Want this question answered?
The larger the force pulling on a spring, the greater the length in the spring and the more energy that is stored in that spring. When looking at a spring there is a gradient that determines how much force much be used to sqeeze or stretch a spring a given amount. When a spring is stretched, the greater the force that is applied, the greater the change in length of the spring and the greater the amount of energy that is stored in the spring. A link is supplied to the Wikipedia article on the spring (device).
More the curvature of the eye lens, lesser the focal length is. Lesser the curvature, greater the focal length is
A pendulum with a period of five seconds has a length of 6.21 meters.
you have to know the wave length.
The Object moving down the Ramp will have its POTENTIAL Energy (Speed=0) at the top of the Ramp changed to Kinetic Energy as it travels DOWN the Ramp. For any given INCLINE the LENGTH of the Ramp will dictate its HEIGHT. The higher the top of the ramp, the greater the Potential Energy to be Converted into Kinetic Energy. The Formula for K.E. is : K.E. = 1/2 Mass x Velocity2 (the 2 means Squared) So as the Potential Energy increases so does the Kinetic Energy. while the Mass is a Constant. Therefore the Velocity MUST increase as well to balance the K.E. equation.
Energy. (if you mean E=h*ni) If you're referring to sound then the greater the frequency the smaller the wave length. (v=lambda*f)
Power (watts) is amperes times voltage, or joules per second. Energy is joules, or watt-seconds. The length of time an electrical load is on is proportional to energy, not power.
power= energy time the time in seconds power= energy time the time in seconds
Is 2yd greater length then 5ft
it means what amount of time you did an activity for.
Which has a greater length 4ft or 4in or 56in
Yes, the length affects the amount of kinetic energy. The shorter the length the more kinetic energy.
It is a length of time equal to 13 minutes and 20 seconds.
The larger the force pulling on a spring, the greater the length in the spring and the more energy that is stored in that spring. When looking at a spring there is a gradient that determines how much force much be used to sqeeze or stretch a spring a given amount. When a spring is stretched, the greater the force that is applied, the greater the change in length of the spring and the greater the amount of energy that is stored in the spring. A link is supplied to the Wikipedia article on the spring (device).
It depends on its age. The older it gets the greater the length.
The length of his belt is greater than his waist.
A parallelogram can have any length which is greater than zero.