Finding local departures from a parametric model using nonparametric regression. (English) Zbl 1247.62119
Summary: Goodness-of-fit evaluation of a parametric regression model is often done through hypothesis testing, where the fit of the model of interest is compared statistically to that obtained under a broader class of models. Nonparametric regression models are frequently used as the latter type of model, because of their flexibility and wide applicability. To date, this type of tests has generally been performed globally, by comparing the parametric and nonparametric fits over the whole range of the data. However, in some instances it might be of interest to test for deviations from the parametric model that are localized to a subset of the data. In this case, a global test will have low power and hence can miss important local deviations. Alternatively, a naive testing approach that discards all observations outside the local interval will suffer from reduced sample size and potential overfitting. We therefore propose a new local goodness-of-fit test for parametric regression models that can be applied to a subset of the data but relies on global model fits, and propose a bootstrap-based approach for obtaining the distribution of the test statistic. We compare the new approach with the global and the naive tests, both theoretically and through simulations, and illustrate its practical behavior in an application. We find that the local test has a better ability to detect local deviations than the other two tests.
MSC:
| 62G08 | Nonparametric regression and quantile regression |
| 62G10 | Nonparametric hypothesis testing |
| 62G09 | Nonparametric statistical resampling methods |
| 62F03 | Parametric hypothesis testing |
| 65C60 | Computational problems in statistics (MSC2010) |
References:
| [1] | Alcalá JT, Cristobal JA and González-Manteiga W (1999). Goodness-of-fit test for linear models based on local polynomials. Stat Probab Lett 42: 39–46 · Zbl 0946.62016 · doi:10.1016/S0167-7152(98)00184-9 |
| [2] | Azzalini A, Bowman AW and Härdle W (1989). On the use of nonparametric regression for model checking. Biometrika 76: 1–12 · Zbl 0663.62096 · doi:10.1093/biomet/76.1.1 |
| [3] | Bjerve S, Doksum KA and Yandell BS (1985). Uniform confidence bounds for regression based on a simple moving average. Scand J Stat 12: 159–169 · Zbl 0602.62034 |
| [4] | Cox D, Koh E, Wahba G and Yandell BS (1988). Testing the (parametric) null model hypothesis in (semiparametric) partial and generalized spline models. Ann Stat 16: 113–119 · Zbl 0673.62017 · doi:10.1214/aos/1176350693 |
| [5] | Dette H (1999). A consistent test for the functional form of a regression based on a difference of variance estimators. Ann Stat 27(3): 1012–1040 · Zbl 0957.62036 · doi:10.1214/aos/1018031266 |
| [6] | Eubank RL, Li CS and Wang S (2005). Testing lack-of-fit of parametric regression models using nonparametric regression techniques. Stat Sin 15(1): 135–152 · Zbl 1059.62042 |
| [7] | Eubank RL and Spiegelman CH (1990). Testing the goodness of fit of a linear model via nonparametric regression techniques. J Am Stat Assoc 85: 387–392 · Zbl 0702.62037 · doi:10.1080/01621459.1990.10476211 |
| [8] | Fan J and Gijbels I (1996). Local polynomial modelling and its applications. Chapman & Hall, London · Zbl 0873.62037 |
| [9] | Gijbels I and Rousson V (2001). A nonparametric least-squares test for checking a polynomial relationship. Stat Probab Lett 51(3): 253–261 · Zbl 0965.62038 · doi:10.1016/S0167-7152(00)00152-8 |
| [10] | Guerre E and Lavergne P (2002). Optimal minimax rates for nonparametric specification testing in regression models. Econom Theory 18(5): 1139–1171 · Zbl 1033.62042 |
| [11] | Härdle W and Mammen E (1993). Comparing nonparametric versus parametric regression fits. Ann Stat 21: 1926–1947 · Zbl 0795.62036 · doi:10.1214/aos/1176349403 |
| [12] | Hart JD (1997). Nonparametric smoothing and lack-of-fit tests. Springer, New York · Zbl 0886.62043 |
| [13] | Horowitz JL and Spokoiny VG (2001). An adaptive, rate-optimal test of a parametric mean-regression model against a nonparametric alternative. Econometrica 69(3): 599–631 · Zbl 1017.62012 · doi:10.1111/1468-0262.00207 |
| [14] | Johnson, RW (1996) Fitting percentage of body fat to simple body measurements. J Stat Educ 4. http://www.amstat.org/publications/jse/v4nl/datasets.johnson.html |
| [15] | Noether GE (1955). On a theorem of Pitman. Ann Math Stat 26: 64–68 · Zbl 0066.12001 · doi:10.1214/aoms/1177728593 |
| [16] | Penrose K, Nelson A and Fisher AA (1985). Generalized body composition prediction equation for men using simple measurement techniques (abstract). Med Sci Sports Exerc 17: 189 · doi:10.1249/00005768-198504000-00037 |
| [17] | Shao J and Tu D (1995). The jacknife and bootstrap. Springer, New York · Zbl 0947.62501 |
| [18] | Spokoiny VG (1996). Adaptive hypothesis testing using wavelets. Ann Stat 24(6): 2477–2498 · Zbl 0898.62056 · doi:10.1214/aos/1032181163 |
| [19] | Staniswalis JG and Severini TA (1991). Diagnostics for assessing regression models. J Am Stat Assoc 86: 684–692 · Zbl 0736.62063 · doi:10.1080/01621459.1991.10475095 |
| [20] | Stute W and González-Manteiga W (1996). NN goodness-of-fit tests for linear models. J Stat Plan Inference 53: 75–92 · Zbl 0847.62036 · doi:10.1016/0378-3758(95)00144-1 |
| [21] | Tibshirani R and Hastie T (1987). Local likelihood estimation. J Am Stat Assoc 82: 559–567 · Zbl 0626.62041 · doi:10.1080/01621459.1987.10478466 |
| [22] | Weirather G (1993). Testing a linear regression model against nonparametric alternatives. Metrika 40: 367–379 · Zbl 0785.62049 · doi:10.1007/BF02613703 |
| [23] | Zheng JH (1996). A consistent test of functional form via nonparametric estimation techniques. J Econom 75: 263–289 · Zbl 0865.62030 · doi:10.1016/0304-4076(95)01760-7 |
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.
