Functional data are frequently accompanied by a parametric template that describes the typical shapes of the functions. However, these parametric templates can incur significant bias, which undermines both utility and interpretability. To correct for model misspecification, we augment the parametric template with an infinite-dimensional nonparametric functional basis. The nonparametric basis functions are learned from the data and constrained to be orthogonal to the parametric template, which preserves distinctness between the parametric and nonparametric terms. This distinctness is essential to prevent functional confounding, which otherwise induces severe bias for the parametric terms. The nonparametric factors are regularized with an ordered spike-and-slab prior that provides consistent rank selection and satisfies several appealing theoretical properties. The versatility of the proposed approach is illustrated through applications to synthetic data, human motor control data, and dynamic yield curve data. Relative to parametric and semiparametric alternatives, the proposed semiparametric functional factor model eliminates bias, reduces excessive posterior and predictive uncertainty, and provides reliable inference on the effective number of nonparametric terms--all with minimal additional computational costs.
翻译:功能数据往往配有一个描述功能的典型形状的参数模板,然而,这些参数模板可能会产生重大的偏差,从而损害其效用和可解释性。为了纠正模型的偏差,我们用无限维非参数功能基础来补充参数模板,从数据中学习非参数基础功能,并限于与参数模板的正对性,以保持参数与非参数术语的区别。这种区别对于防止功能混淆至关重要,否则会给参数术语带来严重偏差。非参数因素与之前的定购的峰值和板块常规化,提供一致的等级选择,并满足若干具有吸引力的理论属性。拟议方法的多功能通过合成数据的应用、人类运动控制数据以及动态曲线数据加以说明。相对于参数和半参数替代方法,拟议的半参数模型消除偏差,减少过分的后表和预测性不确定性,并在非参数的有效数量上提供可靠的推论,同时增加最低的计算成本。