We propose a workflow to investigate spatial distribution

コメント · 350 ビュー

We propose a workflow to investigate spatial distribution

was applied and the performance of each interpolation method was evaluated using cross-validation and estimating the Pearson Corellation and the coefficient of determination (R2). The best interpolation technique for this research proved to be the Ordinary Kriging for the shoreline materials and the Empirical Bayesian Kriging (EBK) for the seabed materials since both had the lowest prediction errors and the highest R2.
Coastal zones are one of the most complex and dynamic systems since their landform changes rapidly (timeframe of days and weeks) due to the combined action of tidal flows, currents and waves on coastal sediments (Raper et al. 2005). Moreover, grain size analysis and textural characteristics of surficial coastal sediments provide useful information to define and reveal the hydrodynamic condition as well as the deposition process. The modelling of many environmental and engineering applications in the coastal zone as well as for risk assessment against coastal hazards requires the knowledge of the grain size and the distribution of the surficial coastal sediments. As a result, measurements of grain size parameters are important for the understanding and calculation of sediment transport and critical parameters for modelling coastal erosion and vulnerability (Boumboulis et al. 2021), offshore and geotechnical engineering (Zananiri and Vakalas 2019), coastal zone management and coastal protection works such as beach nourishment. Hence, maps of surficial sediment spatial distribution in coastal and nearshore zone are important to provide information about the processes and mechanisms of the environment for sustainable management and protection.

An evolutionary-assisted machine learning model for global solar radiation prediction in Minas Gerais region, southeastern Brazil
Solar radiation prediction is necessary for designing photovoltaic systems, assessment of regional climate and crop growth modeling. However, this estimate depends on expensive devices, namely pyranometer and pyranometer. Considering the difficulty of acquiring these devices, predicting such values through mathematical and computational models is a convenient approach where costs can be reduced. In particular, machine learning methods have been successfully and widely applied for this task. However, the choice of the correct machine learning model, its parameters sets, and the variables used influence obtained results. This work presents a methodology that optimizes the aforementioned points to efficiently predict solar radiation in the state of Minas Gerais, Brazil. Currently, no work presents a computational model for the entire state. For this, data from 51 cities in Minas Gerais are used, obtained by the automatic weather stations of the National Institute of Meteorology. Two machine learning models, Artificial Neural Network and Multivariate Adaptive Regression Spline, were optimized through a Simple Genetic Algorithm, and the results compared to those available in the literature. The best results were found at the Guanhães station, with R2
of 0.867 and RMSE of 1.68 MJ m−2

https://sites.google.com/sanin28.com/flix-i-guardiani-galassia/home

https://sites.google.com/foxtailproject.com/flix01-guardiani-galassia/home

https://sites.google.com/zaksos.com/filmflixguardiani3/home-page

https://sites.google.com/gracemill.co.uk/flix01-i-guardiani-3/home

https://sites.google.com/najat.my.id/altadefinizioneflixguardiani/home

https://sites.google.com/sanin28.com/voirlesgardiensgalaxiev3/home

https://sites.google.com/foxtailproject.com/voirflix-gardiens-3/home

https://sites.google.com/zaksos.com/filmvoirlesgardiensgalaxie3/home-page

https://sites.google.com/gracemill.co.uk/voir-gardiens-galaxie3/home

https://sites.google.com/najat.my.id/flixvoirfilmlesgardiens3/home

https://sites.google.com/sanin28.com/xemvbinhdingnh3/home

https://sites.google.com/zaksos.com/phim-v-binh-di-ngn-h-3/home

https://sites.google.com/sanin28.com/volume-3-hd-kr/home

https://sites.google.com/zaksos.com/vol31080p/home

https://sites.google.com/gracemill.co.uk/guardian32023-hd/home

https://sites.google.com/boncu.online/3guardiansgalaxy-4k/home

https://sites.google.com/gracemill.co.uk/volume32023jphd/home

https://sites.google.com/sanin28.com/gaurdianvol3/home

https://sites.google.com/gracemill.co.uk/2023-jp-hd1080p/home

https://sites.google.com/sanin28.com/mariobrosjp/home

https://sites.google.com/sanin28.com/izlegalaksinin3/home

https://sites.google.com/najat.my.id/galaksinin-koruyucular-3/ana-sayfa

https://sites.google.com/foxtailproject.com/assistir-guardies-da-galxia-vo/home

https://sites.google.com/foxtailproject.com/filmeguardiesdagalxiavol32023f/home

 

https://open.firstory.me/user/clhowpsrq06qj01uz334cdgsr

https://backlinktool.io/p/jBtkuyb0QLXk23jEmEqg.html

https://argueanything.com/thread/an-evolutionary-assisted-machine-learning-model-for-global-solar/

https://www.onfeetnation.com/photo/albums/fdga4

https://gotartwork.com/Blog/an-evolutionary-assisted-machine-learning-model/161420/

https://ibusinessday.com/assumption-of-parallelism-in-geological-modelling/

https://caribbeanfever.com/photo/albums/fdga4

http://snaplant.com/question/assumption-of-parallelism-in-geological-modelling/

https://paste.intergen.online/view/194451d2

https://www.kikyus.net/t16083-topic#17457

https://muertadota2.hashnode.dev/we-acknowledge-that-the-modelling-assumption

http://allabouturanch.com/photo/albums/fdga4

https://pastehere.xyz/xzPl5boDn/

https://healingxchange.ning.com/photo/albums/fdga4

https://fnote.net/notes/cq22vG

https://yamcode.com/dsf34-8936

https://ctxt.io/2/AACQe-MVFA

https://justpaste.me/yYTB1

https://pastelink.net/x6pw7ngk

https://homment.com/DjXg4bGrav6FWL6CEnjg

https://rentry.co/3hp9x

https://justpaste.it/9tzwb

https://paste.toolforge.org/view/0bc97571

https://paste.drhack.net/?1e4728458af09102#9AzWxm9kxpAhZUjkUqRJeoaEAwzUEEoFCJbqMvMaKsoA

https://paste.imirhil.fr/?e33aa80286d81d1e#fdK+vVupY+iN0SQzC8meNLAhsFhPXOD/TnsJhBorR9I=

https://controlc.com/e0ed089f

https://etextpad.com/fvxc42kjvq

https://privatebin.net/?6c323fbcf01ee7a7#BH9vGUQApMnEA8isVrfAbhmFjhrTiE3X3Es6f1SbW8MF

https://bitbin.it/Zs0rqbLw/

https://snippet.host/ydwuon

https://pro.pasteshr.in/yxwy1cfwhj

https://www.bankier.pl/forum/temat_the-criteria-to-detect-angular-unconformity,60532011.html

http://pastebin.falz.net/2501209

https://learn.acloud.guru/profile/godsmantownen-ll-l-1

https://godsmantownen.gumroad.com/

https://www.bitsdujour.com/profiles/HqRD9p

http://phillipsservices.net/UserProfile/tabid/43/userId/221652/Default.aspx

http://foxsheets.statfoxsports.com/UserProfile/tabid/57/userId/131991/Default.aspx

https://muckrack.com/godsman-townen/bio

https://www.signalmacc.org/group/holiday-market/discussion/26b50671-2c30-435f-bfb9-1b06ff258ff2

 


day−1
, and at the Muriaé station, with R2
of 0.864 and RMSE of 1.64 MJ m−2
day−1
. The models had their metrics compared to each other through the methodology of performance profiles, where the Multivariate Adaptive Regression Spline model proved to be more efficient. The results demonstrate that computational models perform better than the empirical models currently used.
Flood hazard mapping using M5 tree algorithms and logistic regression: a case study in East Black Sea Region
Flood is a type of disaster that occurs as a result of the overflow of the stream outside its bed. Similarly to many parts of the globe, particularly the Eastern Black Sea Region of Turkey is frequently exposed to major floods. The heavy rainfall and topographic structure of the region and the proximity of settlements to stream beds are the primary causes of flooding. The present study pertains to the utilization of the Logistic Regression (LR), M5P Rule Tree (M5PRT) and M5P Regression Tree (M5PRGT) models for the assessment of the flood hazard areas in and around the Of district, located on the Black Sea coast of Trabzon province. According to flood inventory, 16 flood events occurred in 5 different locations in the study area. These areas were converted into point data, and comprising a total of 1600 points, 800 flooded and 800 non-flooded, were determined by random sampling. Accordingly, flood hazard maps were created with 8 flood parameters and 3 different methods. Accuracies of these models were evaluated through AUC (Receiver Operating Characteristics Curve), ACC (Accuracy), R (Recall), P (Precision) and F (F-Score). Analyses showed that the Tree-Based Algorithms are more successful than the LR method in detecting the flood hazards. In addition, the altitude and precipitation were found out to be the most influential parameters in all 3 methods on the occurrence of flooding events in the region. The confluence points of the streams, the coastal plain where the stream disembogues to the sea and the valley floors in and around the Of district were designated as the areas with high risk of flooding.
Geological model automatic reconstruction based on conditioning Wasserstein generative adversarial network with gradient penalty
Due to the structure complexity and heterogeneity of the geological models, it is difficult for traditional methods to characterize the corresponding anisotropic and structural features. Therefore, one of the generative models called Generative Adversarial Network (GAN) are introduced to the geological modeling fields, which describes the complex structural features effectively according to fitting the high-order statistical characteristics. However, the traditional GAN might cause gradient explosion or vanishment, insufficient model diversity, resulting the network cannot capture the spatial pattern and characteristics of geological models so that the reconstruction always has a bad performance. For this issue, this paper introduced the Wasserstein Generative Adversarial Network with Gradient Penalty (WGAN-GP), which can better measure the distribution discrepancy between the generative data and real data and provide a meaningful gradient for the training process. In addition, the gradient penalty term can make the objective function conform with Lipschitz constraints, which ensures the training process more stable and the correlation between the generative and real samples. Meanwhile, the conditioning loss function can make the reconstruction conform with the conditioning constraints. The 2D and 3D categorical facies model were introduced to perform experimental verification. The results show that the CWGAN-GP ensure the conditioning constraints and the reconstruction diversity simultaneously. In addition, for the network finished training, through inputting different kinds of conditioning data, a variety of stochastic simulation results can be generated, thereby realizing rapid and automatic geological model reconstruction.

コメント