Filtered Legendre expansion method for numerical differentiation at the boundary point with application to blood glucose predictions

Mhaskar, H. N.; Naumova, Valeriya; Pereverzyev, Sergiy

doi:10.1016/j.amc.2013.09.015

Cited by 11 publications

(18 citation statements)

References 28 publications

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“…In this appendix, we review the mathematical background for the method developed in [12] for short term blood glucose prediction. As explained in the text, the main mathematical problem can be summarized as that of estimating the derivative of a function at the end point of an interval, based on measurements of the function in the past.…”

Section: A Filtered Legendre Expansion Methodsmentioning

confidence: 99%

“…Mathematically, if f : [−1, 1] → R is continuously differentiable, we wish to estimate f (1) given the noisy values {y j = f (t j ) + j } at points {t j } d j=1 ⊂ [−1, 1]. We summarize only the method here, and refer the reader to [12] for the detailed proof of the mathematical facts.…”

Section: A Filtered Legendre Expansion Methodsmentioning

confidence: 99%

“…Therefore, it is proposed in [9] to use Legendre polynomials rather than the monomials as the basis for the space of polynomials of degree n. A procedure to choose n is given in [9], together with error bounds in terms of n and the estimates on the noise level in the data, which are optimal up to a constant factor for the method in the sense of the oracle inequality. A substantial improvement on this method was proposed in [12], which we summarize in Appendix A. As far as we are aware, this is the state of the art in this approach in short term blood glucose prediction using linear prediction technology.…”

Section: Prior Workmentioning

confidence: 99%

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A Deep Learning Approach to Diabetic Blood Glucose Prediction

Mhaskar

Pereverzyev

Walt

2017

Front. Appl. Math. Stat.

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107

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We consider the question of 30-min prediction of blood glucose levels measured by continuous glucose monitoring devices, using clinical data. While most studies of this nature deal with one patient at a time, we take a certain percentage of patients in the data set as training data, and test on the remainder of the patients; i.e., the machine need not re-calibrate on the new patients in the data set. We demonstrate how deep learning can outperform shallow networks in this example. One novelty is to demonstrate how a parsimonious deep representation can be constructed using domain knowledge.

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Section: A Filtered Legendre Expansion Methodsmentioning

confidence: 99%

Section: A Filtered Legendre Expansion Methodsmentioning

confidence: 99%

Section: Prior Workmentioning

confidence: 99%

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A Deep Learning Approach to Diabetic Blood Glucose Prediction

Mhaskar

Pereverzyev

Walt

2017

Front. Appl. Math. Stat.

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107

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“…Numerical differentiation from noisy data is an important issue in a wide range of areas of science and technology. Applications areas include image processing (Wang et al 2002), inverse heat conduction problems (Bozzoli et al 2015(Bozzoli et al , 2017, parameter identification (Hanke Communicated by Antonio José Silva Neto. and Scherzer 1999), viscoelastic mechanics (Sovari and Malinen 2007) and blood glucose predictions (Mhaskar et al 2013). The main difficulty found in practical applications is that numerical differentiation is an ill-posed problem; hence, small input data errors can produce large errors in the computed derivative.…”

Section: Introductionmentioning

confidence: 99%

Filtered spectral differentiation method for numerical differentiation of periodic functions with application to heat flux estimation

Bazán

Bedin

2019

Comp. Appl. Math.

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Based on a truncated Fourier series technique to compute stable derivatives in a Sobolev space setting, we propose a method for numerical differentiation of periodic functions from a finite amount of noisy data. In our method, we construct stable approximations to high order derivatives by filtering high frequency components of spectral derivatives obtained through the Fourier differentiation matrix. We derive convergence rates for the approximate derivatives with essentially the same accuracy as those obtained by the truncated Fourier series technique. Our method is illustrated with numerical examples, focusing in particular, on the estimation of the heat flux distribution in coiled tubes from experimental temperature data.

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“…For such problems, the objective is to predict the index f x in the next month, say, based on a vector x of their values over the past few months. Other similar problems include the prediction of blood glucose level f x of a patient based on a vector x of the previous few observed levels [54,51], and the prediction of box office receipts (f x ) on the date of release of a movie in preparation, based on a vector x of the survey results about the movie [57]. It is pointed out in [40,38,19] that all the pattern classification problems can also be viewed fruitfully as problems of function approximation.…”

Section: Introductionmentioning

confidence: 99%

Deep Nets for Local Manifold Learning

Chui

Mhaskar

2018

Front. Appl. Math. Stat.

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The problem of extending a function f defined on a training data C on an unknown manifold X to the entire manifold and a tubular neighborhood of this manifold is considered in this paper. For X embedded in a high dimensional ambient Euclidean space R D , a deep learning algorithm is developed for finding a local coordinate system for the manifold without eigen-decomposition, which reduces the problem to the classical problem of function approximation on a low dimensional cube. Deep nets (or multilayered neural networks) are proposed to accomplish this approximation scheme by using the training data. Our methods do not involve such optimization techniques as back-propagation, while assuring optimal (a priori) error bounds on the output in terms of the number of derivatives of the target function. In addition, these methods are universal, in that they do not require a prior knowledge of the smoothness of the target function, but adjust the accuracy of approximation locally and automatically, depending only upon the local smoothness of the target function. Our ideas are easily extended to solve both the pre-image problem and the out-of-sample extension problem, with a priori bounds on the growth of the function thus extended.

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Filtered Legendre expansion method for numerical differentiation at the boundary point with application to blood glucose predictions

Cited by 11 publications

References 28 publications

A Deep Learning Approach to Diabetic Blood Glucose Prediction

A Deep Learning Approach to Diabetic Blood Glucose Prediction

Filtered spectral differentiation method for numerical differentiation of periodic functions with application to heat flux estimation

Deep Nets for Local Manifold Learning

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