generalized forces

In analytical mechanics (particularly Lagrangian mechanics), generalized forces are conjugate to generalized coordinates. They are obtained from the applied forces {{math|1=F{{sub|i}}, i = 1, …, n}}, acting on a system that has its configuration defined in terms of generalized coordinates. In the formulation of virtual work, each generalized force is the coefficient of the variation of a generalized coordinate.

Virtual work

Generalized forces can be obtained from the computation of the virtual work, {{mvar|δW}}, of the applied forces.{{cite book |last=Torby |first=Bruce |title=Advanced Dynamics for Engineers |series=HRW Series in Mechanical Engineering |year=1984 |publisher=CBS College Publishing |location=United States of America |isbn=0-03-063366-4 |chapter=Energy Methods}}{{rp|265}}

The virtual work of the forces, {{math|F_i}}, acting on the particles {{math|1=P_i, i = 1, ..., n}}, is given by

$\delta W = \sum_{i=1}^n \mathbf F_i \cdot \delta \mathbf r_i$

where {{math|δr_i}} is the virtual displacement of the particle {{mvar|P_i}}.

=Generalized coordinates=

Let the position vectors of each of the particles, {{math|r_i}}, be a function of the generalized coordinates, {{math|1=q_j, j = 1, ..., m}}. Then the virtual displacements {{math|δr_i}} are given by

$\delta \mathbf{r}_i = \sum_{j=1}^m \frac {\partial \mathbf {r}_i} {\partial q_j} \delta q_j,\quad i=1,\ldots, n,$

where {{mvar|δq_j}} is the virtual displacement of the generalized coordinate {{mvar|q_j}}.

The virtual work for the system of particles becomes

$\delta W = \mathbf F_1 \cdot \sum_{j=1}^m \frac {\partial \mathbf r_1} {\partial q_j} \delta q_j + \dots + \mathbf F_n \cdot \sum_{j=1}^m \frac {\partial \mathbf r_n} {\partial q_j} \delta q_j.$

Collect the coefficients of {{mvar|δq_j}} so that

$\delta W = \sum_{i=1}^n \mathbf F_i \cdot \frac {\partial \mathbf r_i} {\partial q_1} \delta q_1 + \dots + \sum_{i=1}^n \mathbf F_i \cdot \frac {\partial \mathbf r_i} {\partial q_m} \delta q_m.$

=Generalized forces=

The virtual work of a system of particles can be written in the form

$\delta W = Q_1\delta q_1 + \dots + Q_m\delta q_m,$

where

$Q_j = \sum_{i=1}^n \mathbf F_i \cdot \frac {\partial \mathbf r_i} {\partial q_j},\quad j=1,\ldots, m,$

are called the generalized forces associated with the generalized coordinates {{math|1=q_j, j = 1, ..., m}}.

=Velocity formulation=

In the application of the principle of virtual work it is often convenient to obtain virtual displacements from the velocities of the system. For the n particle system, let the velocity of each particle P_i be {{math|V_i}}, then the virtual displacement {{math|δr_i}} can also be written in the formT. R. Kane and D. A. Levinson, [https://www.amazon.com/Dynamics-Theory-Applications-Mechanical-Engineering/dp/0070378460 Dynamics, Theory and Applications], McGraw-Hill, NY, 2005.

$\delta \mathbf r_i = \sum_{j=1}^m \frac {\partial \mathbf V_i} {\partial \dot q_j} \delta q_j,\quad i=1,\ldots, n.$

This means that the generalized force, {{mvar|Q_j}}, can also be determined as

$Q_j = \sum_{i=1}^n \mathbf F_i \cdot \frac {\partial \mathbf V_i} {\partial \dot{q}_j}, \quad j=1,\ldots, m.$

D'Alembert's principle

D'Alembert formulated the dynamics of a particle as the equilibrium of the applied forces with an inertia force (apparent force), called D'Alembert's principle. The inertia force of a particle, {{mvar|P_i}}, of mass {{mvar|m_i}} is

$\mathbf F_i^*=-m_i\mathbf A_i,\quad i=1,\ldots, n,$

where {{math|A_i}} is the acceleration of the particle.

If the configuration of the particle system depends on the generalized coordinates {{math|1=q_j, j = 1, ..., m}}, then the generalized inertia force is given by

$Q^*_j = \sum_{i=1}^n \mathbf F^*_{i} \cdot \frac {\partial \mathbf V_i} {\partial \dot q_j},\quad j=1,\ldots, m.$

D'Alembert's form of the principle of virtual work yields

$\delta W = (Q_1 + Q^*_1)\delta q_1 + \dots + (Q_m + Q^*_m)\delta q_m.$

References

Category:Mechanical quantities

Category:Classical mechanics

Category:Lagrangian mechanics