Smoothing noisy data with spline functions

Craven, Peter G.; Wahba, Grace

doi:10.1007/bf01404567

Cited by 2,887 publications

(1,119 citation statements)

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“…The best combination of α and p is obtained through a minimization of the generalized cross validation (GCV) statistic [Loader, 1999, p. 31]. Because it penalizes use of excess parameters, the GCV provides a better estimate of the predictive risk of a model than simply measures of goodness of fit [e.g., Craven and Wahba, 1979]. The regression theory provides the local error of the estimate and, consequently, the confidence and prediction intervals.…”

Section: Data and Forecasting Methodsmentioning

confidence: 99%

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Rajagopalan

Molnár

2014

Geophysical Research Letters

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We exploit El Niño-Southern Oscillation (ENSO) indices and moist static energy of surface air over the Indian subcontinent and surroundings as predictors of monsoon rainfall over India during early and late seasons, defined here as 20 May to 15 June and 20 September to 15 October, respectively. Although these seasons contribute only~22% of the entire seasonal rainfall, they clearly affect planning of agriculture and water resources. A simple, nonlinear, statistical model applied to these predictors accounts for~40% and 45% of the observed variance of early and late season rainfall, respectively, and similar fractions for 3 day maximum rainfall intensity. Forecasted average and 3 day maximum rainfall at grid points covering India show greatest success over central India during the early season and over west central, northwestern, and northern India during the late season, regions where agriculture dominates land use. These predictors, however, offer virtually no predictability of peak season rainfall.

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Section: Data and Forecasting Methodsmentioning

confidence: 99%

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Rajagopalan

Molnár

2014

Geophysical Research Letters

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“…[28] and [31] investigate methods of determining the appropriate level of smoothing by analyzing properties of the input data. LQ problems with various types of boundary conditions are studied in [7] and [23] but to the extent of our knowledge, little work has been done on the type of periodic boundary conditions studied in this paper.…”

Section: D2 Related Work and Contributionsmentioning

confidence: 99%

“…Ideally, to make Algorithm D.4.1 truly automatic, it should include a way of determining the magnitude of ε based on the input data without knowledge of the contour. For regular smoothing splines such methods are presented in for instance [28] and [31]. Ongoing work includes adapting such a method to Problem D.3.1 and Problem D.3.2.…”

Section: D6 Conclusionmentioning

confidence: 99%

Contour reconstruction using recursive smoothing splines - Algorithms and experimental validation

Karasalo

Piccolo

Kragić

et al. 2009

Robotics and Autonomous Systems

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In this paper, a recursive smoothing spline approach for contour reconstruction is studied and evaluated. Periodic smoothing splines are used by a robot to approximate the contour of encountered obstacles in the environment. The splines are generated through minimizing a cost function subject to constraints imposed by a linear control system and accuracy is improved iteratively using a recursive spline algorithm. The filtering effect of the smoothing splines allows for usage of noisy sensor data and the method is robust with respect to odometry drift. The algorithm is extensively evaluated in simulations for various contours and in experiments using a SICK laser scanner mounted on a PowerBot from ActivMedia Robotics.Keywords: mapping, optimal control, recursive smoothing splines, implementation D.1 IntroductionToday robots are expected to operate in at least partially unknown, open-ended environments, detecting and moving around obstacles, building maps of the environment and localizing their position. The area of autonomous mapping has during the past few years matured and there has been a significant amount of work reported using both visual and laser sensors, [8], [26]. However, most methods are still concerned with detecting and maintaining a dense set of discrete features of the environment that are suitable for navigation and localization without retrieving any specific knowledge about the detailed shape of the encountered objects.In this paper, we consider the problem of estimating representations of objects using a type of continuous closed curves, the recursive periodic smoothing splines. The splines are retrieved from noisy measurements of the true contour. Intended applications include mapping, identification and path planning. It is well known that interpolating splines from noisy measurement data will give a poor result, as the resulting curve will go through every measurement point. Data smoothing has been a classical problem in system and control history [1], [13], [18]. The theory of regular smoothing splines is thoroughly treated in [29] and [30]. It has been further shown in [35] that control theoretic smoothing splines, where the curve is found through minimizing a cost function, act as filters and are better suited for noisy measurements. It is also noted in [27] that smoothing 89

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“…To apply the metric based approach to this task, we define the metric d in terms of the squared prediction error err(ŷ, y) = (ŷ − y) 2 with a square root normalization ϕ(z) = z 1/2 , as discussed in Section 2. To evaluate the efficacy of TRI in this problem we compared its performance to a number of standard model selection strategies, including: structural risk minimization, SRM (Cherkassky, Mulier, & Vapnik, 1997;Vapnik, 1996), RIC (Foster & George, 1994), SMS (Shibata, 1981), GCV (Craven & Wahba, 1979), BIC (Schwarz, 1978), AIC (Akaike, 1974), CP (Mallows, 1973), and FPE (Akaike, 1970). We also compared it to 10-fold cross validation, CVT (a standard hold-out method (Efron, 1979;Weiss & Kulikowski, 1991;Kohavi, 1995)).…”

Section: Example: Polynomial Regressionmentioning

confidence: 99%

“…The first class of methods we compared against were the same model selection methods considered before: 10-fold cross validation CVT, structural risk minimization SRM (Cherkassky, Mulier, & Vapnik, 1997), RIC (Foster & George, 1994), SMS (Shibata, 1981), GCV (Craven & Wahba, 1979), BIC (Schwarz, 1978), AIC (Akaike, 1974), CP (Mallows, 1973), FPE (Akaike, 1970), and the metric based model selection strategy, ADJ, introduced in Section 3.3. However, since none of the statistical methods, RIC, SMS, GCV, BIC, AIC, CP, FPE, performed competitively in our experiments, we report results only for GCV which performed the best among them.…”

Section: Example: Polynomial Regressionmentioning

confidence: 99%

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Schuurmans

Southey

2002

Machine Learning

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Abstract. We present a general approach to model selection and regularization that exploits unlabeled data to adaptively control hypothesis complexity in supervised learning tasks. The idea is to impose a metric structure on hypotheses by determining the discrepancy between their predictions across the distribution of unlabeled data. We show how this metric can be used to detect untrustworthy training error estimates, and devise novel model selection strategies that exhibit theoretical guarantees against over-fitting (while still avoiding under-fitting). We then extend the approach to derive a general training criterion for supervised learning-yielding an adaptive regularization method that uses unlabeled data to automatically set regularization parameters. This new criterion adjusts its regularization level to the specific set of training data received, and performs well on a variety of regression and conditional density estimation tasks. The only proviso for these methods is that sufficient unlabeled training data be available.

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Smoothing noisy data with spline functions

Cited by 2,887 publications

References 16 publications

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Contour reconstruction using recursive smoothing splines - Algorithms and experimental validation

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