The physics behind a moving car is that when fuel is sent to the engine from the fuel tank, the fuel injectors spray the fuel in the space above the pistons in the engine where it reacts with the air as combustion, pushing the pistons down. When that air is evacuated through the exhaust the pistons again come up and the process mentioned above repeats resulting in the circular movement of axle due to which the tires move.
Relative means it depends on the person's reference frame/point-of-view. For example, when you're in a moving car, your point-of-view tells you that the car is not moving at all (after all you're inside the car all the time, you only know the car is moving because the objects outside the car are moving against you). But another person standing on the sidewalk will see your moving car as moving at, say, 50 mph.
Examples of a load in physics include the weight of an object, the force exerted on a structure, or the tension in a cable or rope. Loads can be static, such as the weight of a book resting on a table, or dynamic, such as the force of a moving car on a bridge.
The physics behind cars involves concepts like friction, momentum, and aerodynamics. These factors influence a car's performance on the road by affecting its acceleration, braking, and handling. For example, friction between the tires and the road surface determines how quickly a car can stop, while aerodynamics impact its speed and fuel efficiency. Understanding these principles can help improve a car's overall performance and safety on the road.
The best that can be said is that you are moving relative to the Earth's surface.
In physics, rest refers to an object that is not moving or changing its position relative to a reference point.
Relative means it depends on the person's reference frame/point-of-view. For example, when you're in a moving car, your point-of-view tells you that the car is not moving at all (after all you're inside the car all the time, you only know the car is moving because the objects outside the car are moving against you). But another person standing on the sidewalk will see your moving car as moving at, say, 50 mph.
Kinetic energy- capable of movement. Inertia, when moving, and friction-brakes when slowing down.
The purpose of car brakes is to slow or stop the car when it is moving. They are use at intersection where there are traffic control signals to stop the car when a signal is red or to slow a vehicle when the cars in front are moving slower than the car behind.
You should always be looking behind you when backing up. You don't look forward when reversing because you're not moving in a forward direction.
the physics behind paper airplane is of aerodynamics
A moving object can not be used a a reference point because it has no fixed position.
Physics are definitely used when getting hit by a car. When getting hit by a car physics explains the injury.
A stopped car shouldn't hit anything because it's not moving. If a car hits the car behind it must have been in reverse and front ended the vehicle. In that case the car that front ended the vehicle is at fault.
well no that will hurt ur motor
Coming up behind a car at a faster speed and moving around said vehicle.
Examples of a load in physics include the weight of an object, the force exerted on a structure, or the tension in a cable or rope. Loads can be static, such as the weight of a book resting on a table, or dynamic, such as the force of a moving car on a bridge.
The physics behind cars involves concepts like friction, momentum, and aerodynamics. These factors influence a car's performance on the road by affecting its acceleration, braking, and handling. For example, friction between the tires and the road surface determines how quickly a car can stop, while aerodynamics impact its speed and fuel efficiency. Understanding these principles can help improve a car's overall performance and safety on the road.