That was with a aero-glitch tho. All the things that was in fron og his cockpit had hitboxes that negated the aero, thus rendering the cockpit aero-less when detatched.

​@@megatryn didn't realize that, nice catch!

Ikr 🤣🤣🤣

@@megatryn he still did break it with out trying to so that means he did it in a fair way

@@Jump_Today Rightly so, I was just explaining the reason why he managed to and the glitch.

Touching it wasn't worth the risk of waiting 5 more minutes, he would have gained maybe 30 km/h.

The weight simply won’t matter whatsoever as long as the drag is same. In vacuum no matter the shape everything falls the same speed.

​@@alkestos except it does matter in this case. Gravity accelerates all things at the same rate, that is true. And aerodynamic drag force vs speed is essentially the same in the 2 weighted builds Kan tried. However Acceleration = Force/mass (f=ma rearranged) so the force of drag has a lesser acceleration (decelleration) affect in the heavier vehicle for the same given velocity. Terminal velocity is reached when the drag decelleration = gravity = 9.81m/s2 (on earth), which for a heavier object requires a larger aerodynamic force which the vehicle must be travelling faster to occur.

You can see what ​@@Dakakeisalie's talking about in the video as Kan's accelerating noticably faster on attempt 3 at 1300kph than attempt 2 at 1100kph.

@@alkestos yes, if drag is 0 aka vacuum, it does not matter and there is no terminal velocity in a vacuum either, but A=(W-D)/m, W=g*m, so you can rewrite it as a=g-D/m. As you increase mass, you'll increase the acceleration as long as you don't also increase drag.

If the terminal velocity is higher then it by definition falls faster

I got a scam reply on this from a fake account called @fficial_KanGaming so thanks for removing it

Choo choo.

True. Can't believe it's been 11 years, since he jumped from space down to earth. Crazy guy. 😆

@@error404fnf As a fellow countryman of Felix, I'm glad, someone mentioned is name, and I'm kinda bummed, that kAN didn't know. Yeah, has been a while, hasn't it? And what an event that was! Felt like the moon landing! xD It was amazing! :) And I'm still super proud lol

@@loerichson But to be fair, it's kinda hard to follow all the craziness going on, on earth. For example: If a coworker of mine didn't mention the SpaceX program, I would have totally missed the lauch of the first roket. And boy, what a show this was.

@@error404fnf sure, absolutely, especially these days, eh? ^^ Oh, yeah, didn't know about it either until after the fact. It's funny though, how on the one hand they said it was a 'failure' because it blew up, and then on the other side they said, it was a 'success' because it managed to take off. And You as a pleb sit in the middle and think, 'So what is it now? Yay, fireworks!' lol

Assuming the same coefficient of drag and area, more mass does make an object accelerate faster. If it didn't, they would have the same terminal velocity. If the object is moving in air, and the force from drag is identical, but the force due to gravity is larger for one, that means the net force is larger for it so it will accelerate faster. The easiest way to consider it is by considering the 2 options are the terminal velocity of the lighter craft. The lighter craft has the forces balanced so it is at terminal velocity, i.e. its acceleration is 0. The heavier object has a greater force due to gravity so it is accelerating at a different rate.

It also increases acceleration, in a manner of speaking. Decreases it slower would be more accurate, since obviously maximum acceleration of the object is at v=0. It's also correct that Fd will be dependent on velocity, and not mass, however, the action of Fd against an object is directly proportional to its mass.

This is incorrect. Since you want the math approach, there are multiple forces to consider. First we have the force due to gravity, as F=g*m. Then we have the force due to air resistance, which we can simplify down assuming the objects are identical in size and shape. Depending on how simple you want to go, you can have F=c*rho*A*v^2/2, or F=k*v^2. These are in different directions, so we have the net force as: F=g*m-k*v^2. And we know that F=m*a, so: F=g*m-k*v^2=m*a a=g-k*v^2/m Notice the dependence on m in the acceleration. For any non-zero velocity, the acceleration will be greater for the heavier object. This is because there is the same upwards force due to air resistance, but a greater downwards force due to gravity.

@@scottwalker6386 The "action" of drag against the object is not directly proportional to mass. If you take action to be force, it is not related to mass. If you take it to be acceleration, then it is inversely proportional to mass.

@@jeffreyblack666 Action of F *is* acceleration. And you're correct, the relationship is inversely proportional from the perspective of the acceleration due to gravity, or directly proportional from the perspective of the acceleration due to drag (in the opposite direction)

@@scottwalker6386 Wrong again. If you are talking about the action of a force, then for gravity the relationship is constant. That is because F=m*g=m*a, so a=g, with no dependence on mass. It is proportional to mass if you are talking about force instead of acceleration. For air resistance, it is inversely proportional, because a larger object requires a greater force to accelerate it (or decelerate it). Being in the opposite direction does not make it directly proportional. Directly proportional means that if you double the mass you double the result. So that would require a heavier object to be more affected by the air.

TLDR; The difference between a falling piece of paper and a falling scrunched up piece of paper. Try it at home if you doubt me. Man, I made that harder than necessary...

I think Scrapman already did that one

@@edopronk1303 ah, I'll have to take a look at his channel then.

I believe scrapman has that happen when he tried to break sound barrier with ballons

It does and it MASSIVELY reduces your max speed

It doesn't affect acceleration. A hammer and a feather dropped in a vacuum would hit the ground at the same time.

Force of gravity does not scale with mass. However, air resistance works against momentum, which means mass affects acceleration due to gravity in an atmosphere.

​@@floppaquest4916 it does in an atmosphere. Air resistance works against momentum.

It would, just based off of force balancing. Wouldn't affect initial (and also maximum) acceleration as that's limited by gravity and additional forces.

@@covenantslayergaming6362 Would at v=0, you mean. Ag will always = 9.8m/s^2 (within the parameters of our experiment), and drag will be based on velocity of object, coefficient of drag, and drag cross-section. However, the drag force's ability to work against the mass of the object being pulled by gravity will apply a different amount of Newtons (and thus reverse acceleration) with different masses. But yes- maximum acceleration is indeed dictated by gravity, and flow velocity. At v=0, A = G.

Sure will. F=ma. It won't affect F, but it'll affect how much F can change the acceleration of the object due to gravity.

If it doesn't change the acceleration, how can it change terminal velocity. Terminal velocity is when acceleration reaches 0. So if the acceleration is the same, terminal velocity has to be.

@@jeffreyblack666 It doesn't affect the acceleration from gravity, it affects the air resistance. The acceleration remains the same from gravity while the air resistance is less effective against a heavier object with the same air resistance. It depends on if you're looking at the acceleration from gravity or just 'acceleration' in general, both can be technically correct.

@@rallok2483 There is no reason to look at just gravity. It goes to a pointless technicality, which doesn't correspond to anything physical. There is an object which is being acted on by air and gravity. The acceleration of that object is being discussed, and should be considered with both air resistance and gravity. And that acceleration changes if you change the mass. There is also no need to put acceleration in quotes like that.

Yeah.. Accidentally

It would stabilise it but the added air resistance would make it a lot harder to reach the speed of sound. Rifling on rounds adds to the aerodynamic stability, making it fly straighter. This would not help to fall quicker and would actually be a hinderance. (No idea if this is how it would work in Trailmakers, but this is how it would work in real life) I think I understand what you were trying to think but the spin stabilisation would also cause slightly more drag due to an increased air velocity over the surface of the vehicle as the air would be traveling root( fall speed^2 + surface rotational velocity^2 ) and the surface drag would be greater than the drag going ‘straight’. It wouldn’t be a lot as the spin would have to be very fast to severely impact it, but it would have some adverse effects. In the real world, the effects of the increase in surface drag would mainly come from the heating of the outside of the vehicle, with the transfer of heat energy into the vehicle being energy that is not kinetic energy. Bullets do not suffer greatly from this as they are traveling very fast with very little surface rotational velocity as that is proportional to the radius (which is quite small compared to a vehicle)

@@communistpingu5255 thank you just an idea

@kAN Gaming you might have a scammer in your comments

Scrapman also did this with a giant lawndart contraption.

@@Core-1948 I believe that was one of his workshop videos. And yes, that inspired the falling part of my contraption, allthough mine was a much simpler design. I don't know if some update changed the physics or if the creator just wanted it to look cool, but it was way bigger than it needed to be.

Acceleration does decrease gradually though, when you're near terminal velocity. So even though he didn't quite reach terminal velocity, just adding a bit more mass would already have been enough to exceed the speed of sound.

@@Nomiswelt Do you mean it decreases over time or with mass difference? Because yeah the acceleration will decrease slower with higher mass but that difference would be negligible

@@laurensholthof What I was trying to say is during free fall all the way up to terminal velocity, the acceleration isn't constantly 9,81m/s² until you reach terminal velocity and then it suddenly jumps to 0m/s². The higher your speed, the more aerodynamics will play a role and decrease acceleration. This is especially noticeable near terminal velocity, as your speed gradually levels off

I think the acceleration of a falling object as a function of its velocity follows a quadratic function (as drag is proportional to velocity squared) which has its maximum at v=0m/s with a=9,81m/s². "a" (the coefficient of the quadratic term) is negative and directly proportional to the mass of the object. If you draw this function (y = a*x² + 9,81 with y being acceleration and x being velocity) in GeoGebra or something similar you can alter the "a" in the formula and see how exactly the acceleration changes (remember, "a" is directly proportional to mass). For a terminal velocity of somewhere around the speed of sound (343m/s) "a" should be about -1*10^(-4).

@@Nomiswelt Yeah ofc, FD =(1/2)ρ*CD*A and if v increases so does FD, but let's say his terminal velocity with m1 (mass on first aircraft) is v1 and his terminal velocity with m2 is v2. Gravitational force will be lower for his first machine, so the drag vector will have the same magnitude as the Fg vector sooner. In m2, at v1, the object isn't at terminal velocity yet but has the same amout of drag as m1 in that moment. Fg is greater with m2 so it will take longer for the resulting vector to become 0N and the acceleration to be 0m/s², but because the drag increase is exponential (v is squared), the closer you get to v1 the further the accelerations will drift apart. Because he hasn't reached terminal velocity, however, could the argument be made that the delta between accelerations is not big enough to cause a sizablr difference in speed at impact. Sorry for the long-winded and confusing text, this was written on my phone

Bacon

and he also did this recently.ACCIDENTALLY.

@@Damian-cilr2 ik i just pointed it out also you need to calm down a bit

That's not because of weight but because of aerodynamics. If you have a metal cube and a hollow metal cube of same dimension, both will fall the same speed

Yes the feather just has a lot more drag, if it was in a vacuum they would fall the same speed.

@@xelspeth it does make a difference when auerodynamics are significant. If you drop your metal cube and hollow metal cube from high up enough, the hollow one will hit the ground later. You are correct in a vacuum tho

​@@xelspeth It is because of both. If you have a solid metal cube and a hollow metal cube of the same dimensions, and drop them in an atmosphere (or fluid) the hollow metal cube will fall slower as soon as air resistance becomes significant. You can try this with an alfoil cube, vs a solid block of aluminium

I didnt say a vacuum or a hallow cube and even if there was a hallow cube and a solid one, they both might be close to the same speed if you drop them but the heavier one will allways be slightly faster because thats just how gravity works

This is the best way to put it. Acceleration is highest at velocity = 0, but the more mass the object has, the slower it will decelerate. i.e., if you have 2 objects with the same coefficient of drag and drag cross-section (and thus same aerodynamic drag), but different masses (and hence different terminal velocities), which will reach the terminal velocity of the less massive object first? The more massive object. The more massive object will in fact decelerate slower. It'll only become appreciable at pretty high speeds, though.

No, they accelerated at a greater rate. If they accelerated at the same speed they would reach terminal velocity at the same speed. The only way to exceed the terminal velocity of the original is by having the acceleration be different (so it is not 0 at the terminal velocity of the lighter object).

Yeah but this is different aerodynamics has changed kid

@@-LAWAN kid 🙂

@@alakabis yes your a kid

@@-LAWAN i wish :/

at least i'm acting like one 😃

As terminal velocity is when acceleration is 0, it is impossible to affect terminal velocity of a falling object without also affecting accleration.

Bullets make noise and they're just flying through the air