The formula for calculating power (p) in a system is p v2/r, where v represents velocity and r represents radius.
The equation for calculating the velocity amplitude in a given system is V A, where V is the velocity amplitude, A is the amplitude of the oscillation, and is the angular frequency of the system.
Flow velocity in a fluid system can be calculated by dividing the flow rate of the fluid by the cross-sectional area of the pipe or channel through which the fluid is flowing. The formula for calculating flow velocity is: Velocity Flow Rate / Cross-sectional Area.
The formula for calculating the amplitude of oscillation in a system is A (maximum displacement from equilibrium) - (equilibrium position).
The formula for calculating the phase of a signal in a communication system is phase arctan(imaginary part / real part).
The velocity ratio of a differential wheel and axle system can be determined by taking the ratio of the angular velocities of the two wheels connected to the axle. This can be calculated using the formula: Velocity Ratio = (Angular velocity of wheel A) / (Angular velocity of wheel B) This ratio helps in understanding how the rotational speed of the wheels relates to each other when the axle is being driven.
The equation for calculating the velocity amplitude in a given system is V A, where V is the velocity amplitude, A is the amplitude of the oscillation, and is the angular frequency of the system.
Flow velocity in a fluid system can be calculated by dividing the flow rate of the fluid by the cross-sectional area of the pipe or channel through which the fluid is flowing. The formula for calculating flow velocity is: Velocity Flow Rate / Cross-sectional Area.
The formula for calculating the amplitude of oscillation in a system is A (maximum displacement from equilibrium) - (equilibrium position).
The formula for calculating the phase of a signal in a communication system is phase arctan(imaginary part / real part).
The velocity ratio of a differential wheel and axle system can be determined by taking the ratio of the angular velocities of the two wheels connected to the axle. This can be calculated using the formula: Velocity Ratio = (Angular velocity of wheel A) / (Angular velocity of wheel B) This ratio helps in understanding how the rotational speed of the wheels relates to each other when the axle is being driven.
The critical radius formula is used to calculate the minimum size at which a system becomes stable. It is determined by the balance between internal and external forces. When the system's radius is smaller than the critical radius, it is unstable.
The formula for calculating the angular frequency () of a system in terms of the mass (m) and the spring constant (k) is (k/m).
The formula for calculating the period of a spring system is T 2(m/k), where T is the period, m is the mass of the object attached to the spring, and k is the spring constant.
The formula for calculating pressure (p) in a fluid system is: p h / .
To determine the velocity of the center of mass of a system of particles, you can use the formula: velocity of center of mass (total momentum of the system) / (total mass of the system). This formula takes into account the individual velocities and masses of all the particles in the system.
The formula for calculating the entropy of surroundings in a thermodynamic system is S -q/T, where S is the change in entropy, q is the heat transferred to or from the surroundings, and T is the temperature in Kelvin.
The ideal mechanical advantage of a wheel and axle system is calculated by dividing the radius of the wheel by the radius of the axle. The formula is: IMA = radius of wheel / radius of axle.