SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3146746977> ?p ?o ?g. }

Showing items 1 to 100 of ±146 with 100 items per page.

W3146746977 endingPage "326" @default.
W3146746977 startingPage "302" @default.
W3146746977 abstract "SUMMARY To understand earth processes, geoscientists infer subsurface earth properties such as electromagnetic resistivity or seismic velocity from surface observations of electromagnetic or seismic data. These properties are used to populate an earth model vector, and the spatial variation of properties across this vector sheds light on the underlying earth structure or physical phenomenon of interest, from groundwater aquifers to plate tectonics. However, to infer these properties the spatial characteristics of these properties need to be known in advance. Typically, assumptions are made about the length scales of earth properties, which are encoded a priori in a Bayesian probabilistic setting. In an optimization setting, appeals are made to promote model simplicity together with constraints which keep models close to a preferred model. All of these approaches are valid, though they can lead to unintended features in the resulting inferred geophysical models owing to inappropriate prior assumptions, constraints or even the nature of the solution basis functions. In this work it will be shown that in order to make accurate inferences about earth properties, inferences can first be made about the underlying length scales of these properties in a very general solution basis. From a mathematical point of view, these spatial characteristics of earth properties can be conveniently thought of as ‘properties’ of the earth properties. Thus, the same machinery used to infer earth properties can be used to infer their length scales. This can be thought of as an ‘infer to infer’ paradigm analogous to the ‘learning to learn’ paradigm which is now commonplace in the machine learning literature. However, it must be noted that (geophysical) inference is not the same as (machine) learning, though there are many common elements which allow for cross-pollination of useful ideas from one field to the other, as is shown here. A non-stationary trans-dimensional Gaussian Process (TDGP) is used to parametrize earth properties, and a multichannel stationary TDGP is used to parametrize the length scales associated with the earth property in question. Using non-stationary kernels, that is kernels with spatially variable length scales, models with sharp discontinuities can be represented within this framework. As GPs are multidimensional interpolators, the same theory and computer code can be used to solve geophysical problems in 1-D, 2-D and 3-D. This is demonstrated through a combination of 1-D and 2-D non-linear regression examples and a controlled source electromagnetic field example. The key difference between this and previous work using TDGP is generalized nested inference and the marginalization of prior length scales for better posterior subsurface property characterization." @default.
W3146746977 created "2021-04-13" @default.
W3146746977 creator A5082026610 @default.
W3146746977 date "2021-03-26" @default.
W3146746977 modified "2023-10-09" @default.
W3146746977 title "Bayesian inversion using nested trans-dimensional Gaussian processes" @default.
W3146746977 cites W1512628853 @default.
W3146746977 cites W1567512734 @default.
W3146746977 cites W1784770034 @default.
W3146746977 cites W1818136361 @default.
W3146746977 cites W1837874438 @default.
W3146746977 cites W1978723754 @default.
W3146746977 cites W1983034039 @default.
W3146746977 cites W1987293313 @default.
W3146746977 cites W1990544959 @default.
W3146746977 cites W1992327408 @default.
W3146746977 cites W2003054657 @default.
W3146746977 cites W2007692097 @default.
W3146746977 cites W2018705428 @default.
W3146746977 cites W2037139490 @default.
W3146746977 cites W2050497240 @default.
W3146746977 cites W2056760934 @default.
W3146746977 cites W2064076387 @default.
W3146746977 cites W2064546619 @default.
W3146746977 cites W2077434352 @default.
W3146746977 cites W2078193801 @default.
W3146746977 cites W2086989547 @default.
W3146746977 cites W2089957715 @default.
W3146746977 cites W2096448541 @default.
W3146746977 cites W2096486277 @default.
W3146746977 cites W2097849132 @default.
W3146746977 cites W2106407799 @default.
W3146746977 cites W2106706098 @default.
W3146746977 cites W2108064160 @default.
W3146746977 cites W2112759806 @default.
W3146746977 cites W2120575449 @default.
W3146746977 cites W2125809621 @default.
W3146746977 cites W2127508581 @default.
W3146746977 cites W2138309709 @default.
W3146746977 cites W2139860650 @default.
W3146746977 cites W2140499889 @default.
W3146746977 cites W2140561420 @default.
W3146746977 cites W2143022286 @default.
W3146746977 cites W2152415136 @default.
W3146746977 cites W2152657433 @default.
W3146746977 cites W2153263933 @default.
W3146746977 cites W2155621115 @default.
W3146746977 cites W2155707890 @default.
W3146746977 cites W2157326321 @default.
W3146746977 cites W2160748827 @default.
W3146746977 cites W2161807841 @default.
W3146746977 cites W2164272473 @default.
W3146746977 cites W2166928582 @default.
W3146746977 cites W2168558146 @default.
W3146746977 cites W2168746634 @default.
W3146746977 cites W2169682845 @default.
W3146746977 cites W2172039401 @default.
W3146746977 cites W2203714058 @default.
W3146746977 cites W2288220947 @default.
W3146746977 cites W2310705318 @default.
W3146746977 cites W2419359459 @default.
W3146746977 cites W2554500547 @default.
W3146746977 cites W2560286530 @default.
W3146746977 cites W2594063887 @default.
W3146746977 cites W2594383661 @default.
W3146746977 cites W2762775423 @default.
W3146746977 cites W2789408438 @default.
W3146746977 cites W2810372792 @default.
W3146746977 cites W2891101440 @default.
W3146746977 cites W2908425746 @default.
W3146746977 cites W2919524826 @default.
W3146746977 cites W2948612905 @default.
W3146746977 cites W2960813931 @default.
W3146746977 cites W2962980151 @default.
W3146746977 cites W2964007675 @default.
W3146746977 cites W2968467336 @default.
W3146746977 cites W2981735744 @default.
W3146746977 cites W2997325095 @default.
W3146746977 cites W3096098553 @default.
W3146746977 cites W3098919389 @default.
W3146746977 cites W3102974605 @default.
W3146746977 cites W3123551284 @default.
W3146746977 cites W4211177544 @default.
W3146746977 cites W4237417375 @default.
W3146746977 doi "https://doi.org/10.1093/gji/ggab114" @default.
W3146746977 hasPublicationYear "2021" @default.
W3146746977 type Work @default.
W3146746977 sameAs 3146746977 @default.
W3146746977 citedByCount "5" @default.
W3146746977 countsByYear W31467469772022 @default.
W3146746977 countsByYear W31467469772023 @default.
W3146746977 crossrefType "journal-article" @default.
W3146746977 hasAuthorship W3146746977A5082026610 @default.
W3146746977 hasBestOaLocation W31467469771 @default.
W3146746977 hasConcept C107673813 @default.
W3146746977 hasConcept C111472728 @default.
W3146746977 hasConcept C12426560 @default.
W3146746977 hasConcept C127313418 @default.