Design sensitivity analysis of a mechanical system is an essential tool for
design optimization and trade-off studies. This paper presents a design se
nsitivity analysis method, using direct differentiation and generalized rec
ursive formulas. The equations of motion are first generated in the Cartesi
an coordinate system and then transformed into the relative coordinate syst
em by using a velocity transformation. The design-sensitivity equations are
derived by directly differentiating the equations of motion. The equations
of motion and of design sensitivity are discritized by using the backward
difference formula (BDF) in time domain. The resulting equations constitute
an overdetermined differential algebraic system (ODAS) and are treated as
ordinary differential equations (ODEs) on manifolds. The computational stru
cture of the resulting equations is examined to classify all necessary comp
utations into several categories. The generalized recursive formula for eac
h category is then developed and applied whenever such a category of comput
ation is encountered in the equations of motion and of design sensitivity.
Since the velocity transformation yields the equations in a compact form an
d computational efficiency is achieved by the generalized recursive formula
s, the proposed method is not only easy to implement but also efficient. A
practical example of a vehicle consisting of many joints, bushings, and tir
es is given to show the efficiency of the proposed method. (C) 2001 Elsevie
r Science B.V. All rights reserved.