11 Other formulas that you can solve using the same Inputs

Impulsive Force
Impulsive Force=(Mass*(Final Velocity-Initial Velocity))/Time Taken to Travel GO
Final Velocity of freely falling body from height h, when it reaches ground
Velocity on reaching ground=sqrt(2*Acceleration Due To Gravity*Height) GO
Specific Heat Capacity
Specific Heat Capacity=Energy Required/(Mass*Rise in Temperature) GO
Archimedes Principle
Archimedes Principle=Density*Acceleration Due To Gravity*Velocity GO
Centripetal Force or Centrifugal Force when angular velocity, mass and radius of curvature are given
Centripetal Force=Mass*(Angular velocity^2)*Radius of Curvature GO
Potential Energy
Potential Energy=Mass*Acceleration Due To Gravity*Height GO
Pressure when density and height are given
Pressure=Density*Acceleration Due To Gravity*Height GO
Centripetal Force
Centripetal Force=(Mass*(Velocity)^2)/Radius GO
Kinetic Energy
Kinetic Energy=(Mass*Velocity^2)/2 GO
Force
Force=Mass*Acceleration GO
Density
Density=Mass/Volume GO

11 Other formulas that calculate the same Output

Total torque required to overcome friction in rotating a screw
Torque=(Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw/2)+(Coefficient of friction for collar*Weight of Load*Mean radius of collar) GO
Torque In Running Condition
Torque=3*Slip*Electromotive Force*Electromotive Force*Resistance/(2*pi*Synchronous Speed*((Resistance*Resistance)+(Reactance*Reactance*Slip))) GO
Starting Torque of Inductance Motor
Torque=(3*Electromotive Force*Electromotive Force*Resistance)/2*pi*Synchronous Speed*((Resistance*Resistance)+(Reactance*Reactance)) GO
Total frictional torque on flat pivot bearing considering uniform pressure
Torque=2*Coefficient of Friction*Load transmitted over the bearing surface*Radius of bearing surface/3 GO
Total frictional torque on flat pivot bearing considering uniform wear
Torque=Coefficient of Friction*Load transmitted over the bearing surface*Radius of bearing surface/2 GO
Torque required to overcome friction between screw and nut(lowering load)
Torque=Weight of Load*tan(Limiting angle of friction-Helix Angle)*Mean diameter of Screw/2 GO
Torque required to overcome friction between screw and nut(lowering load)
Torque=Weight of Load*tan(Limiting angle of friction-Helix Angle)*Mean diameter of Screw/2 GO
Torque required to overcome friction between screw and nut
Torque=Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw/2 GO
Maximum Running Torque
Torque=(3*Electromotive Force*Electromotive Force)/(4*pi*Synchronous Speed*Reactance) GO
Torque required to overcome friction at collar
Torque=Coefficient of friction for collar*Weight of Load*Mean radius of collar GO
Torque
Torque=Force*Displacement*sin(θ) GO

Restoring torque for simple pendulum Formula

Torque=Mass*Acceleration Due To Gravity*sin(Angle through which the string is displaced)*Length of the string
More formulas
Frequency of oscillation for SHM GO
Periodic time for SHM GO
Moment of inertia of bob of pendulum, about an axis through the point of suspension GO
Restoring force due to spring GO
Deflection of spring when mass m is attached to it GO
Periodic time for one beat of SHM GO
Periodic time of SHM for compound pendulum in terms of radius of gyration GO
Frequency of SHM for compound pendulum GO
Minimum periodic time of SHM for compound pendulum GO

What causes the restoring force in a simple pendulum?

So there is a net force directed along the other coordinate axes. It is this tangential component of gravity which acts as the restoring force. As the pendulum bob moves to the right of the equilibrium position, this force component is directed opposite its motion back towards the equilibrium position.

How to Calculate Restoring torque for simple pendulum?

Restoring torque for simple pendulum calculator uses Torque=Mass*Acceleration Due To Gravity*sin(Angle through which the string is displaced)*Length of the string to calculate the Torque, Restoring torque for simple pendulum is the torque which rises to return an object (twisted, rotating, etc.) to its original orientation is the restoring torque. The oscillations of a simple pendulum is a very good example of effects of restoring torque. Torque and is denoted by τ symbol.

How to calculate Restoring torque for simple pendulum using this online calculator? To use this online calculator for Restoring torque for simple pendulum, enter Acceleration Due To Gravity (g), Mass (m), Angle through which the string is displaced (θ) and Length of the string (L) and hit the calculate button. Here is how the Restoring torque for simple pendulum calculation can be explained with given input values -> -1823.032958 = 35.45*9.8*sin(2864.78897565466)*20.

FAQ

What is Restoring torque for simple pendulum?
Restoring torque for simple pendulum is the torque which rises to return an object (twisted, rotating, etc.) to its original orientation is the restoring torque. The oscillations of a simple pendulum is a very good example of effects of restoring torque and is represented as τ=m*g*sin(θ)*L or Torque=Mass*Acceleration Due To Gravity*sin(Angle through which the string is displaced)*Length of the string. The Acceleration Due To Gravity is acceleration gained by an object because of gravitational force, Mass is the quantity of matter in a body regardless of its volume or of any forces acting on it, Angle through which the string is displaced is the displacement angle and Length of the string is the length measurement of the string of pendulum.
How to calculate Restoring torque for simple pendulum?
Restoring torque for simple pendulum is the torque which rises to return an object (twisted, rotating, etc.) to its original orientation is the restoring torque. The oscillations of a simple pendulum is a very good example of effects of restoring torque is calculated using Torque=Mass*Acceleration Due To Gravity*sin(Angle through which the string is displaced)*Length of the string. To calculate Restoring torque for simple pendulum, you need Acceleration Due To Gravity (g), Mass (m), Angle through which the string is displaced (θ) and Length of the string (L). With our tool, you need to enter the respective value for Acceleration Due To Gravity, Mass, Angle through which the string is displaced and Length of the string and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Torque?
In this formula, Torque uses Acceleration Due To Gravity, Mass, Angle through which the string is displaced and Length of the string. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Torque=Force*Displacement*sin(θ)
  • Torque=(3*Electromotive Force*Electromotive Force*Resistance)/2*pi*Synchronous Speed*((Resistance*Resistance)+(Reactance*Reactance))
  • Torque=3*Slip*Electromotive Force*Electromotive Force*Resistance/(2*pi*Synchronous Speed*((Resistance*Resistance)+(Reactance*Reactance*Slip)))
  • Torque=(3*Electromotive Force*Electromotive Force)/(4*pi*Synchronous Speed*Reactance)
  • Torque=Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw/2
  • Torque=Coefficient of friction for collar*Weight of Load*Mean radius of collar
  • Torque=(Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw/2)+(Coefficient of friction for collar*Weight of Load*Mean radius of collar)
  • Torque=Weight of Load*tan(Limiting angle of friction-Helix Angle)*Mean diameter of Screw/2
  • Torque=Weight of Load*tan(Limiting angle of friction-Helix Angle)*Mean diameter of Screw/2
  • Torque=2*Coefficient of Friction*Load transmitted over the bearing surface*Radius of bearing surface/3
  • Torque=Coefficient of Friction*Load transmitted over the bearing surface*Radius of bearing surface/2
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