PIVlab - particle image velocimetry (PIV) tool with GUIPIVlab is a GUI based particle image velocimetry (PIV) software. It does not only calculate the velocity distribution within particle image pairs, but can also be used to derive, display and export multiple parameters of the flow pattern. A user-friendly graphical user interface (GUI) with the ability to control a PIV camera and a laser makes PIV data acquisition and data post-processing fast and efficient.Video tutorial 1/3: Quickstart guidehttps://youtube.com/watch?v=g2hcTRAzBvYVideo tutorial 2/3: Pre-processing, analysis and data validationhttps://youtube.com/watch?v=15RTs_USHFkVideo tutorial 3/3: Data exploration and data exporthttps://youtube.com/watch?v=47NCB_RFiE8Installation: https://github.com/Shrediquette/PIVlab/wiki#installation-instructionsPlease ask your questions in the PIVlab forum: http://pivlab.blogspot.de/p/forum.htmlSoftware documentation is available in the wiki: https://github.com/Shrediquette/PIVlab/wikiCode contributors:Main: William Thielicke (http://william.thielicke.org)Vectorization in piv_fftmulti: Sergey Filatov (http://www.issp.ac.ru/lqc/people.html)GUI parallelization: Chun-Sheng Wang, ParaPIV (https://de.mathworks.com/matlabcentral/fileexchange/63358-parapiv)Command line parallelization: Quynh M. Nguyen (https://github.com/quynhneo)Several donations to update Matlab licensesWe would like to acknowledge Uri Shavit, Roi Gurka & Alex Liberzon for sharing their code for 3-point Gaussian sub-pixel estimation. Thanks to Nima Bigdely Shamlo for allowing me to include the LIC function. Thanks to Raffel et al. for writing the book "Particle Image Velocimetry, A Practical Guide", which was a very good help.Visit Matlabs File exchange site for PIVlab:

This Toolbox contains functions and classes to represent orientation and pose in 2D and 3D (SO(2), SE(2), SO(3), SE(3)) as orthogonal and homogeneous transformation matrices, quaternions, twists, triple angles, and matrix exponentials. The Toolbox also provides functions for manipulating these datatypes, converting between them, composing them, transforming points and graphically displaying them.Much of this Toolbox functionality was previously in the Robotics Toolbox for MATLAB.

Gramm is a powerful plotting toolbox which allows to quickly create complex, publication-quality figures in Matlab, and is inspired by R's ggplot2 library. As a reference to this inspiration, gramm stands for GRAMmar of graphics for Matlab.USE CASES AND EXAMPLE SCREENSHOTS ON THE GITHUB README: https://github.com/piermorel/grammFor quick help use the cheat sheet: https://github.com/piermorel/gramm/raw/master/gramm%20cheat%20sheet.pdfCITE GRAMM:Morel, (2018). Gramm: grammar of graphics plotting in Matlab. Journal of Open Source Software, 3(23), 568, https://doi.org/10.21105/joss.00568WORKFLOW:The typical workflow to generate a figure with gramm is the following (the example figures in the vignette are generated using 6 lines of code):- In a first step, provide gramm with the relevant data for the figure: X and Y variables, but also grouping variables that will determine color, subplot rows/columns, etc.- In the next steps, add graphical layers to your figure: raw data layers (directly plot data as points, lines...) or statistical layers (plot fits, histograms, densities, summaries with confidence intervals...). One instruction is enough to add each layer, and all layers offer many customization options.- In the last step, gramm draws the figure, and takes care of all the annoying parts: no need to loop over colors or subplots, colors and legends are generated automatically, axes limits are taken care of, etc.FEATURES:- Accepts X,Y and Z data as arrays, matrices or cells of arrays- Accepts grouping data as arrays or cellstr. Gramm works best with table-like data: separate variables/fields/columns for the variables of interest, with each variable having as many elements as observations.- Multiple ways of separating data by groups: - Colors, lightness, point markers, line styles, and point/line size ('color', 'lightness', 'marker', 'linestyle', 'size') - Subplots by row and/or columns, or wrapping columns (facet_grid() and facet_wrap()). Multiple options for consistent axis limits across facets, rows, columns, etc. (using 'scale' and 'space').- Multiple ways of directly plotting the data: - scatter plots (geom_point()) and jittered scatter plot (geom_jitter()) - lines (geom_line()) - confidence intervals (geom_interval()) - bars plots (geom_bar()) - raster plots (geom_raster()) - point counts (point_count())- Multiple ways of plotting statistical visualizations of the data: - y data summarized by x values (uniques or binned) with confidence intervals (stat_summary()) - histograms and density plots of x values (stat_bin() and stat_density()) - histograms of x-y differences (stat_cornerhist()) - box and whisker plots (stat_boxplot()) - violin plots (stat_violin()) - quantile-quantile plots (stat_qq()) of x data distribution against theoretical distribution or y data distribution. - spline-smoothed y data with optional confidence interval (stat_smooth()) - 2D binning with contour or heatmap output (stat_bin2d()) - GLM fits (stat_glm(), requires statistics toolbox) - Custom fits with user-provided anonymous function (stat_fit(), requires curve fitting toolbox) - Ellipses of confidence (stat_ellipse())- Subplots are created without too much empty space in between (and resize properly !)- Polar coordinates (set_polar())- 'z' input data in gramm() creates 3D plots when using geom_point() or geom_line()- Color data can also be displayed as a continous variable, not as a grouping factor (set_continuous_color())- X and Y axes can be flipped to get horizontal statistics visualizations (coord_flip())- Color generation can be customized in the LCH color space, or can use alternative/custom colormaps (set_color_options())- Marker shapes and sizes can be customized with set_point_options()- Line styles and width can be customized with set_line_options()- Text elements aspect can be customized with set_text_options()- Confidence intervals as shaded areas, error bars or thin lines- Set the width and dodging of graphical elements in geom_ functions, stat_bin(), stat_summary(), and stat_boxplot(), with 'width' and 'dodge' arguments- The member structure results contains the results of computations from stat_ plots as well as graphic handles for all plotted elements- Global title (set_title)- Multiple gramm plots can be combined in the same figure by creating a matrix of gramm objects and calling the draw() method on the whole matrix. An overarching title can be added by calling set_title on the whole matrix.- Different groupings can be used for different stat_ and geom_ layers with the update() method- Matlab axes properties are acessible through the method axe_property- Custom legend labels with set_names- Plot reference elements on the plots with geom_abline, geom_vline, geom_hline, and geom_polygon- Date ticks with set_datetick- Draw in a specific figure or uipanel/uitab with set_parent()

These colormaps were developed by Kristen Thyng using viscm. They are perceptually uniform, as color should be when it serves as a numeric axis. If these colormaps are useful for you, please consider citing our paper: Thyng, K.M., C.A. Greene, R.D. Hetland, H.M. Zimmerle, and S.F. DiMarco. 2016. True colors of oceanography: Guidelines for effective and accurate colormap selection. Oceanography 29(3):9–13. http://dx.doi.org/10.5670/oceanog.2016.66

This AC/DC HMG has two AC voltage distribution levels (the primary level is 13,8 kV and the secondary level is 220 V) and one DC distribution level (300V). The AC MG operates at a frequency of 60 Hz.This test system simulation includes:• One diesel generator,• Two photovoltaic (PV) systems,• Two battery energy storage system,• Various linear and non-linear loads.Additionally, the DC microgrid model is extracted from the original model.

Augmented Lagrangian Digital Image Correlation (2D_ALDIC)AL-DIC(Augmented Lagrangian DIC) is a fast, parallel-computing hybrid DIC algorithm, which combines advantages of local subset DIC method (fast computation speed, and parallel computing) and finite-element-based global DIC method (guarantee global kinematic compatibility and decrease noise).Welcome to give the ALDIC code ratings and comments in the MATLAB File Exchange community: Advantages of AL-DIC algorithm[1] It’s a fast algorithm using distributed parallel computing.[2]Global kinematic compatibility is added as a global constraint in the form of augmented Lagrangian, and solved using Alternating Direction Method of Multipliers scheme.[3]Both displacement fields and affine deformation gradients are correlated at the same time.[4]No need of much manual experience about choosing displacement smoothing filters.[5]It works well with compressed DIC images and adaptive mesh. See our paper: Yang, J. & Bhattacharya, K. Exp Mech (2019). https://doi.org/10.1007/s11340-018-00459-y;[6]Both accumulative and incremental DIC modes are implemented to deal with image sequences, which is especially quite useful for very large deformations.[7]ALDIC application example -- uniaxial compression experiment:https://github.com/jyang526843/2D_ALDIC_v3/blob/master/Example_aldic_foam_compression_strain_eyy.gif[8]ALDIC is extended with adaptive quadtree mesh to solve complex geometry. Some examples: https://uwmadison.box.com/s/4n5hmf04rzp4la96bt2rcjk4f6o5d5nfPrerequisites & InstallationAL-DIC MATLAB code was tested on MATLAB versions later than R2018a. Both single thread and parallel computing features are included in AL-DIC code. Please download and unzip the code to the MATLAB working path. Then, execute the mail file: main_ALDIC.m.Code manualFull size code manual is available at:https://www.researchgate.net/publication/344796296_Augmented_Lagrangian_Digital_Image_Correlation_AL-DIC_Code_ManualCode demo videosALDIC Matlab code demo:(Youtube) https://www.youtube.com/watch?v=JctudMfO-7w(Bilibili) https://www.bilibili.com/video/BV1hf4y1i7bK/I also attach my EASF webinar to introduce AL-DIC/DVC algorithm and review other DIC/DVC methods:(Youtube) https://www.youtube.com/watch?v=-t61WrVagZ4(Bilibili) https://www.bilibili.com/video/BV1ff4y1B71L/Citation[1] For full details, and to use this code, please cite our paper:Yang, J. and Bhattacharya, K. Augmented Lagrangian Digital Image Correlation. Exp.Mech. 59: 187, 2018. https://doi.org/10.1007/s11340-018-00457-0. Full text can be requested at: www.researchgate.net/publication/329456141_Augmented_Lagrangian_Digital_Image_Correlation[2] Yang, J. (2019, March 6). 2D_ALDIC (Version 3.3). CaltechDATA. https://data.caltech.edu/records/1443% =========================================[3] Yang, J. and Bhattacharya, K. Combining Image Compression with Digital Image Correlation. Exp.Mech. 59: 629-642, 2019. https://doi.org/10.1007/s11340-018-00459-y. Full text can be requested at: https://www.researchgate.net/publication/330489954_Combining_Image_Compression_with_Digital_Image_Correlation[4] Finite-element-based Global DIC code is also available at:https://www.mathworks.com/matlabcentral/fileexchange/82873-2d-finite-element-global-digital-image-correlation-fe-dic[5] Besides 2D-DIC, our new code "ALDVC" (augmented Lagrangian Digital Volume Correlation) to track deformations in volumetric images is also available:https://www.mathworks.com/matlabcentral/fileexchange/77019-augmented-lagrangian-digital-volume-correlation-aldvcContact and supportJin Yang (Caltech solid mechanics, PhD '19): jyang526@wisc.edu -or- aldicdvc@gmail.comI appreciate your comments and ratings to help me further improve this code. If you have other questions, feel free to email me.

TopoToolbox provides a set of Matlab functions that support the analysis of relief and flow pathways in digital elevation models. The major aim of TopoToolbox is to offer helpful analytical GIS utilities in a non-GIS environment in order to support the simultaneous application of GIS-specific and other quantitative methods.TopoToolbox enables calculation of standard terrain attributes such as- slope- curvature- aspect- local topography- ...flow related terrain attributes such as- drainage basin delineation- flow accumulation- flow distance- ...stream network analysis such as- stream order- slope-area plots- chiplotsMoreover, TopoToolbox contains several tools to modify stream networks in an automated way and derive swath profiles, among other tools. The algorithms are fast and can thus be used in spatially distributed, dynamic modelling approaches in hydrology, glaciology and geomorphology. See http://topotoolbox.wordpress.com for examples and instructions.

When color is a numerical axis, it should not be distorted. This function is similar to the cmocean (Thyng et al., 2016) function also found on File Exchange, but this one's for Fabio Crameri's colormaps (Crameri 2018a,b).

Social Network Search (SNS) is a novel metaheuristic optimization algorithm, and its socrce code for solving mixed continuous/discrete engineering optimization problems is presented here. The SNS algorithm mimics the social network user’s efforts to gain more popularity by modeling the decision moods in expressing their opinions. Four decision moods, including Imitation, Conversation, Disputation, and Innovation are real-world behaviors of users in social networks. These moods are used as optimization operators that model how users are affected and motivated to share their new views.Related papers:Hadi Bayzidi, Siamak Talatahari, Meysam Saraee, Charles-Philippe Lamarche, "Social Network Search for Solving Engineering Optimization Problems", Computational Intelligence and Neuroscience, vol. 2021, Article ID 8548639, 32 pages, 2021. https://doi.org/10.1155/2021/8548639S. Talatahari, H. Bayzidi and M. Saraee, "Social Network Search for Global Optimization," in IEEE Access, vol. 9, pp. 92815-92863, 2021, doi: https://doi.org/10.1109/ACCESS.2021.3091495 .In this source code, the sns algorithm is employed for solving the following benchmark problems:1 - Speed reducer design2 - Tension/compression spring design3 - Pressure vessel design4 - Three-bar truss design problem5 - Design of gear train6 - Cantilever beam7 - Minimize I-beam vertical deflection8 - Tubular column design9 - Piston lever10 - Corrugated bulkhead design11 - Car side impact design12 - Design of welded beam design13 - A reinforced concrete beam design

Source code and user interface for Golden Eagle Optimizer (GEO) and Multi-Objective Golden Eagle Optimizer (MOGEO) metaheuristic algorithms Original paper: https://doi.org/10.1016/j.cie.2020.107050 Preprint: https://www.researchgate.net/publication/347685369_Golden_Eagle_Optimizer_A_nature-inspired_metaheuristic_algorithm Email: geo.algorithm@gmail.com

Metaheuristics play a crucial role in solving optimization problems. The majority of such algorithms are inspired by collective intelligence and foraging of creatures in nature. In this paper, a new metaheuristic is proposed inspired by African vultures’ lifestyle. The algorithm is named African Vultures Optimization Algorithm (AVOA) and simulates African vultures’ foraging and navigation behaviors. To evaluate the performance of AVOA, it is first tested on 36 standard benchmark functions. A comparative study is then conducted that demonstrates the superiority of the proposed algorithm compared to several existing algorithms. To showcase the applicability of AVOA and its black box nature, it is employed to find optimal solutions for eleven engineering design problems. As per the experimental results, AVOA is the best algorithm on 30 out of 36 benchmark functions and provides superior performance on the majority of engineering case studies. Wilcoxon rank-sum test is used for statistical evaluation and indicates the significant superiority of the AVOA algorithm at a 95% confidence interval.Main paper:African vultures optimization algorithm: A new nature-inspired metaheuristic algorithm for global optimization problems Benyamin Abdollahzadeh, Farhad Soleimanian Gharehchopogh, Seyedali Mirjalili,Computers & Industrial Engineering,2021,DOI: https://doi.org/10.1016/j.cie.2021.107408.Download the paper from:https://www.researchgate.net/publication/351795002_African_Vultures_Optimization_Algorithm_A_New_Nature-Inspired_Metaheuristic_Algorithm_for_Global_Optimization_Problemshttps://www.sciencedirect.com/science/article/abs/pii/S0360835221003120Email: benyamin.abdolahzade@gmail.comHomepage:https://www.researchgate.net/profile/Benyamin-Abdollahzadeh

# HRVTool v1.07## Methods for analyzing Heart Rate VariabilityThe present functions are originally made for Matlab R2016b. Errors may occur using older releases (at least R2014b required). Additional toolboxes are not required to run the basic analysis. The Image Processing Toolbox is recommended and required to use the 'picker'-functionality.Importing ECGs out of PDFs requires Matlab start as administrator and the installation of Inkscape (or for Linux: PDFminer and pdf2svg).**HRV.m** is a Matlab class containing function for analyzing HRV.**HRVTool.m** contains the code to start the GUI (Graphical User Interface) on Matlab.**HRVTool.mlappinstall** is the app package which can be installed with Matlab.Please run HRVTool.m to start the GUI or click on the icon in the App menu of Matlab.The user interface has been tested on Windows 10, Linux Ubuntu 18.04 and Mac OS 10.15.6.### Supported file types- [x] HRM - Polar files- [x] MAT - Matlab files, structures or workspace variables containing waveforms or RR intervals (in ms)- [x] TXT - text files containing waveforms or RR intervals (in ms)- [x] ECG - PhysioNet files (PhysioNet wfdb toolbox required)- [x] WAV - Hexoskin files- [x] EDF - European Data Format- [x] ACQ - BIOPAC data (Source code of Jimmy Shen)- [x] ISHNE - Holter Standard Format (ECG and annotation data)- [x] MIBF - Machine Independent Beat file (GE Marquette holter format)- [x] PDF - ECG-PDFs from Apple Watch and AliveCor devices (Kardia and aliveecg)Other formats are possible to integrate. Please address your wishes to marcus.vollmer@uni-greifswald.deSupporting files to load BIOPAC ACQ data (load_acq.m, acq2mat.m) are licensed by Jimmy Shen given the copyright notice LICENSE_ACQ.Copyright (c) 2009, Jimmy ShenAll other supported files and functions are licensed under the terms of the MIT License (MIT) given in LICENSE and LICENSE_ICONSCopyright (c) 2015-2020 Marcus Vollmer27 October 2020

Nowadays, the design of optimization algorithms is very popular to solve problems in various scientific fields. The optimization algorithms usually inspired by the natural behaviour of an agent, which can be humans, animals, plants, or a physical or chemical agent. Most of the algorithms proposed in the last decade inspired by animal behaviour. In this article, we present a new optimizer algorithm called the Wild Horse Optimizer (WHO), which is inspired by the social life behaviour of wild horses.

MOBATSimMOBATSim (Model-based Autonomous Traffic Simulation Framework) is a framework based on MATLAB® and Simulink® that allows users to develop automated driving algorithms and assess their safety and performance. By running a traffic simulation, the safety of the implemented component or algorithm can be measured on both the vehicle level and the traffic level, supported by 2D and 3D visualization options.Consider starring our GitHub Repositories and subscribing to our MOBATSim YouTube Channel to support us!Autonomous Vehicle Modeling and Simulation in Simulink TutorialsTable of contentsIntroductionKey Features of MOBATSimRequirementsCitationContributing to MOBATSimRelease NotesGetting StartedIntroductionAutomated driving systems tend to be more critical and sophisticated in the nearest future. The functional safety assessment for these systems becomes an urgent necessity for the transition to full autonomy. Testing these functions consisting of decision and control algorithms with many variables and parameters in a unified manner is a daunting task. Threat assessment has to be made for vehicles to avoid hazardous situations actively. This requires analyzing complex operational profiles such as routing, intersection management, and collision prediction in an environment where multiple vehicles are in different positions and traveling at different speeds. There is a need for a comprehensive traffic simulation framework that models the functionality of the vehicles and the interactions between them.More detailed information about the scientific papers related to MOBATSim can be found on our website,or you can visit our YouTube Channel where we publish the latest updates with tutorial videos:Key Features of MOBATSimAll the scripts, class files, and functions used in MOBATSim are open for editing. Users can control all the vehicles, traffic management algorithms, and the map.Each vehicle is considered as an agent, and the traffic is simulated as a closed-loop multi-agent system. The vehicles generate their trajectories during the simulation according to the states and intentions of the other vehicles around in the environment. This feature also allows reactive planning algorithms to be developed and tested.Users can either develop an algorithm or a controller for a single vehicle (usually referred to as the ego vehicle) or different implementations for different vehicles simultaneously.Full control over all the states regarding the simulation allows for fault injection and error propagation analysis. States can be easily manipulated during the simulation by implementing either Simulink fault injection blocks or code snippets in MATLAB System Block functions.MOBATSim can be used for benchmarking control and decision algorithms regarding safety and performance on different abstraction levels such as component level, vehicle level, and traffic level.Object-oriented programming structure (MATLAB Classes) combined with a block diagram environment (Simulink) allows a flexible framework suitable for collaboration.Data logging can be extended to states and signals of interest other than the default vehicle states used by the post-simulation 3D visualization.The compatible data structure allows for various post-simulation visualization options (e.g., Unreal Engine 4 support, Bird's Eye View Scope, or Simulink 3D Animation).MOBATSim's compatible map structure allows road network extensions through a user-friendly interface using the Driving Scenario Designer app.MATLAB Version and Toolbox RequirementsMOBATSim is continuously updated with the latest version of MATLAB®. Therefore the requirement is MATLAB R2021a or MATLAB R2020b. The following toolboxes are required for running MOBATSim:Simulink® and Stateflow®Automated Driving Toolbox™Robotics System Toolbox™Control System Toolbox™Deep Learning Toolbox™Symbolic Math Toolbox™Model Predictive Control Toolbox™ (only if MPC-Cruise Controller Block is used)Simulink 3D Animation Toolbox™ (only required for the 3D Animation Virtual World)Authors and ContactMain Author: Mustafa SaraoğluContributors: Johannes Pintscher, Laura Slabon, Qianwei Yang, Qihang Shi, Wenkai Wu, Maoxuan Zhao, Erik Noack, Fabian Hart, Müjdat Korkmaz, Marta Valdes MartinMessage us via the contact form on our website!Copyright © 2017 MOBATSim.Please Cite Our Related Paper as:Saraoglu, M., Morozov, A., & Janschek, K. (2019). MOBATSim: MOdel-Based Autonomous Traffic Simulation Framework for Fault-Error-Failure Chain Analysis. IFAC-PapersOnLine, 52(8), 239–244. Elsevier BV. Retrieved from https://doi.org/10.1016%2Fj.ifacol.2019.08.077BibTex:@article{MOBATSim, title = {{MOBATSim}: {MOdel}-Based Autonomous Traffic Simulation Framework for Fault-Error-Failure Chain Analysis}, journal = "IFAC-PapersOnLine", volume = "52", number = "8", pages = "239 - 244", year = "2019", note = "10th IFAC Symposium on Intelligent Autonomous Vehicles IAV 2019", issn = "2405-8963", doi = "https://doi.org/10.1016/j.ifacol.2019.08.077", url = "http://www.sciencedirect.com/science/article/pii/S2405896319304100", author = "Mustafa Saraoglu and Andrey Morozov and Klaus Janschek", keywords = "Autonomous driving, Fault injection, Error propagation, Safety analysis, Traffic simulator", }Contributing to MOBATSimIf you find MOBATSim useful and you would like to improve it by implementing your own automated driving algorithms:"Fork" the repository from the top right corner.Go to your forked repository and switch to the development branch.Make your changes in the development branch. Make sure your contributions fit the format in terms of coding or input/output properties of the Simulink blocks.To make sure that your changes work, you should run MOBATSimAutoTesting.m in src/Scripts folder and if you get passed from all the tests, you should "commit" and then "Push" to your forked repository.Then if you would like to contribute, send a "Pull Request" to the corresponding branch on the MOBATSim/MOBATSim repository.Once it is reviewed, it will be approved or changes will be requested along with the comments of the reviewer regarding the issue with your Pull Request.We would like to encourage everyone who would like to contribute, so you can also contact us for a more detailed explanation of the structure!Release Notes - Version 2.0New ways to visualize your driving scenario: Unreal Engine 4 support via DrivingScenarioDesigner App, Bird's Eye View.New vehicle kinematic bicycle models taken from the Automated Driving Toolbox library.A more detailed road structure with actual units as meters and double lane roads.New lateral controllers: Stanley lateral controller for common vehicles, Pure Pursuit lateral controller for the Ego Vehicle (Vehicle 2).Implementation of Frenet Coordinate system for local trajectory planning.Implementation of lane-changing maneuver on double lane roads (at the moment only allowed for Pure Pursuit controller - Ego Vehicle)An improved coding structure using superclasses, name-value pairs to also enhance the flexibility of MOBATSim and also code optimization using vectorizations and memory preallocations to increase the performance.Detailed documentation for the people who are interested and would like to understand and contribute to MOBATSimBonus content: 3D Animation World with the new Dinosaur Park.Known Issues and BugsVehicles are not allowed to start or finish on the intersection points to avoid congestion.Bird's Eye View or DrivingScenarioDesigner APP might work slowly because of the size of the road network.Some road merges do not have safety guarantees which means that a vehicle just merging another road at the same time with another vehicle or there is a stopping vehicle at the merging point of the joining road may cause collisions.Changing the default sample time value of 0.02 or playing with different Simulink Solver options other than auto may cause unexpected behavior.Getting StartedMOBATSim has a project file that includes the Simulink files and their paths. The project can be opened by double-clicking on MOBATSim.prj and a GUI will appear, which can be used to start the simulation. Simply click on Start Simulation and wait for the simulation to start.First it would be best if you fork the MOBATSim repository and then clone it to your computer. After opening the MOBATSim folder please refer to the live script file GettingStarted.mlx for more detailed documentation.

With MIB2 you can analyse, segment and visualize various multidimensional datasets from both light and electron microscopy. MIB2 is completely rewritten to follow MVC architecture and brings additional stability among many new features. See more further details and tutorials on MIB website: http://mib.helsinki.fiI would like to acknowledge Matlab File Exchange user community and especially the authors whose functions were utilized during development of the program: http://mib.helsinki.fi/acknowledgements.htmlThe MIB version 1 is available from here http://se.mathworks.com/matlabcentral/fileexchange/56481-microscopy-image-browser--mib- and recommended for Matlab version: R2011a - 2014aList of all features with video tutorials is available from http://mib.helsinki.fi/features_all.htmlFeatures:Support 2D-4D datasets (x,y,c,z,t) Up to 9 simultaneously opened datasets Bounding box for each dataset Extendible via plugins Log of performed actions Customizable undo system Customizable keyboard shortcuts Colorblind friendly color schemes Regions of interestsVirtual stacking mode for working with datasets that are larger than available memory Batch processing mode Data import/exportDirect import/export with Matlab , Fiji , Imaris and system clipboard Direct import from Omero server and URL links Load and save to TIF, Amira Mesh, JPG, Fiji BigDataViewer, HDF5, MRC, NRRD, PNG formatsLoad up to 100 different image and video formatsMicrosoft Excel (export) for quantificationRename and shuffle tool for unbiased classification and segmentationQuantification and StatisticsObjects: Area (2D/3D)Objects: ConvexArea (2D)Objects: Curve Length (2D, pixels and image units)Objects: Eccentricity (2D)Objects: Equatorial Eccentricity (3D)Objects: Equiv Diameter (2D)Objects: Euler number (2D)Objects: Extent (2D)Objects: Filled area (2D/3D)Objects: Holes area (2D/3D)Objects: Length between end points (2D/3D)Objects: Major axis length (2D/3D)Objects: Meridional Eccentricity (3D)Objects: Orientation (2D)Objects: Perimeter (2D)Objects: Second axis length (2D/3D)Objects: Solidity (2D)Objects: Third axis length (3D)Intensity: Correlation (2D/3D)Intensity: Maximal (2D/3D)Intensity: Mean (2D/3D)Intensity: Minimal (2D/3D)Intensity: Standard deviation (2D/3D)Intensity: Sum (2D/3D)MeasurementsAnglesCaliperCircle, radiusFreehand distance and intensity profileLinear distance and intensity profilePolyline distance and intensity profileStereology Wound healing assaySegmentation tools3D ball (3D) 3D lines (3D) Annotations with values Brush tool (2D) Brush tool for 2D superpixels (SLIC , Watershed )Black and White Thresholding tool (global, local, adaptive; 2D/3D) Deep convolutional neural networks for train and prediction Dilate (2D/3D, difference)Drag & Drop Erode (2D/3D, difference)Fill holes (2D/3D)Frame selection tool Frangi tubular filter (2D/3D)Graphcut based semi-automatic segmentation(2D/3D) , Lasso tool (2D/3D) Magic Wand tool (2D/3D) Membrane Click Tracker tool (2D/3D) Morphological operations (branch points, diagonal fill, end points, skeleton, spur, thin, ultimate erosion) Object Picker (2D/3D) Quantification Filtering (2D/3D) Random Forest Classifier (2D/3D)Shape and Line Interpolation (3D) Smooth (2D/3D)Spot tool (2D/3D) Watershed for automatic image segmentation and object separation (2D/3D)Segmentation tools3D ball (3D) 3D lines (3D) Annotations with values Brush tool (2D) Brush tool for 2D superpixels (SLIC , Watershed )Black and White Thresholding tool (global, local, adaptive; 2D/3D) Deep convolutional neural networks for train and prediction Dilate (2D/3D, difference)Drag & Drop Erode (2D/3D, difference)Fill holes (2D/3D)Frame selection tool Frangi tubular filter (2D/3D)Graphcut based semi-automatic segmentation(2D/3D) , Lasso tool (2D/3D) Magic Wand tool (2D/3D) Membrane Click Tracker tool (2D/3D) Morphological operations (branch points, diagonal fill, end points, skeleton, spur, thin, ultimate erosion) Object Picker (2D/3D) Quantification Filtering (2D/3D) Random Forest Classifier (2D/3D)Shape and Line Interpolation (3D) Smooth (2D/3D)Spot tool (2D/3D) Watershed for automatic image segmentation and object separation (2D/3D)Image ProcessingAdd frame around the dataset Alignment Brightness, Contrast, Gamma adjustments Chop and re-chop large dataset to smaller volumesContent-aware fill Contrast-limited adaptive histogram equalizationColor mode change (depth, color type)Color channel operations (add, copy, delete, invert, rotate, shift, swap) Crop , Resize , Flip , Rotate , Transpose Crop 2D/3D objects to files Debris removal Image arithmetics Image filtersIntensity normalization in Z/T (complete slice, masked areas, background shift) Intensity replacement within selected areas Invert Manipulations with slices: insert, copy, delete Intensity projections and focus stacking Morphological operationsVisualizationOrthoslices (XY, ZX, ZY planes) Volume Rendering (hardware) Volume Rendering (software) Models with Matlab isosurfaces Models and volumes with Fiji 3D viewer Models and volumes with Imaris Export models to IMOD Export models to Amira Export models to 3D Slicer Export models and volumes to Matlab Volume Viewer Export models in STL format

This toolbox offers a Whale Optimization Algorithm (WOA) methodThe < Main > script illustrates the example of how WOA can solve the feature selection problem using benchmark data-set.**********************************************************************************************************************************

To transfer the learnable parameters from pre-trained 2D ResNet-18 (ImageNet) to 3D one, we duplicated 2D filters (copying them repeatedly) through the third dimension. This is possible since a video or a 3D image can be converted into a sequence of image slices. In the training process, we expect that the 3D ResNet-18 learns patterns in each frame. This model has 34 million learnable parameters. simply, call "resnet18TL3Dfunction()" function.

Damping ratio estimation from ambient vibrations (SDOF)SummaryIf the free-decay response (FDR) of a Single Degree-of-Freedom (SDOF) system is not directly available, it is possible to use ambient vibrations data yo estimate the modal damping ratio. Here, the Random Decrement Technique (RDT) [1], as well as the Natural Excitation Technique (NExT) [2], are used. First, the response of a SDOF to white noise is simulated in the time domain using [3]. Then the IRF is computed using the RDT or NExT. Finally, and an exponential decay is fitted to the envelop of the IRF to obtain the modal damping ratio.ContentThe present submission contains:a function RDT.,m that implements to Random Decrement Technique (RDT)a function NExT that implements the Natural Excitation Technique (NExT)a function expoFit that determine the modal damping ratio by fitting an exponential decay to the envelope of the IRF.a function CentDiff used to simulate the response to a white noise load of a SDOF in the time domain.An example file Example.mAny question, comment or suggestion is welcomed.References[1] Ibrahim, S. R. (1977). Random decrement technique for modal identification of structures. Journal of Spacecraft and Rockets, 14(11), 696-700.[2] James III, O. H., & Came, T. G. (1995). The natural excitation technique (next) for modal parameter extraction from operating structures.[3] http://www.mathworks.com/matlabcentral/fileexchange/53854-harmonic-excitation-of-a-sdof

The Geometry and Image-Based Bioengineering add-On for MATLABhttp://gibboncode.org/GIBBON (The Geometry and Image-Based Bioengineering add-ON) is an open-source MATLAB toolbox by Kevin M. Moerman and includes an array of image and geometry visualization and processing tools and is interfaced with free open source software such as TetGen, for robust tetrahedral meshing, and FEBio for finite element analysis. The combination provides a highly flexible image-based modelling environment and enables advanced inverse finite element analysis.IMPORTANT cite as: K. M. Moerman, “GIBBON: The Geometry and Image-Based Bioengineering add-On,” J. Open Source Softw., vol. 3, no. 22, p. 506, Feb. 2018, doi: 10.21105/joss.00506Example sentence to cite this work: "... the mesh was created using the open source toolbox GIBBON (v3.5.0, Moerman et al. 2018, https://www.gibboncode.org)"

The Chaos Game Optimization (CGO) algorithm is a simple however efficient optimization meta-heuristic presented. The main concept of the CGO algorithm is based on some principles of chaos theory in which the configuration of fractals by chaos game methodology alongside the fractals self-similarity issues are in perspective. Author and programmer: S. Talatahari, M. Azizi, Email: Siamak.Talat@gmail.com, mehdi.azizi875@gmail.comMain paper: 1.S. Talatahari, M. Azizi, Chaos Game Optimization: a Novel Metaheuristic Algorithm, Artificial Intelligence Review, 2020, https://doi.org/10.1007/s10462-020-09867-w2.S. Talatahari, M. Azizi, Optimization of Constrained Mathematical and Engineering Design Problems Using Chaos Game Optimization, Computers & Industrial Engineering, Volume 145, Pages 106560, https://doi.org/10.1016/j.cie.2020.106560

Blind deconvolution methods, such as minimum entropy deconvolution (MED), Maximum correlated Kurtosis deconvolution (MCKD) and Maximum second-order cyclostationarity blind deconvolution (CYCBD), which can counteract the effect of the transmission path, have been widely applied in machinery fault diagnosis. Taking the periodicity and the impulsiveness into consideration simultaneously, MCKD, CYCBD can solve the problem of MED which prefers to focus on the random impulse rather than the periodic fault impulses. Yet, the superiority of MCKD and CYCBD highly depends on the prior fault period. In industrial applications, it is difficult to accurately obtain the fault period due to the rotating speed fluctuation and the measurement problem. Therefore, we firstly proposed to estimate the iterative period by using the iterative algorithm to solve the problem of the prior period in blind deconvolution methods. According to the principle of autocorrelation, that is it will show a higher value when the time delay meets the period or its multiple, the location with local maximum value is selected as the iterative period in MCKD. And envelope harmonic product spectrum (EHPS), is initially tailored to estimate the characteristic frequency in CYCBD. The period estimation based on the iterative algorithm in BDMs can help MCKD and CYCBD apply in the machinery fault diagnosis without prior knowledge. The matlab codes of period estimation using autocorrelation permit to reproduce some results in the papers:[1] Y. Miao, M. Zhao, J. Lin, Y. Lei, Application of an improved maximum correlated kurtosis deconvolution method for fault diagnosis of rolling element bearings, Mechanical Systems and Signal Processing, 92 (2017) 173-195.[2] Y. Miao, M. Zhao, K. Liang, J. Lin, Application of an improved MCKDA for fault detection of wind turbine gear based on encoder signal, Renewable Energy, 151 (2020) 192-203. The matlab codes of period estimation using EHPS permit to reproduce some results in the papers:[1] B. Zhang, Y. Miao, J. Lin, Y. Yi, Adaptive maximum second-order cyclostationarity blind deconvolution and its application for locomotive bearing fault diagnosis, Mechanical Systems and Signal Processing, 158 (2021) 107736.[2] Y. Miao, B. Zhang, J. Lin, M. Zhao, H. Liu, Z. Liu, H. Li, A review on the application of blind deconvolution in machinery fault diagnosis, Mechanical Systems and Signal Processing, 163 (2022) 108202. In addition, the matlab codes of the deconvolution method, Sparse maximum harmonics-to-noise-ratio deconvolution (SMHD), permit to reproduce some results in the papers:[1] Y. Miao, M. Zhao, J. Lin, X. Xu, Sparse maximum harmonics-to-noise-ratio deconvolution for weak fault signature detection in bearings, Measurement Science and Technology, 27 (2016) 105004.[2] Y. Miao, B. Zhang, J. Lin, M. Zhao, H. Liu, Z. Liu, H. Li, A review on the application of blind deconvolution in machinery fault diagnosis, Mechanical Systems and Signal Processing, 163 (2022) 108202. Copyright (c) belongs to the authors of the papers. An acknowledgment for the codes and the citations about all the papers above must be included in the publications as long as the codes are used.Our works and full texts can referhttps://www.researchgate.net/profile/Yonghao-Miaohttps://scholar.google.com.hk/citations?user=gRZ_iZsAAAAJ&hl=zh-CN&oi=ao

Wind turbulence generation using text-based input filesFor a more robust and time-efficient Matlab implementation, see https://se.mathworks.com/matlabcentral/fileexchange/68632-wind-field-simulation-the-fast-version.SummaryA method to simulate spatially correlated turbulent wind histories is implemented following [1,2].Two possible vertical wind profiles and two possible wind spectra are implemented. The user is free to implement new ones. The wind co-coherence is a simple exponential decay as done by Davenport [3]. If the wind field is simulated in a grid, the function windSim.m should be used (cf. Examples 1 and 2). For a more complex geometry, such as a radial grid, the function windSim.m has an optional parameter to include two inputs (cf. Example3.mlx): The first one contains the wind properties, and the second one contains the coordinates of the nodes where wind histories are simulated (cf. Example 3).ContentThe folder windSim.zip contains:1 input file INPUT.txt for Example1.m1 input file INPUT_MAST.txt for Example2.m2 input files windData.txt and circle.txt for Example3.mThe function windSim.m4 examples files Example1.m, Example2.m, Example3.m and Example4.mThe function coherence.m that computes the co-coherence.Notes:Simulating the wind field in a high number of points with a high sampling frequency may take a lot of time.This code aims to be highly customizableA faster version of the present submission has been used to simulate the turbulent wind load on a floating suspension bridge [4].References[1] Shinozuka, M., Monte Carlo solution of structural dynamics, Computers and Structures, Vol. 2, 1972, pp. 855 – 874[2] Deodatis, G., Simulation of ergodic multivariate stochastic processes, Journal of Engineering Mechanics, ASCE, Vol. 122 No. 8, 1996, pp. 778 – 787.[3] Davenport, A. G. (1961), The spectrum of horizontal gustiness near the ground in high winds. Q.J.R. Meteorol. Soc., 87: 194–211[4] Wang, J., Cheynet, E., Snæbjörnsson, J. Þ., & Jakobsen, J. B. (2018). Coupled aerodynamic and hydrodynamic response of a long span bridge suspended from floating towers. Journal of Wind Engineering and Industrial Aerodynamics, 177, 19-31.

Automated Frequency Domain Decomposition (AFDD)Automated Modal parameters identification from ambient vibrations measurementSummaryThe automated Frequency Domain Decomposition presented was applied in [1]. It inspired by the Frequency Domain Decomposition (FDD) introduced by [2, 3]. The goal is to identify the mode shapes, eigenfrequencies and modal damping ratios from acceleration records obtained during structural health monitoring of civil engineering structures subjected to ambient noise. In this submission, an automated procedure is implemented in addition to the manual one proposed by [4]. For the automated procedure, I am using the peak picking function “pickpeaks” developed by [5] and available in [6], which was much more efficient than the Matlab function "findpeaks" for this purpose. I am, therefore, indebted to [4-6] for their previous works. The modal damping ratios are determined for each mode by using [7]. The acceleration data comes from a time-domain simulation of a clamped-free beam response to white noise excitation. The target modal properties from the beam come from [8].ContentThe submission contains:The function AFDDA Matlab livescript file Documentation.mlxAcceleration data beamData.m (4 Mb)The function pickpeaks.m [6]Any comment, suggestion and question is welcome.References[1] Cheynet, E., Jakobsen, J. B., & Snæbjörnsson, J. (2017). Damping estimation of large wind-sensitive structures. Procedia engineering, 199, 2047-2053.[2] Brincker, R.; Zhang, L.; Andersen, P. (2001). "Modal identification of output-only systems using frequency domain decomposition". Smart Materials and Structures 10 (3): 441. doi:10.1088/0964-1726/10/3/303.[3] Brincker, R., Zhang, L., & Andersen, P. (2000, February). Modal identification from ambient responses using frequency domain decomposition. In Proc. of the 18*‘International Modal Analysis Conference(IMAC), San Antonio, Texas.[4] https://se.mathworks.com/matlabcentral/fileexchange/50988-frequency-domain-decomposition--fdd-[5] Antoine Liutkus. Scale-Space Peak Picking. [Research Report] Inria Nancy - Grand Est (Villers-lès-Nancy, France). 2015. .[6] https://se.mathworks.com/matlabcentral/fileexchange/42927-pickpeaks-v-select-display-[7] https://se.mathworks.com/matlabcentral/fileexchange/55557-modal-parameters-identification-from-ambient-vibrations--sdof-[8] https://se.mathworks.com/matlabcentral/fileexchange/52075-eigen-value-calculation-of-a-continuous-beam--transverse-vibrations-

Atomic Orbital Search (AOS) is a novel metaheuristic algorithm proposed for optimization purposes. The main concept of this algorithm is based on some principles of quantum mechanics and the quantum-based atomic model in which the general configuration of electrons around nucleus is in perspective.

FOPID tunerThis project is based on FOPD tuner: https://github.com/cnpcshangbo/FOPD-tuner/tree/optimization-method/controller-analysis-with-Simulink/optimizationUsageRun "run_patternsearch_npm"

Atomistic Topology Operations in MATLAB, functions for manipulation of molecular dynamics or monte carlo simulation systems.% Note that version 2.x comes with an extensive and searchable html-documentation for all the >100 functions, which can be used interactively from Matlab's own browser.% The purpose of the atom library is to automate and enable efficient construction/manipulation and analysis of complex and multicomponent molecular systems, and generate topological information with bonds and angles etc, over the PBC!It is especially useful for building inorganic/geochemical systems, since bond distances can be compared to the ideal semi-empirical bond distances computed with the Bond Valence Sum Method, or just simply just compared to Shannon's revised radii. Or one could plot a theoretical X-ray profile with the xrd_atom() function.% For lists of all available functions by category, see inside these files:List_all_functions.mList_build_functions.mList_export_functions.mList_general_functions.mList_import_functions.mList_forcefield_functions.m% The atom scripts can read and write basic .pdb | .xyz | .gro | .mol2 structure files as well as write basic .itp and .psf topology files. They can also manipulate/transform the structures in various ways making use of the MATLAB struct variable and indexing. The atom scripts can be used to build and plot multicomponent systems, by adding molecules, ions and SPC/TIP3P/TIP4P water molecules or other solvents (ie solvating an existing molecule/slab) into a simulation box, and remove molecular overlap. For plotting one can call vmd(atom,Box_dim) if the VMD software is also installed and the PATH2VMD() function is properly set. Else the very quick-and-dirty plot_atom(arguments) or the slower show_atom(arguments) can be used. Most functions takes PBC into account, which allows for generation of topologies of molecules with bonds, angles, dihedrals across the PBC. There is also some support for triclinic support using the tilt vectors xy, xz, yz, as well as for generating powder X-ray diffractograms using the function xrd_atom(). Michael Holmboe michael.holmboe@umu.se Chemistry departmentUmeå University, Sweden% Where to start? Perhaps the html-documentation with some basic examples? % % Some typical commands...%% To read a structure file into matlab (check the variable explorer) atom=import_atom('filename') % filename could be a .pdb | .xyz | .gro file % or... atom=import_atom_pdb('filenamepdb')atom=import_atom_gro('filenamegro') atom=import_atom_xyz('filenamexyz')% Note that you get a lot more info then just the atom struct variable, like the box dimension variable Box_dim % To write a atom struct to a new topology or structure filewrite_atom_lmp(atom,Box_dim,filename,1.2,1.2,'clayff') % supports bonds, angles, simple dihedralswrite_atom_psf(atom,Box_dim,filename,1.2,1.2,'clayff') % note only bonds and angleswrite_atom_itp(atom,Box_dim,filename,1.2,1.2,'clayff','spce') % Gromacs topology file, note only bonds and angleswrite_atom_pdb(atom,Box_dim,filename)write_atom_cif(atom,Box_dim,filename)write_atom_gro(atom,Box_dim,filename) write_atom_xyz(atom,Box_dim,filename)% Adding water to a box % - This function SOLvates a certain region defined by limits with a water or a custom solvent% structure with density. r (and r-0.5 for H) is the closest distance of solvent atoms% to the (optional) solute atomsSOL_atom = solvate_atom(limits,density,r,maxsol) % limits can be [10] | [10 20 30] | [10 20 30 40 50 60]SOL_atom = solvate_atom(limits,density,r,maxsol,solute_atom,'tip4p') % spc | tip3p | tip4p | tip5p% One can filter the atom struct with respect to molid, resname, atomtype, index, coordinates and so on. This allows manipulation of an atom struct on the atomic, molecule and molecular type level. This also allows us to use 'dynamic indexes' of groups of atom.{molid/resname/type/index/} when analyzing a trajectory for instance. Some basic examples: index=ismember([atom.type],[{'Al' 'Alt' 'Mgo'}]) % gives a binary (1/0) logical array index=strcmp([atom.type],'Al') % try also strncmp or strncmpi? index=find(strncmpi([atom.type],'al',2) % Will find the indexes of 'Al' 'Alt? new_atom=atom(index) % This creates a new_atom struct with the filtered/selected atomtypes positive_z_atom=atom([atom.z]>0) % finds all atoms with a positve z-coordinatefirst100_atom=atom([atom.index]<101) % finds the first 100 atoms in the atom struct first100_v2_atom=atom(1:100) % also finds the first 100 atoms in the atom struct% Merging two different atom structs % - This function returns the second atom set with non-overlapping atomsnew_atom = merge_atom(atom1,Box1,atom2,Box2,type,Atom_label,r)% Calculating bonds or the distance matrix/es atom = bond_angle_dihedral_atom(atom,Box_dim,1.2,2.2) % first cut-off for bonds to H's, second cut-off for everything else. Only atoms having the same MolID will be considered as bonded.dist_matrix = dist_matrix_atom(atom,Box_dim) % another cell lists version also exist.

GeographicLib toolboxVersion 1.52 2021-06-20This toolbox provides native MATLAB implementations of a subset of theC++ library, GeographicLib. Key components of this toolbox are * Geodesics: direct, inverse, area calculations. * Projections: transverse Mercator, polar stereographic, etc. * Grid systems: UTM, UPS, MGRS. * Geoid lookup: EGM84, EGM96, EGM2008 geoids supported. * Geometric transformations: geocentric, local cartesian. * Great ellipses: direct, inverse, area calculations.There is some overlap between this toolbox and MATLAB's MappingToolbox. However, this toolbox offers: * better accuracy; * treatment of oblate and prolate ellipsoids; * guaranteed convergence for geoddistance; * calculation of area and differential properties of geodesics; * ellipsoidal versions of the equidistant azimuthal and gnomonic projections.Subsets of this package were previously released as: Geodesics on an ellipsoid of revolution (deprecated) Geodesic projections for an ellipsoid (withdrawn) Great ellipses (withdrawn)Including all of the functionality in a single toolbox allows easiersharing of code (via a common private directory).Extensive documentation on the C++ library is available at https://geographiclib.sourceforge.io/1.52Geoid lookup requires the installation of one or more geoid models.Instructions for this are given in https://geographiclib.sourceforge.io/1.52/geoid.html#geoidinstA change log for this package is available at https://geographiclib.sourceforge.io/1.52/changes.html

A new meta-heuristic optimization approach, called “Sperm Swarm Optimization (SSO)” is proposed. The underlying ideas and concepts behind the proposed method are inspired by sperm motility to fertilize the egg. In SSO, sperm swarm moves forward from a low-temperature zone called Cervix. During this direction, sperm searches for a high-temperature zone called Fallopian Tubes where the egg is waiting for the swarm for fertilization in this zone, which this area is considered as the optimal solution. Note: This version of the code is without mutation part in which is a secondary thing.

Software for performing highly comparative time-series analysis in Matlab. Contains code for extracting over 7000 features from a given time series, and functions for visualizing and analyzing the results across a time-series dataset.

The optical tweezers toolbox can be used to calculate optical forces and torques of particles using the T-matrix formalism in a vector spherical wave basis. The toolbox includes codes for calculating T-matrices, beams described by vector spherical wave functions, functions for calculating forces and torques, simple codes for simulating dynamics and examples.

Polynomial chaos expansion (PCE) introduced by Norbert Wiener in 1938. PCE can be seen, intuitively, as a mathematically optimal way to construct and obtain a model response surface in the form of a high-dimensional polynomial in uncertain model parameters. Recently the polynomial chaos expansion received a generalization towards the arbitrary polynomial chaos expansion (aPC: Oladyshkin S. and Nowak W., 2012), which is a so-called data-driven generalization of the PCE. Like all polynomial chaos expansion techniques, aPC approximates the dependence of simulation model output on model parameters by expansion in an orthogonal polynomial basis. The aPC generalizes chaos expansion techniques towards arbitrary distributions with arbitrary probability measures, which can be either discrete, continuous, or discretized continuous and can be specified either analytically (as probability density/cumulative distribution functions), numerically as histogram or as raw data sets. The aPC at finite expansion order only demands the existence of a finite number of moments and does not require the complete knowledge or even existence of a probability density function. This avoids the necessity to assign parametric probability distributions that are not sufficiently supported by limited available data. Alternatively, it allows modellers to choose freely of technical constraints the shapes of their statistical assumptions. Investigations indicate that the aPC shows an exponential convergence rate and converges faster than classical polynomial chaos expansion techniques. The aPC Matlab Toolbox have been developed in the year 2010 for scientific purpose and now it is available for the Matlab community (see details in Readme file). AUTHOR: Sergey OladyshkinAFFILIATION: Stuttgart Research Centre for Simulation Technology, Department of Stochastic Simulation and Safety Research for Hydrosystems, Institute for Modelling Hydraulic and Environmental Systems, University of Stuttgart, Pfaffenwaldring 5a, 70569 StuttgartCONTACT INFORMATION: E-mail: Sergey.Oladyshkin@iws.uni-stuttgart.dePhone: +49-711-685-60116Fax: +49-711-685-51073Website: http://www.iws.uni-stuttgart.de

This model contains vehicle models that drive autonomously following each other on a highway. The following vehicle uses different controllers to follow the leading vehicle. The purpose of this model is to tune the MPC controller for the following vehicle so that it keeps a safe distance. The visualization is done by both 2D and 3D Animations at this point but we improve the model every week, we will include different vehicle following algorithms and visualizations such as gaming engines in the future. How to build this model is explained in this playlist and it is updated whenever another video is uploaded:https://www.youtube.com/playlist?list=PLNNL3443z4lHTmBFrrur6aYhJnwvITqWM

Simulating the propagation of elastic waves in multi-layered media has many applications. A common approach is to use matrix methods where the elastic wave-field within each material layer is represented by a sum of partial waves along with boundary conditions imposed at each interface. While these methods are well-known, coding the required matrix formation, inversion, and analysis for general multi-layered systems is non-trivial and can take a long time. Here, a new open-source toolbox called ElasticMatrix is introduced which solves the problem of acoustic and elastic wave propagation in multi-layered media for isotropic and transverse-isotropic materials where the wave propagation occurs in a material plane of symmetry. The toolbox is implemented in MATLAB using an object oriented programming framework and is designed to be easy to use and extend. Methods are provided for calculating and plotting dispersion curves (Lamb waves and other guided waves), displacement and stress fields, reflection and transmission coefficients, and slowness profiles (from the Christoffel Equation).Known issues:- For leaky structures the Lamb modes can trace incorrectly. If this occurs, try the .calculateDispersionCurveCoarse method.

mTRF-Toolbox is a MATLAB package for modelling multivariate stimulus-response data, suitable for neurophysiological data such as MEG, EEG, sEEG, ECoG and EMG. It can be used to model the functional relationship between neuronal populations and dynamic sensory inputs such as natural scenes and sounds, or build neural decoders for reconstructing stimulus features and developing real-time applications such as brain-computer interfaces (BCIs).

This is a detailed Matlab implementation of five classic inpainting methods (AMLE, Harmonic, Mumford-Shah, Cahn-Hilliard, Transport) described in "Partial Differential Equation Methods for Image Inpainting" (Carola-Bibiane Schönlieb, Cambridge University Press, 2015).

windSimFastA three-variate turbulent wind field (u,v and w components) is simulated in three-dimensions.SummaryA turbulent wind field (u,v,w, components) in 3-D (two dimensions for space and one for the time) is simulated using random processes. The computational efficiency of the simulation relies on Ref. [1], which leads to a significantly shorter simulation time than the function windSim, also available on fileExchange. However, only the case of a regular 2D vertical grid normal to the flow is here considered.ContentThe submission contains:An example file Example1 that illustrates simply how the output variables look like.An example file Example2, which is more complete, and which simulates a 3-D turbulent wind field on a 7x7 grid.An example file Example3, which illustrates the implementation of the quad-coherence to generate a turbulent wind field.A data file exampleData.mat used in Example1.The function windSimFast.m, which is used to generate the turbulent wind field. A similar implementation of windSimFast.m was used in ref. [2].The function getSamplingpara.m, which computes the time and frequency vectors.The function KaimalModel.m, which generates the one-point auto and cross-spectral densities of the velocity fluctuations, following the Kaimal model [3]. I have corrected the cross-spectrum density formula used by Kaimal et al. so that the simulated friction velocity is equal to the target one.The function coherence used to estimate the root-mean-square coherence, the co-coherence and the quad-coherence.Any comment, suggestion or question is welcomed.References[1] Shinozuka, M., & Deodatis, G. (1991). Simulation of stochastic processes by spectral representation. Applied Mechanics Reviews, 44(4), 191-204.[2] Wang, J., Cheynet, E., Snæbjörnsson, J. Þ., & Jakobsen, J. B. (2018). Coupled aerodynamic and hydrodynamic response of a long span bridge suspended from floating towers. Journal of Wind Engineering and Industrial Aerodynamics, 177, 19-31.[3] Davenport, A. G. (1961). The spectrum of horizontal gustiness near the ground in high winds. Quarterly Journal of the Royal Meteorological Society, 87(372), 194-211.

The VME is a robust method when there is no need to decompose the whole signal. Indeed, if the aim is to achieve a particular mode from the signal VME is the best choice (just by knowing an approximation of the frequency band of the specific mode of interest). Indeed, VME assumes that signal is composed of two parts: F(t)=Ud(t)+Fr(t); in which F(t) refers to input signal, Ud(t) is the desired mode, and Fr(t) indicates the residual signal.

This folder provides the Matlab codes of metaheuristic (EHO) and TOPSIS approach for solving the multiobjective optimal DG integration problems of distribution networks. The objective functions considered here are the minimization of power loss and node voltage deviation while maximizing the voltage stability index of the distribution system. It also includes the backwards-forward load flow method to solve the power flow equations.

The Simulink Module Tool performs several functions in order to support modular development for Simulink models. It helps with converting default Subsystems into Simulink Functions, scoping Simulink Functions, creating Function Callers, extracting a syntactic interface, listing dependencies, and other operations.• For more information, please see the included user guide: Simulink-Module/doc/SimulinkModule_UserGuide.pdf.• This tool relies on our Simulink Utility. Please download it here: https://github.com/McSCert/Simulink-Utility.

The smart phone is used as webcam device. We can use it by installing IP Webcam app. Make sure that the Laptop and your smart phone must me connected to the same network using Wifi.A specific solution for Android:Install the free IP Webcam app. (Make sure you read the corresponding permissions and understand any security issues therein)Open the app, set the desired resolution (will impact the speed!)Scroll to the bottom and tap on 'Start Server'

Here are some for loading and interpolating data from BedMachine. You'll have to get the BedMachine data from the NSIDC website (https://nsidc.org/data/idbmg4 for Greenland or https://nsidc.org/data/nsidc-0756 for Antarctica.) Download the full .nc files.Check the Examples tab above for explanations of how to use these functions. And as always, if you use this dataset, be sure to cite the Morlighem paper listed below. And if this toolbox is useful for you, please cite my AMT paper listed below.

Converting acceleration to displacements recordsSummaryThe present submission introduces a simple function ASD.m that is inspired by [1] but includes also the possibility to use the double integration technique instead of the Discrete Fourier Transform (DFT) when transforming acceleration records to displacement records. The simple right-hand difference technique is also implemented as an alternative to the DFT for transforming displacement data to acceleration data.The function also includes the possibility to compute the velocity histories from the acceleration of displacement records.ContentThe submission contains three files:The function ASD.m, which is an acronym for Acceleration-Speed-Displacement.Two data file data_bridge.mat and data_beam.mat that contains the computed vertical acceleration, velocity and displacement response from a suspension bridge and a cantilever beam, respectively. The data set is created using [2]Two example files Example1.mlx and Example2.mlx, that illustrates how the function ASD.m can be called.The is the second version of the submission, Several typos may still be present as well as bugs. Any suggestion, comment or question is welcomed. Credits for the present submission should also go to ref. [1] for the function iomega.References:[1] https://www.mathworks.com/matlabcentral/answers/21700-finding-the-velocity-from-displacement#answer_33902[2] https://www.mathworks.com/matlabcentral/fileexchange/66016-response-of-a-line-like-structure-to-a-random-load

Analyze spike train data exported from multi-electrode array recordings with advanced visualizations. Matlab not required.This stand-alone tool gives you the ability to:Load spike trains from a variety of electrode layoutsSelect electrodes from a graphical displayCrop time segmentsCalculate electrode-specific metrics for spike activityPlot and export raster plots in publication-ready formatPlot plate-wide activity with a bin size of your choosingCalcualte bursts based on your own burst definitionCalculate periodic intervals for plate-wide activityCalculate and visualize network correlation activityExport 3D visualizations and videosAll parameters are adjustable

Mode shapes extraction by time domain decomposition (TDD)SummaryThe Time domain decomposition (TDD) [1] is an output-only method to extract mode shapes of a structure. Here, the modal damping ratios and modal displacements are in addition extracted using the functions presented in [6]. The TDD is similar to a more popular technique called Frequency-domain method (FDD) that was introduced by [2,3]. A good example of the FDD already exists on the Matlab File Exchange [4]. In a previous version, the present submission contained a function for the FDD. This function has been modified and moved to a new submission [5].ContentThe submission contains:The function TDD.m: function to apply the TDD method.An example file Example1.mAcceleration data beamData.m (4 Mb)References[1] Byeong Hwa Kim, Norris Stubbs, Taehyo Park, A new method to extract modal parameters using output-only responses, Journal of Sound and Vibration, Volume 282, Issues 1–2, 6 April 2005, Pages 215-230, ISSN 0022-460X, http://dx.doi.org/10.1016/j.jsv.2004.02.026.[2] Brincker, R.; Zhang, L.; Andersen, P. (2001). "Modal identification of output-only systems using frequency domain decomposition". Smart Materials and Structures 10 (3): 441. doi:10.1088/0964-1726/10/3/303.[3] BRINCKER, Rune, ZHANG, Lingmi, et ANDERSEN, P. Modal identification from ambient responses using frequency domain decomposition. In: Proc. of the 18*‘International Modal Analysis Conference (IMAC), San Antonio, Texas. 2000[4] http://www.mathworks.com/matlabcentral/fileexchange/50988-frequency-domain-decomposition--fdd-[5] https://se.mathworks.com/matlabcentral/fileexchange/57153-automated-frequency-domain-decomposition--afdd-[6] https://se.mathworks.com/matlabcentral/fileexchange/55557-modal-parameters-identification-from-ambient-vibrations--sdof

In order to evaluate the thermo-mechanical behaviour of crystalline materials (such as metals or ceramics) at microscopic scale, one usually performs numerical simulation at grain scale using the Finite Element Method. In order to proceed, one must first create a mesh which is representative of the real material.The microstructure of crystalline materials is usually characterized using Electron Backscattered Diffraction (EBSD) technique. Thus, this toolbox is designed to generate meshes from EBSD in a robust and accurate way.

In this repository, we develop a comprehensive open-source MIMO-SAR imaging toolbox, which is a MATLAB based software package, including the complete signal processing chain of the prototyped testbed solutions in our journal paper (please see the reference below). The toolbox allows the user to control the testbeds and to reconstruct high-resolution 3-D holographic images using the captured experimental data.The developed toolbox consists of three main modules: (1) data capture, (2) MIMO array calibration, and (3) image reconstruction. The framework of each module is detailed in our journal paper.

Multi-trial vector-based differential evolution (MTDE) is distinguished by introducing an adaptive movement step designed based on a new multi-trial vector approach named MTV, which combines different search strategies in the form of trial vector producers (TVPs). In the developed MTV approach, the TVPs are applied on their dedicated subpopulation, which are distributed by a winner-based distribution policy, and share their experiences efficiently by using a life-time archive. The MTV can be deployed by different types of TVPs, particularly, we use the MTV approach in the MTDE algorithm by three TVPs: representative based trial vector producer, local random based trial vector producer, and global best history-based trial vector producer. The source code has been developed in Prof. Nadimi's research group and belongs to the following paper:Nadimi-Shahraki, M. H., Taghian, S., Mirjalili, S., & Faris, H. (2020). MTDE: An effective multi-trial vector-based differential evolution algorithm and its applications for engineering design problems. Applied Soft Computing, 106761, doi: https://doi.org/10.1016/j.asoc.2020.106761More information can be found here: https://seyedalimirjalili.com/de

SHape Analyser for Particle Engineering What SHAPE does • Architectural features • File tree • Simple example • Credits • BYOS • Acknowledging SHAPEWhat SHAPE doesSHAPE implements morphological characterisation of three-dimensional particles from imaging data, such as point clouds, surface and tetrahedral meshes or segmented voxelated images (derived using Computed Tomography). Characterisation of morphology is performed for all three aspects of shape, namely form, roundness and surface texture (roughness). The code also supports shape simplification, using edge-collapse techniques, to reduce the number of triangular faces of each particle to user-defined fidelity levels. The particle shapes can be exported to several formats, compatible with various FEA and DEM solvers.Architectural featuresSHAPE is built using an object-oriented architecture, where each particle has the following set of attributes:-Particle % e.g. 1, 2, 3, etc. -Particle_type % e.g. Original, Convex_hull, Face_No_100, Face_No_50, etc. -Mesh % Surface_mesh, Tetrahedral_mesh, Voxelated_image, Surface_texture -Auxiliary_geometries % AABB, OBB, Fitted_ellipsoid, Minimal_bounding_sphere, Maximal_inscribed_sphere -Geometrical_features % Volume, Centroid, Surface_area, Current_inertia_tensor, Principal_inertia_tensor, Principal_orientations -Morphological_features % Form, Roundness, RoughnessFile treeSHAPELICENSEREADME.mdREADME.txtclasses (Definition of objects)examplesfiguresfunctionslib (External dependencies)Simple exampleThis example demonstrates different ways to define Particle objects and characterise their morphology.addpath(genpath('functions'));% Load in-house functionsaddpath(genpath('lib'));% Load external functions (dependencies)addpath(genpath('classes'));% Load object-oriented architecture% Define particle from Point Cloudp1=Particle(P,[],[],[],options); % P (Nv x 3): List of Vertices; options (struct): options for shape characterisation and/or simplification% Define particle from Surface/Tetrahedral Mesh and Texture profilep2=Particle(P,F,[],Texture,options); % P (Nv x 3): List of Vertices; F (Nf x 3) or (Nf x 4): List of Faces/Elements; Texture (Nx x Ny): Planar roughness profile% Define particle from voxelated (volumetric) imagep3=Particle([],[],Vox,[],options); % Vox.img (Nx x Ny x Nz): Segmented voxelated (3-D) image of particle geometry;New users are advised to start from running the available examples, to get familiarised with the syntax and functionalities of SHAPE.CreditsSHAPE uses several external functions available within the Matlab FEX community. We want to acknowledge the work of the following contributions, for making our lives easier:Qianqian Fang - Iso2MeshLuigi Giaccari - Surface Reconstruction From Scattered Points CloudJohaness Korsawe - Minimal Bounding BoxPau Micó - stlToolsYury Petrov - Ellipsoid fitAnton Semechko - Exact minimum bounding spheres and circlesThese external dependencies are added within the source code of SHAPE, to provide an out-of-the-box implementation. The licensing terms of each external dependency can be found inside the lib folder.BYOS (Bring Your Own Scripts)!If you enjoy using SHAPE and you are interested in shape characterisation, you are welcome to ask for the implementation of new morphological descriptors and features or even better contribute and share your implementations. SHAPE was created out of our excitement and curiosity around the characterisation of irregular particle morphologies and we share this tool hoping that members of the community will find it useful. So, feel free to expand the code, propose improvements and report issues.Acknowledging SHAPEAngelidakis, V., Nadimi, S. and Utili, S., 2021. SHape Analyser for Particle Engineering (SHAPE): Seamless characterisation and simplification of particle morphology from imaging data. Computer Physics Communications, p.107983.Download BibTeX entry2020 © Vasileios Angelidakis, Sadegh Nadimi, Stefano Utili. Newcastle University, UK

This toolbox offers an Equilibrium Optimizer (EO) methodThe "Main" script illustrates the example of how EO can solve the feature selection problem using benchmark data-set.**********************************************************************************************************************************

Eigen-value calculation of continuous beamsSummaryThe eigenfrequencies and mode shapes of a simple beam are calculated based on [1]. During the calculation procedure, It is assumed that:There is no structural coupling between the different degrees of freedom of the beamThe beam is homogeneousThe beam is un-dampedthere are free oscillationsFour boundaries conditions are included:pinned-pinnedclamped-freeclamped-clampedclamped-pinnedTwo Geometries are available:rectangular beamcylinderContent:eigenModes.m: a function used to compute the eigenfrequencies and modes shapes of a continuous beam with different boundaries conditions.Example.m is an application of this function.References[1] Engineering vibration, Daniel J. Inman (3rd edition), near page 500

Check the Examples Tab ^^ for function descriptions, syntax, etc. This is an Antarctic Mapping Tools plugin for MEaSUREs Antarctic Boundaries for IPY 2007-2009 from Satellite Radar, Version 2 (Mouginot et al., 2017). All the data are contained in this File Exchange upload, so you don't need to download the data from the NSIDC, but you can read the full details here: http://nsidc.org/data/NSIDC-0709. This toolbox contains several functions for masking based ice basins, or groundedness. Also some plotting functions to show grounding line, coast line, or ice basins. If this toolbox is helpful for you, please cite the following: The dataset: Mouginot, J., E. Rignot, and B. Scheuchl. 2017. MEaSURES Antarctic Boundaries for IPY 2007-2009 from Satellite Radar, Version 1. [Indicate subset used]. Boulder, Colorado USA. NASA National Snow and Ice Data Center Distributed Active Archive Center. doi:http://dx.doi.org/10.5067/AXE4121732AD.Literature citation:Rignot, E., S. S. Jacobs, J. Mouginot, and B. Scheuchl. 2013. Ice-shelf melting around Antarctica, Science. 341. 266-270. http://dx.doi.org/10.1126/science.1235798. Antarctic Mapping Tools: Chad A. Greene, David E. Gwyther, and Donald D. Blankenship. Antarctic Mapping Tools for Matlab. Computers & Geosciences. 104 (2017) pp. 151-157 http://dx.doi.org/10.1016/j.cageo.2016.08.003

Buffeting response of a suspension bridge (frequency domain)The dynamic response of a suspension bridge to wind turbulence is computed in the frequency domain.The estimation of the displacement response of a large civil engineering structure to wind turbulence is based on the buffeting theory [1, 2, 5]. Ref. [5] contains the theoretical background I have used for the function dynaRespFD3. In the present script, the structure in question is a suspension bridge modelled using the theory of continuous beams [3]. The buffeting response is computed in the frequency domain using the quasi-steady theory. Modal coupling was assumed negligible, which is generally well verified for most of the wind velocities recorded in full scale [4]. The present script is a simplified version of the one used in [6].The present script computes the lateral, vertical and torsional displacement response. A multi-modes approach is used. Some knowledge in the field of random vibration analysis and wind loading on structures are advised for proper use of this script.The present submission contains• dynaRespFD.m : Function that calculates the displacement response spectrum of the bridge• A function VonKarmanSpectrum.m to generate the power spectral density of the velocity fluctuations based on von Karman model.• Two example files Example_1.m and Example_2.m• Two .mat files bridgeModalProperties.mat and DynamicDispl.mat that are used in the 2 examples.Any question, comment or suggestion to improve the submission is welcomed.References[1] Davenport, A.G., The response of slender line-like structures to a gusty wind, Proceedings of the Institution of Civil Engineers, Vol. 23, 1962, pp. 389 – 408.[2] Scanlan, R. H. (1978). The action of flexible bridges under wind, II: Buffeting theory. Journal of Sound and vibration, 60(2), 201-211.[3] http://www.mathworks.com/matlabcentral/fileexchange/51815-suspension-bridge--eigen-frequency-and-mode-shapes-benchmark-solutions[4] Thorbek, L. T., & Hansen, S. O. (1998). Coupled buffeting response of suspension bridges. Journal of Wind Engineering and Industrial Aerodynamics, 74, 839-847.[5] Hjorth-Hansen, E. (1993). Fluctuating drag, lift and overturning moment for a line-like structure predicted (primarily) from static, mean loads. Wind Engineering, Lecture note no, 2.[6] Cheynet, E., Jakobsen, J. B., & Snæbjörnsson, J. (2016). Buffeting response of a suspension bridge in complex terrain. Engineering Structures, 128, 474-487. http://dx.doi.org/10.1016/j.engstruct.2016.09.060

This toolbox offers Binary Differential Evolution (BDE) method The < Main.m file > illustrates the example of how BDE can solve the feature selection problem using benchmark data-set.*********************************************************************************************************************************

This App solves the optimal axisymmetric slip profile of microswimmers with user-defined shape. Such a slip profile minimizes the power loss of the active microswimmer swimming at unit speed. The algorithm is documented in the paper "Optimal slip velocities of micro-swimmers with arbitrary axisymmetric shapes" (https://doi.org/10.1017/jfm.2020.969).

Fast Iterative Filtering for the decompostion of non-stationary signals [1,2,3].Please refer to "Example_v8.m" and "Example_real_life_v6.m" for examples of how to use the code.It is based on FFT, which makes FIF to be really fast [2,3]. This implies that it is required a periodical extension at the boundaries.To overcome this limitation we can preextend the signal under investigation [4]. We do it thanks to the function "Extend_sig_v2.m". See "Example_real_life_v6.m" for an example of application.Please cite our works:[1] A. Cicone, J. Liu, H. Zhou. "Adaptive Local Iterative Filtering for Signal Decomposition and Instantaneous Frequency analysis". Applied and Computational Harmonic Analysis, Volume 41, Issue 2, September 2016, Pages 384-411. doi:10.1016/j.acha.2016.03.001 Arxiv http://arxiv.org/abs/1411.6051[2] A. Cicone, H. Zhou. "Numerical Analysis for Iterative Filtering with New Efficient Implementations Based on FFT". Numerische Mathematik, 2020. doi: 10.1007/s00211-020-01165-5 ArXiv http://arxiv.org/abs/1802.01359[3] A. Cicone. "Iterative Filtering as a direct method for the decomposition of nonstationary signals". Numerical Algorithms, Volume 373, 2020, 112248. doi: 10.1007/s11075-019-00838-z ArXiv http://arxiv.org/abs/1811.03536[4] A. Stallone, A. Cicone, M. Materassi. "New insights and best practices for the successful use of Empirical Mode Decomposition, Iterative Filtering and derived algorithms". Scientific Reports, Volume 10, article number 15161, 2020. doi: 10.1038/s41598-020-72193-2

MATLAB code to plot the Moody chart, showing the relationship between the friction factor and the Reynolds number, for different roughness coefficients in a pipe.

A simple yaml parser for OpenCV datatypes to Matlab using the new Matlab C++ Data API. The mexfile readcvYaml can be used to transfer data efficiently from OpenCV to Matlab through YAML files. The parser is able to infer the correct datatype at runtime and return it in a corresponding Matlab structure. It uses the OpenCV filestorage class. Additionally, the parser is able to fold indexed variables with same basename into a multidimensional structure.Usage: https://youtu.be/jHjLLROfxhgUPDATE V2.0! : Windows support and multichannel matrix support is addedIn the latest update (v2.0) windows mex function and compile instructions are added. Additionally the parces is greatly improved, now allowing nested mixed structures (map,vector) and multichannel matrices and raw image data. Installation1: go to mex foldercd mex/2: invoke mex command with optimization flags:It's not necessary but good to have level 3 optimisation. by default optimisation level 2 is used. Make sure to link with the correct open cv library and include paths:mex -v COPTIMFLAGS="-O3 -fwrapv -DNDEBUG" ../src/readcvYaml.cpp -I [path_to_includes] -L [path_to_lib]e.g.:mex -v COPTIMFLAGS="-O3 -fwrapv -DNDEBUG" ../src/readcvYaml.cpp -I/usr/local/include/opencv4 -L/usr/local/lib/ -lopencv_coreIf mex was successful a verbose message will be printed in the console.3: add mex path to matlab path variable:You do this the easiest by navigating to mex folder and calling:addpath(pwd); savepath;From now the readcvYaml mex function should be accessible from any path in you matlab environment4 : ReferencesPlease use the following DOI to cite cvyamlParser: DOI5: LicencePlease refer to the licence file for information about code distribution, usage and copy rights. The code is provided under BSD 3-Clause License. Licence info regarding OpenCV and Matlab: https://opencv.org/license/ https://in.mathworks.com/pricing-licensing.htmlUsage:call readcvYaml on the dataset of choice. The function takes as input the filename and the sort option. By default readcvYaml will parse the variables names listed in the yaml file and assign this to a structure with corresponding fields. E.g.:s = readcvYaml('../data/test_data.yaml')s = struct with fields: matA0: [1000×3 double] matA1: [1000×3 double] matA2: [1000×3 double]In readcvYaml a handy option is implemented to sort the data based on basename and numeric identifier. When using the sorting option entries that have a unique basename will be folded into multidimentional struct. This is very handy when you have similar datasets that belong to the same category or experimental condition etc. This is done like so:s = readcvYaml('../data/test_data.yaml','sorted')s = struct with fields: matA: [1×3 struct]The sorting then stores the matrices with matA basename in 2d strructure that can be accessed with:s.matA(1).matAThe numerical identifier does not have to be continuous, the sorting wil sort and store in ascending order. I.e.: A1, A2, A7, A12 and so forth. s.matA(1).index stores the numerical identifier.The parser will automatically identify the datatype of the stored variable and return this in the structure. It is able to handle all common types used in OpenCV and Matlab environments. Common datatypes are that are returned from OpenCv to matlab:OpenCV --> Matlab --sizeof CV_8U ,CV_8US -->int8_t(char)--1CV_16S,CV_16U-->short--2CV_32S-->int--4CV_32F-->float--4CV_64F-->double--8The parser can convert vectors, matrices and single variables stored in yaml file. Although untested it should also work with xml files. Refer to the test_data.yaml and genyamlData.cpp see an example of how the data is generated.BenchmarkingA benchmark results are provided for linux and osx platforms in folders linux and osx. The benchmark test were perfomed on standard Dell Optiplex 7400 and 2,3 GHz Intel Core i5 16G macbook, respectively.To run the benchmark follow the steps:1: generate test data to test the function:Go to src folder and compile genyamlData:cd src/g++ -std=c++11 genyamlData.cpp -o genyamlData -I [path_to_cv_includes] [opencv_core_lib]e.g.:g++ -std=c++11 genyamlData.cpp -o genyamlData -I /usr/local/include/opencv4 -lopencv_coreThen run with:genyamlData [outout_path_of_yaml] e.g.:genyamlData ../data/test_data.yaml2: Run benchmark on you own pc:In folder benchmark a simple script is provided to run readcvYaml on your own data. Simply choose the number of iterations with N parameter and run benchmarktest_cvYaml.m. The benchmark was performed for 5x[1000x3] double, 5x[2000x3] float, 5x[2000x3] int, and 5x[3000] double, 5x[6000] float and 5x[6000] int vectors. See test_data.yaml for the actual dataset.Result of the benchmark test on linux Optiplex system can be found in figures. The sorting is slightly more expensive as expected but negligible for the current dataset.

The least-squares wavelet analysis (LSWA) is a robust method of analyzing any type of time/data series without the need for editing and preprocessing of the original series. The LSWA can rigorously analyze any non-stationary and equally/unequally spaced series with an associated covariance matrix that may have trends and/or datum shifts. The least-squares cross-wavelet analysis complements the LSWA in the study of the coherency and phase differences of two series of any type. A MATLAB software package including a graphical user interface is developed for these methods to aid researchers in analyzing pairs of series. The package also includes the least-squares spectral analysis, the antileakage least-squares spectral analysis, and the least-squares cross-spectral analysis to further help researchers study the components of interest in a series. We demonstrate the steps that users need to take for a successful analysis using three examples: two synthetic time series, and a Global Positioning System time series.

This repository was created for anybody interested in using feature selection (ReliefF, Matlab: relieff) and support vector machines (SVM, Matlab: fitcsvm) as a minimum working example to reproduce steps described in the publication below (Doerr2020). Data is provided in the sub-folder '_Data'. Structural features were extracted from micro-X-ray tomography data. ReliefF and SVM were used to build a classifier for the detection of broken pharmaceutical pellets within the sample.Input Data:(1) Extracted features of six ibuprofen (IBU) capsules (1763 pellets, 206 features): 'Desc_DataFile_C0.csv' 'Desc_DataFile_C1.csv' 'Desc_DataFile_C2.csv' 'Desc_DataFile_C3.csv' 'Desc_DataFile_C4.csv' 'Desc_DataFile_C5.csv'(2) User defined feature categories: 'Feature_Categories.csv'(3) Results of a feature sensitivity analysis: 'Feature_SenAnlys_Score.csv'%------------------------------------------------------------------------------------------------% Code written by Frederik Doerr, Feb 2020 (MATLAB R2019b)% Application: For 'Support Vector Machine - Introduction and Application'% % % Reference (open access):% Doerr, F. J. S., Florence, A. J. (2020)% A micro-XRT image analysis and machine learning methodology for the characterisation of multi-particulate capsule formulations. % International Journal of Pharmaceutics: X. % https://doi.org/10.1016/j.ijpx.2020.100041% Data repository: https://doi.org/10.15129/e5d22969-77d4-46a8-83b8-818b50d8ff45% Video Abstract: https://strathprints.strath.ac.uk/id/eprint/71463%------------------------------------------------------------------------------------------------

DGTtool for computing STFT/DGTA simple and user-friendly MATLAB tool for computing the short-time Fourier transform (STFT) and the discrete Gabor transform (DGT). It is designed to be easy and fast for practical use.The following features of DGTtool might be different from the other tools:Parameters are stored inside DGTtool object for user-friendliness.All pre-computation runs only once so that repeated computation of DGT/STFT is fast.Many computations run in parallel for all channels (for multi-channel signal).Perfect reconstruction is very easily realized.Number of frequency bins can be smaller than the window length.Dual and tight windows can be computed easily.Sparse time-frequency representation (reassigned spectrogram) is implemented.Phase visualization tool (plotPhase) is implemented.STFT/DGT can be written in an operator form.How to UseDownload DGTtool.m and place it in the Current Folder.1. Create DGTtool objectCreate a DGTtool object F by specifying its parameters.F = DGTtool('windowShift',500,'windowLength',1500,'FFTnum',2000,'windowName','Blackman')(Note: This step can be done without parameters: F = DGTtool. Unspecified parameters are set to default values.)2. Compute spectrogramCompute a spectrogram X from a signal x.X = F(x);3. Convert spectrogram back to signalCompute the signal x from its spectrogram X.x = F.pinv(X);4. Visualize spectrogramThree visualization functions are implemented. A spectrogram is computed and plotted from a time-domain signal x (and sampling frequency fs, optional).F.plot(x,fs)F.plotPhase(x,fs)F.plotReassign(x,fs)DocumentationTo check all functions in DGTtool, please read and run demo.m.help DGTtoolanddoc DGTtoolprovide detailed usage.