This problem is an algebra-based problem using applications of oscillations. The rod is a length L with the axis of rotation in the center.
I found the answer to be that T = PIE x Sq root of (2L(m1 + m2) / (m1 - m2)g)
In a simple pendulum, with its entire mass concentrated at the end of a string, the period depends on the distance of the mass from the pivot point. A physical pendulum's period is affected by the distance of the centre-of-gravity of the pendulum arm to the pivot point, its mass and its moment of inertia about the pivot point. In real life the pendulum period can also be affected by air resistance, temperature changes etc.
It doesn't matter what unit you use to measure the physical length of the pendulum. As a matter of fact, it doesn't matter what unit you use to measure the duration of its period either. If both are at rest on the same planet, then the penduum with the longer string has the longer period. Period!
the wellness triangle is a diagram of a well balanced life style that consists of physical mental and social. We should always have a ballance with these aspects , the tirangle should not be lopsided.
A physical need includes food, water, clothing, and shelter. Physical needs are those needs that are met through physical objects.
Geometry does not expose the physical world, but it does tell us something about how the physical world works. Geometry is relevant to the physical world.
The physical parameters of a simple pendulum include (1) the length of the pendulum, (2) the mass of the pendulum bob, (3) the angular displacement through which the pendulum swings, and (4) the period of the pendulum (the time it takes for the pendulum to swing through one complete oscillation).
Compound pendulum is a physical pendulum whereas a simple pendulum is ideal pendulum. The difference is that in simple pendulum centre of mass and centre of oscillation are at the same distance.
There is no abstract noun form for the concrete noun 'pendulum', a word for a physical device.
Compound pendulum is a physical pendulum whereas a simple pendulum is ideal pendulum. The difference is that in simple pendulum centre of mass and centre of oscillation are at the same distance.
physical meaning of experiment of acceleration of free fallby means of the simple pendulum
In a simple pendulum, with its entire mass concentrated at the end of a string, the period depends on the distance of the mass from the pivot point. A physical pendulum's period is affected by the distance of the centre-of-gravity of the pendulum arm to the pivot point, its mass and its moment of inertia about the pivot point. In real life the pendulum period can also be affected by air resistance, temperature changes etc.
External devices which are attached to the computer are called "peripherals."
300,000
Physical pollution
Your license won't be suspended, but you'll be forced to downgrade. You can't hold a CDL if you can't pass a DOT physical. And if you can't pass a DOT physical, you have much bigger problems than your license to worry about.
no. u don't know a person till u meet them Yes you can it depends on you if you think attached then guess what you attached its all natural and nothing to worrie about not everything needs to be physical
The period of oscillation of a simple pendulum displaced by a small angle is: T = (2*PI) * SquareRoot(L/g) where T is the period in seconds, L is the length of the string, and g is the gravitional field strength = 9.81 N/Kg. This equation is for a simple pendulum only. A simple pendulum is an idealised pendulum consisting of a point mass at the end of an inextensible, massless, frictionless string. You can use the simple pendulum model for any pendulum whose bob mass is much geater than the length of the string. For a physical (or real) pendulum: T = (2*PI) * SquareRoot( I/(mgr) ) where I is the moment of inertia, m is the mass of the centre of mass, g is the gravitational field strength and r is distance to the pivot from the centre of mass. This equation is for a pendulum whose mass is distributed not just at the bob, but throughout the pendulum. For example, a swinging plank of wood. If the pendulum resembles a point mass on the end of a string, then use the first equation.