We suspect that you're also given a line on the graph. If so, then the initial speed
is the slope of the line at the initial position. To get the real slope of the line, you
need to know the scales of the axes. If the scales aren't the same, then the real
slope of the line isn't what it looks like, and has to be calculated by measuring its
progress along both axes just after the initial position.
To calculate the initial velocity given only the initial position and the scale of the axes, you would need additional information such as the time of flight or the maximum height reached by the object. Without this additional data, it is not possible to determine the initial velocity.
To calculate resultant velocity, you would need to determine the magnitude and direction of the individual velocities that are involved. Then, you can use vector addition to find the resultant velocity by adding the velocities together considering both magnitude and direction.
Vertical acceleration is the rate of change of velocity moving up or down, while horizontal acceleration is the rate of change of velocity moving left or right. Vertical acceleration is affected by gravity, while horizontal acceleration is typically due to external forces like friction or thrust.
Vertical and horizontal
The horizontal velocity component can be found using the equation: horizontal distance = horizontal velocity * time. The vertical velocity component can be calculated using the equation: vertical height = (initial vertical velocity * time) + (0.5 * acceleration due to gravity * time^2). The total velocity is the vector sum of the horizontal and vertical velocity components.
vertical
No, horizontal velocity does not affect the rate of vertical velocity. Each component of velocity (horizontal and vertical) is independent of the other. They act separately to determine the motion of an object.
When a projectile's horizontal and vertical velocities are independent, it means that the horizontal velocity does not affect the vertical velocity, and vice versa. This means that the projectile will continue to move horizontally at a constant velocity regardless of its vertical motion, and its vertical motion will be affected only by gravity.
This is not always true. High velocity pumps can be found in horizontal configurations too. It all depends on the application (sometimes the manufacturer) whether it will be a horizontal of vertical pump.
9.8
Yes, in projectile motion, the vertical component of motion is influenced by the initial velocity in the vertical direction. The horizontal and vertical components of motion are independent of each other, with the horizontal component being influenced by the initial velocity in the horizontal direction.
If the initial velocity is v, at an angle x to the horizontal, then the vertical component is v*sin(x) and the horizontal component is v*cos(x).
The horizontal component of velocity for a projectile is not affected by the vertical component. They are independent of each other. The horizontal velocity remains constant as long as there are no external forces acting on the projectile.
13
At the top of its trajectory, a projectile's vertical velocity is momentarily zero, while its horizontal velocity remains constant. The speed of a projectile at the top of its trajectory can be determined by calculating the magnitude of its velocity vector using the horizontal and vertical components of velocity.
It means that the vertical motion of the projectile (up or down) does not affect the horizontal motion (left or right), and vice versa. The vertical velocity is influenced by gravity, while the horizontal velocity remains constant unless acted upon by an external force.
Yes, a body can possess velocity in both horizontal and vertical directions simultaneously. This is known as projectile motion, where an object is moving in a parabolic path due to a combination of horizontal and vertical velocities.
Vertical is defined as the direction or position that is perpendicular to the plane. Horizontal is defined as to be parallel to the horizon.