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What is the relationship between acceleration, initial velocity, final velocity, displacement, and time in a given motion, as described by the suvat equations?
The relationship between acceleration, initial velocity, final velocity, displacement, and time in a given motion is described by the suvat equations. These equations show how these variables are related and can be used to calculate one variable if the others are known. The equations are used in physics to analyze and predict the motion of objects.
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What is the relationship between velocity, time, and displacement when acceleration is constant?
When acceleration is constant, the relationship between velocity, time, and displacement can be described by the equations of motion. The velocity of an object changes linearly with time when acceleration is constant. The displacement of the object is directly proportional to the square of the time elapsed.
What are the equations of motion involving uniform acceleration?
The equations of motion involving uniform acceleration are: v = u + at, where v is the final velocity, u is the initial velocity, a is the acceleration, t is the time taken. s = ut + (1/2)at^2, where s is the displacement. v^2 = u^2 + 2as, where s is the displacement. These equations describe the relationships between initial velocity, final velocity, acceleration, displacement, and time during motion with uniform acceleration.
What are the three equations of motion which of them describe velocity time relation?
The three equations of motion are: ( v = u + at ) (relates initial velocity, acceleration, and time) ( s = ut + \frac{1}{2}at^2 ) (relates initial velocity, acceleration, and displacement) ( v^2 = u^2 + 2as ) (relates initial and final velocity, acceleration, and displacement) The first equation, ( v = u + at ), describes the relationship between velocity and time.
Can kinematics equations bs used in situation in which the acceleration is zero?
Yes the equations of Kinematics can be used if accelration varies with time, displacement or even velocity; but remember it's not just plug & chug, you will have to integrate the equations. vdv=ads ds/dt=v dv/dt=a d2s/dt=a
What is the relationship between initial velocity, acceleration, and time in the kinematic equations for distance?
In the kinematic equations for distance, the relationship between initial velocity, acceleration, and time is that the distance traveled is determined by the initial velocity, the acceleration, and the time taken to travel that distance. The equations show how these factors interact to calculate the distance an object moves.
What is the relationship between velocity, time, and displacement when acceleration is constant?
When acceleration is constant, the relationship between velocity, time, and displacement can be described by the equations of motion. The velocity of an object changes linearly with time when acceleration is constant. The displacement of the object is directly proportional to the square of the time elapsed.
What are the equations of motion involving uniform acceleration?
The equations of motion involving uniform acceleration are: v = u + at, where v is the final velocity, u is the initial velocity, a is the acceleration, t is the time taken. s = ut + (1/2)at^2, where s is the displacement. v^2 = u^2 + 2as, where s is the displacement. These equations describe the relationships between initial velocity, final velocity, acceleration, displacement, and time during motion with uniform acceleration.
What are the three equations of motion which of them describe velocity time relation?
The three equations of motion are: ( v = u + at ) (relates initial velocity, acceleration, and time) ( s = ut + \frac{1}{2}at^2 ) (relates initial velocity, acceleration, and displacement) ( v^2 = u^2 + 2as ) (relates initial and final velocity, acceleration, and displacement) The first equation, ( v = u + at ), describes the relationship between velocity and time.
Can kinematics equations bs used in situation in which the acceleration is zero?
Yes the equations of Kinematics can be used if accelration varies with time, displacement or even velocity; but remember it's not just plug & chug, you will have to integrate the equations. vdv=ads ds/dt=v dv/dt=a d2s/dt=a
What is the relationship between initial velocity, acceleration, and time in the kinematic equations for distance?
In the kinematic equations for distance, the relationship between initial velocity, acceleration, and time is that the distance traveled is determined by the initial velocity, the acceleration, and the time taken to travel that distance. The equations show how these factors interact to calculate the distance an object moves.
What is the relationship between the variables in the suvat equations used to describe motion?
The suvat equations used to describe motion show the relationship between the variables of displacement (s), initial velocity (u), final velocity (v), acceleration (a), and time (t). These variables are interconnected and can be used to calculate different aspects of an object's motion.
What physics quantities do the kinematic equations describe the relationship between?
The kinematic equations describe the relationship between distance, time, initial velocity, final velocity, and acceleration in physics.
What is the derivation of the suvat equation used in physics to describe the motion of an object under constant acceleration?
The suvat equation is derived from the equations of motion in physics, specifically from the kinematic equations that describe the motion of an object under constant acceleration. It is a set of equations that relate the initial velocity (u), final velocity (v), acceleration (a), displacement (s), and time (t) of an object in motion.
What is constant retardation in physics?
Constant retardation is a type of motion where an object is slowing down at a steady rate. This means that the acceleration in the opposite direction of motion is constant. It can be described by equations such as (v = u + at) and (s = ut + 0.5at^2), where (v) is the final velocity, (u) is the initial velocity, (a) is the constant acceleration, (t) is the time, and (s) is the displacement.
What is the relationship between displacement and time?
There is no direct relationship between the two. Newton's Second Law, though, tells you how the VELOCITY of an object will change when a force is applied. The law - as it is usually quoted - says:F = ma Solving for acceleration: a = F/m So, the acceleration of an object will depend on the force. If you integrate this equation twice, you get the displacement - but the integration will also give you two arbitrary integration constants, meaning that you need to know the initial conditions (initial position, and initial velocity).
How to derive the kinematic equations for motion in one dimension?
To derive the kinematic equations for motion in one dimension, start with the definitions of velocity and acceleration. Then, integrate the acceleration function to find the velocity function, and integrate the velocity function to find the position function. This process will lead to the kinematic equations: (v u at), (s ut frac12at2), and (v2 u2 2as), where (v) is final velocity, (u) is initial velocity, (a) is acceleration, (t) is time, and (s) is displacement.
How do you calculate the displacement of an object when the object's initial velocity constant acceleration and time of travel are known?
By using one of the simple equations of motion. s = ut + 1/2 at2
