我想讨论本构方程误差(ECE)方法作为一种新兴的和令人兴奋的途径来识别材料在逆问题的背景下。在本文讨论的ECE方法中，我们定义了一个基于能量范数的成本函数，该能量范数连接了一组运动学允许位移和一组动态允许应力。运动容许位移集是由满足必要边界条件并具有足够规律性(即光滑性)的场构成的。动态容许应力集由满足线性动量守恒和自然(即牵引)边界条件的场组成。通过寻找材料特性以及允许的位移和应力场来解决反问题，从而使ECE函数(以及数据不匹配的测量)最小化。实验数据在公式中作为二次惩罚项添加到ECE泛函中。

图1。使用ECE方法重建目标和重建剪切“G”和块体“B”模场。[Banerjee等人] CMAME, 253, 60-72 (2013)]

ECE approaches possess significant advantages such as incorporating the relevant physics directly into the cost functional as well as offering natural metrics for a posteriori error estimation, among others. Furthermore, in many of our applications, we have observed faster convergence with ECE-type functionals than with conventional least squares objective functions.

Our group, in collaboration with the Mayo Clinic Ultrasound Research Laboratory, has been working with the ECE technique in the context of biomechanics problems. Specifically, we have focused on the identification of viscoelastic material properties in arteries, the heart wall, and breast tumors with the end goal of early disease diagnosis.

The ECE approach may be widely applied to problems involving complex nonlinear mechanics, coupled physics, and multiple temporal and spatial scales. There are many exciting (and still unexploited) opportunities in using ECE methods in the latter fronts. For an overview of the method and other references, please see

1) B. Banerje, T.F. Walsh, W. Aquino, and M. Bonnet (2013). Large Scale Parameter Estimation Problems in Frequency-Domain Elastodynamics Using an Error in Constitutive Equation Functional. Computer Methods in Applied Mechanics and Engineering, 253, 60-72.