anorlunda said:Think of Newton's second law. F=ma. Express it as a=F/m. To produce a specific acceleration a you need a specific ratio of F to m. There is no v in that equation. So accelerating/decelerating a fast moving body is no different than for a slow moving body.
Changing or reversing direction is a different question. Why do you think it is more difficult to reverse a body moving at a velocity of 1, compared to reversing a body moving at a velocity of 100?
anorlunda said:Reversing a body with speed 1 means a net speed change of 2. (changing speed +1 to -1 is a net change of 2)
Reversing a body with speed 100 means a net speed change of 200.
anorlunda said:Let's start with you. What have you studied about physics and mechanics? I don't want to give answers you don't understand.
https://en.wikipedia.org/wiki/AerodynamicsSundown444 said:what factors make it hard for the car and aircraft to control at high speeds?
rootone said:
rootone said:You were asking what sort of factors need to be considered for designing a supersonic vehicle?
Sundown444 said:Need I say more?
anorlunda said:Yes, I said 1+1=2 and you asked me to elaborate. Do you not understand that?
anorlunda said:Yes, I said 1+1=2 and you asked me to elaborate. Do you not understand that?
It's not that hard but flight controls become hugely more sensitive at supersonic speed and a few millimeters of change are important.Sundown444 said:No, just factors that make it hard to control supersonic vehicles.
rootone said:It's not that hard but flight controls become hugely more sensitive at supersonic speed and a few millimeters of change are important.
At subsonic speed, typically passenger aircraft say, a few centimeters movement of flight of control surface is sufficient for control
rootone said:I'm no expert, but I think the answer is that a craft moving at supersonic speed is now facing head on collision with air molecules,
There no longer is any buffer of compressed air ahead of it, well not as much,
rootone said:As far as I know inertia does not enter into it,
friction does increase with speed though, I think that contributed to commercial SSTs being uneconomic (cool idea though)
Not true. The amount of speed change might be larger, but the effort to change speed, or accelerate are the same at any speed. That's why I pointed you to the equation F=ma in post #2. F=ma does not change with speed. Do you understand that or not?Sundown444 said:Normally, maneuvering and controlling at high speeds (slowing down, speeding up, stopping and changing direction) is very hard.
anorlunda said:Your original question was for car or airplane, so I assume you are not asking about aerodynamics.Not true. The amount of speed change might be larger, but the effort to change speed, or accelerate are the same at any speed. That's why I pointed you to the equation F=ma in post #2. F=ma does not change with speed. Do you understand that or not?
anorlunda said:I still don't understand the question. Please clarify. Are you asking about airplanes in the air, or about any fast moving object whether in air or space?
Inertia does not change with speed.
Sundown444 said:I meant air and space.
anorlunda said:That makes it easier, because in space we don't have to talk about drag from the air.
So the answer is no, faster motion is not harder to control. You can stop asking what factors make it harder, because it isn't harder.
Especially in space, get used to thinking of different frames of reference. An object moving fast in one frame is moving only slowly in a second frame, and not moving at all in a third frame. Yet the laws of physics remain the same in all frames. The difficulty of maneuvering a heavy object is the same in all frames. That is the kind of thinking (plus light speed) that eventually led Einstein to the special theory of relativity.
anorlunda said:If you keep changing the question I'm losing interest in answering. But one last time.
Remember the delta ##v## from post #6? Let's put it in terms of momentum which is ##mv##. Start at time 1 with momentum ##mv_1## then change to momentum ##mv_2##. The mass stays constant but velocity changes. Then the change in momentum is ##m(v_1-v_2)## If you let ##v_2## equal zero than means stopping. If you let ##v_2=-v_1## then we reversed direction.
The point is that the effort or work we need to do depends on the change in velocity, not the value of ##v_1##. So ##v_1## big means fast, ##v_1## small means slow. ##m(v_1-v_2)## is the same starting fast or slow. But stopping a fast object is more change in ##v## than for a slow object. But different observers moving at different speeds will disagree about what speed means stopped. So to say it observer independently, it is only the change that matters, not the initial velocity.Do you understand now?
Speed refers to how fast an object is moving, while velocity refers to both the speed and direction of an object's motion. For example, a car traveling at 60 miles per hour has a speed of 60 mph, but if it changes direction, its velocity will also change.
The type of vehicle can greatly impact its speed. For instance, a sports car is designed for speed and can reach higher velocities compared to a heavy truck. Additionally, factors such as aerodynamics, weight, and engine power also play a role in determining a vehicle's speed.
Speed and distance are directly related. The higher the speed, the greater the distance traveled in a given amount of time. This can be calculated using the formula: distance = speed x time. For example, a car traveling at 60 mph for 2 hours will cover a distance of 120 miles.
The higher the speed, the longer the stopping distance. This is because it takes longer for a vehicle to come to a complete stop when traveling at higher speeds. Other factors such as road conditions and the type of brakes also play a role in stopping distance.
Yes, speed can be measured accurately using various methods such as radar guns, speedometers, and GPS devices. However, external factors such as weather conditions and human error can affect the accuracy of speed measurements.