 1 person
= 2*atan(169/(605/tan(70/2)))object degree size = 2*atan(Object_Size/(Panel_Height/tan(70/2)))
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