"Gaussian process"의 두 판 사이의 차이

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위키데이터

• ID : Q1496376

말뭉치

1. Below is a collection of papers relevant to learning in Gaussian process models.^[1]
2. Since Gaussian process classification scales cubically with the size of the dataset, this might be considerably faster.^[2]
3. In one-versus-rest, one binary Gaussian process classifier is fitted for each class, which is trained to separate this class from the rest.^[2]
4. In “one_vs_one”, one binary Gaussian process classifier is fitted for each pair of classes, which is trained to separate these two classes.^[2]
5. A Gaussian process defines a prior over functions.^[3]
6. For example, if a random process is modelled as a Gaussian process, the distributions of various derived quantities can be obtained explicitly.^[4]
7. Thus, if a Gaussian process is assumed to have mean zero, defining the covariance function completely defines the process' behaviour.^[4]
8. The effect of choosing different kernels on the prior function distribution of the Gaussian process.^[4]
9. A Wiener process (aka Brownian motion) is the integral of a white noise generalized Gaussian process .^[4]
10. The covariance matrix Σ \Sigma Σ is determined by its covariance function k k k, which is often also called the kernel of the Gaussian process.^[5]
11. Making a prediction using a Gaussian process ultimately boils down to drawing samples from this distribution.^[5]
12. Clicking on the graph results in continuous samples drawn from a Gaussian process using the selected kernel.^[5]
13. Using the checkboxes, different kernels can be combined to form a new Gaussian process.^[5]
14. In this article, we introduce Gaussian process dynamic programming (GPDP), an approximate value function-based RL algorithm.^[6]
15. In this colab, we explore Gaussian process regression using TensorFlow and TensorFlow Probability.^[7]
16. Note that, according to the above definition, any finite-dimensional multivariate Gaussian distribution is also a Gaussian process.^[7]
17. This paper proposes the application of bagging to obtain more robust and accurate predictions using Gaussian process regression models.^[8]
18. A Gaussian Process places a prior over functions, and can be described as an infinite dimensional generalisation of a multivariate Normal distribution.^[9]
19. The package allows the user to fit exact Gaussian process models when the observations are Gaussian distributed about the latent function.^[9]
20. The defining feature of a Gaussian process is that the joint distribution of the function’s value at a finite number of input points is a multivariate normal distribution.^[10]
21. Unlike a simple multivariate normal distribution, which is parameterized by a mean vector and covariance matrix, a Gaussian process is parameterized by a mean function and covariance function.^[10]
22. In so doing, this Gaussian process joint modeling (GPJM) framework can be viewed as a temporal and nonparametric extension of the covariance-based linking function (8, 14).^[11]
23. On the contrary, Gaussian process regression directly models the function f as a sample from a distribution over functions.^[11]
24. In the Gaussian process framework, one way to enforce temporally lagged, convolved neural signals is to convolve the GP kernel with a secondary function—an HRF in our case.^[11]
25. This approach is justified from the fact that convolution of a Gaussian process with another function is another Gaussian process (34⇓–36).^[11]
26. 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 # evaluate a gaussian process classifier model on the dataset from numpy import mean from numpy import std from sklearn .^[12]
27. 2 3 4 5 6 7 8 9 10 11 12 13 14 15 # make a prediction with a gaussian process classifier model on the dataset from sklearn .^[12]
28. The prior samples are taken from a Gaussian process without any data and the posterior samples are taken from a Gaussian process where the data are shown as black squares.^[13]
29. Gaussian process regression (GPR) models are nonparametric kernel-based probabilistic models.^[14]
30. This paper develops an efficient computational method for solving a Gaussian process (GP) regression for large spatial data sets using a collection of suitably defined local GP regressions.^[15]
31. Gaussian process models are routinely used to solve hard machine learning problems.^[16]
32. A Gaussian process (GP) can be used as a prior probability distribution whose support is over the space of continuous functions.^[17]
33. PyMC3 is a great environment for working with fully Bayesian Gaussian Process models.^[17]
34. I'm working my way through Rasmussen and Williams' classical work Gaussian Process for Machine Learning, and attempting to implement a lot of their theory in Python.^[18]
35. Some call it kriging, which is a term that comes from geostatistics (Matheron 1963); some call it Gaussian spatial modeling or a Gaussian stochastic process.^[19]
36. Gaussian process is a generic term that pops up, taking on disparate but quite specific meanings, in various statistical and probabilistic modeling enterprises.^[19]
37. modeling of massive datasets called globally approximate Gaussian process (GAGP).^[20]
38. Gaussian process (GP) models (also known as Kriging) have many attractive features that underpin their widespread use in engineering design.^[20]

소스

노트

위키데이터

• ID : Q1496376

말뭉치

1. Below is a collection of papers relevant to learning in Gaussian process models.^[1]
2. Since Gaussian process classification scales cubically with the size of the dataset, this might be considerably faster.^[2]
3. In one-versus-rest, one binary Gaussian process classifier is fitted for each class, which is trained to separate this class from the rest.^[2]
4. In “one_vs_one”, one binary Gaussian process classifier is fitted for each pair of classes, which is trained to separate these two classes.^[2]
5. A Gaussian process defines a prior over functions.^[3]
6. For example, if a random process is modelled as a Gaussian process, the distributions of various derived quantities can be obtained explicitly.^[4]
7. Thus, if a Gaussian process is assumed to have mean zero, defining the covariance function completely defines the process' behaviour.^[4]
8. The effect of choosing different kernels on the prior function distribution of the Gaussian process.^[4]
9. A Wiener process (aka Brownian motion) is the integral of a white noise generalized Gaussian process.^[4]
10. The covariance matrix Σ \Sigma Σ is determined by its covariance function k k k, which is often also called the kernel of the Gaussian process.^[5]
11. Making a prediction using a Gaussian process ultimately boils down to drawing samples from this distribution.^[5]
12. Clicking on the graph results in continuous samples drawn from a Gaussian process using the selected kernel.^[5]
13. Using the checkboxes, different kernels can be combined to form a new Gaussian process.^[5]
14. This tutorial introduces the reader to Gaussian process regression as an expressive tool to model, actively explore and exploit unknown functions.^[6]
15. Gaussian process regression is a powerful, non-parametric Bayesian approach towards regression problems that can be utilized in exploration and exploitation scenarios.^[6]
16. In this article, we introduce Gaussian process dynamic programming (GPDP), an approximate value function-based RL algorithm.^[7]
17. In this colab, we explore Gaussian process regression using TensorFlow and TensorFlow Probability.^[8]
18. Note that, according to the above definition, any finite-dimensional multivariate Gaussian distribution is also a Gaussian process.^[8]
19. A Gaussian Process places a prior over functions, and can be described as an infinite dimensional generalisation of a multivariate Normal distribution.^[9]
20. The package allows the user to fit exact Gaussian process models when the observations are Gaussian distributed about the latent function.^[9]
21. The defining feature of a Gaussian process is that the joint distribution of the function’s value at a finite number of input points is a multivariate normal distribution.^[10]
22. Unlike a simple multivariate normal distribution, which is parameterized by a mean vector and covariance matrix, a Gaussian process is parameterized by a mean function and covariance function.^[10]
23. Use the Gaussian Process platform to model the relationship between a continuous response and one or more predictors.^[11]
24. The Gaussian Process platform fits a spatial correlation model to the data.^[11]
25. 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 # evaluate a gaussian process classifier model on the dataset from numpy import mean from numpy import std from sklearn .^[12]
26. 2 3 4 5 6 7 8 9 10 11 12 13 14 15 # make a prediction with a gaussian process classifier model on the dataset from sklearn .^[12]
27. In so doing, this Gaussian process joint modeling (GPJM) framework can be viewed as a temporal and nonparametric extension of the covariance-based linking function (8, 14).^[13]
28. On the contrary, Gaussian process regression directly models the function f as a sample from a distribution over functions.^[13]
29. In the Gaussian process framework, one way to enforce temporally lagged, convolved neural signals is to convolve the GP kernel with a secondary function—an HRF in our case.^[13]
30. This approach is justified from the fact that convolution of a Gaussian process with another function is another Gaussian process (34⇓–36).^[13]
31. The prior samples are taken from a Gaussian process without any data and the posterior samples are taken from a Gaussian process where the data are shown as black squares.^[14]
32. Some call it kriging, which is a term that comes from geostatistics (Matheron 1963); some call it Gaussian spatial modeling or a Gaussian stochastic process.^[15]
33. Gaussian process is a generic term that pops up, taking on disparate but quite specific meanings, in various statistical and probabilistic modeling enterprises.^[15]

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