You have to solve Newton's equation ΣF=ma in order to find the velocity and displacement vectors.
Velocity is a vector quantity that includes both speed and direction. To convert speed to velocity, you need to include the direction in which the object is moving. So, the equation for converting speed to velocity is velocity = speed * direction, where direction is a unit vector indicating the object's direction of motion.
To find the acceleration of a particle using the vector method, you can use the equation a = r x (w x v), where "a" is the acceleration, "r" is the position vector, "w" is the angular velocity vector, and "v" is the velocity vector. The cross product (x) represents the vector cross product. By taking the cross product of the angular velocity vector with the velocity vector and then multiplying the result by the position vector, you can find the acceleration of the particle.
The result of subtracting one velocity vector from another velocity vector is a new velocity vector. This new vector represents the difference in speed and direction between the two original velocity vectors.
The equation for resultant velocity is the vector sum of all individual velocities acting on an object. Mathematically, it can be represented as Vr = V1 + V2 + V3 + ..., where Vr is the resultant velocity and V1, V2, V3, etc. are the individual velocities. This equation takes into account both the magnitude and direction of each velocity component to determine the overall resultant velocity of the object.
A vector. Since velocity is a vector, moment, which is mass x velocity, is also a vector.
Because it's a type of velocity and velocity is vector quantity
True ,velocity is a vector quantity ,it is specified by a magnitude and direction.
Yes, angular velocity is a vector quantity
Instantaneous velocity is a vector quantity.
Velocity is an indication of a speed, including a direction. It is a vector because that is how a vector is defined (a magnitude, including a direction).
The result will also be a velocity vector. Draw the first vector. From its tip draw the negative of the second vector ( ie a vector with the same magnitude but opposite direction). The the resultant would be the vector with the same starting point as the first vector and the same endpoint as the second. If the two vectors are equal but opposite, you end up with the null velocity vector.
Momentum is a vector quantity because the definition of momentum is that it is an object's mass multiplied by velocity. Velocity is a vector quantity that has direction and the mass is scalar. When you multiply a vector by a scalar, it will result in a vector quantity.