--- title: "4. Visualization Tools" author: - Hannah L. Owens - Carsten Rahbek date: "`r Sys.Date()`" output: rmarkdown::html_vignette: fig_caption: yes fig_width: 7 fig_height: 7 toc: true toc_depth: 3 vignette: > %\VignetteIndexEntry{4. Visualization Tools} \usepackage[utf8]{inputenc} %\VignetteEncoding{UTF-8} %\VignetteEngine{knitr::rmarkdown} editor_options: chunk_output_type: console --- ```{r setup, include=FALSE} knitr::opts_chunk$set(echo = TRUE, error = FALSE, fig.retina = 1, dpi = 80) ``` # Introduction `voluModel` contains several functions to generate formatted maps of rasters and points automatically. This was to aid us in cleanly visualizing large numbers of maps efficiently using `ggplot2` (Wickam, 2016) and `lattice` (Sarkar, 2008) functionality. While there are quite a few features available in these functions, they were designed with fairly specific use cases in mind. You are welcome to gut the functions and rewrite them for your own custom needs. The data I will be using for the demos in this tutorial will be loaded and analyzed first. The Luminous Hake occurrence points, which you can see in the [data sampling tutorial](https://hannahlowens.github.io/voluModel/articles/c_DataSampling.html), were downloaded via R (R Core Team, 2020) from GBIF (Chamberlain *et al.*, 2021; Chamberlain and Boettiger, 2017) and OBIS (Provoost and Bosch, 2019) via `occCite` (Owens *et al.*, 2021). The simple envelope model is based on two environmental datasets from the World Ocean Atlas (Garcia *et al.*, 2019): temperature (Locarnini *et al.*, 2018) and apparent oxygen utilization (AOU; Garcia *et al.*, 2019). For more details on how to process environmental data, see [the raster data tutorial](https://hannahlowens.github.io/voluModel/articles/b_RasterProcessing.html). For the workflow used to generate the niche envelopes, refer to [the introduction vignette](https://hannahlowens.github.io/voluModel/articles/a_Introduction.html). ```{r generating data for plotting} library(voluModel) # Because of course library(ggplot2) # For fancy plotting library(viridisLite) # For high-contrast plotting palettes library(dplyr) # To filter data library(terra) # Now being transitioned in library(sf) # Now being transitioned in # Load data oxygenSmooth <- rast(system.file("extdata/oxygenSmooth.tif", package='voluModel')) occs <- read.csv(system.file("extdata/Steindachneria_argentea.csv", package='voluModel')) # Temperature td <- tempdir() unzip(system.file("extdata/woa18_decav_t00mn01_cropped.zip", package = "voluModel"), exdir = paste0(td, "/temperature"), junkpaths = T) temperature <- vect(paste0(td, "/temperature/woa18_decav_t00mn01_cropped.shp")) # Creating a SpatRaster vector template <- centerPointRasterTemplate(temperature) tempTerVal <- rasterize(x = temperature, y = template, field = names(temperature)) # Get names of depths envtNames <- gsub("[d,M]", "", names(temperature)) envtNames[[1]] <- "0" names(tempTerVal) <- envtNames temperature <- tempTerVal # Oxygen processing names(oxygenSmooth) <- names(temperature) # Clean points ---- occurrences <- occs %>% dplyr::select(decimalLongitude, decimalLatitude, depth) %>% distinct() %>% filter(dplyr::between(depth, 1, 2000)) # Gets the layer index for each occurrence by matching to depth layerNames <- as.numeric(names(temperature)) occurrences$index <- unlist(lapply(occurrences$depth, FUN = function(x) which.min(abs(layerNames - x)))) indices <- unique(occurrences$index) downsampledOccs <- data.frame() for(i in indices){ tempPoints <- occurrences[occurrences$index==i,] tempPoints <- downsample(tempPoints, temperature[[1]], verbose = FALSE) tempPoints$depth <- rep(layerNames[[i]], times = nrow(tempPoints)) downsampledOccs <- rbind(downsampledOccs, tempPoints) } occsWdata <- downsampledOccs[,c("decimalLatitude", "decimalLongitude", "depth")] # Extract data ---- occsWdata$temperature <- xyzSample(occs = occsWdata, temperature) occsWdata$AOU <- xyzSample(occs = occsWdata, oxygenSmooth) occsWdata <- occsWdata[complete.cases(occsWdata),] # Land shapefile land <- rnaturalearth::ne_countries(scale = "small", returnclass = "sf")[1] # Study region studyRegion <- marineBackground(occsWdata, buff = 1000000) # Get limits tempLims <- quantile(occsWdata$temperature,c(0, 1)) aouLims <- quantile(occsWdata$AOU,c(0, 1)) # Reclassify environmental bricks to presence/absence temperaturePresence <- classify(temperature, rcl = matrix(c(-Inf,tempLims[[1]],0, tempLims[[1]], tempLims[[2]], 1, tempLims[[2]], Inf, 0), ncol = 3, byrow = TRUE)) AOUpresence <- classify(oxygenSmooth, rcl = matrix(c(-Inf, aouLims[[1]],0, aouLims[[1]], aouLims[[2]], 1, aouLims[[2]], Inf, 0), ncol = 3, byrow = TRUE)) # Put it all together envelopeModel3D <- temperaturePresence * AOUpresence envelopeModel3D <- mask(crop(envelopeModel3D, studyRegion), mask = studyRegion) names(envelopeModel3D) <- names(temperature) rm(AOUpresence, downsampledOccs, occurrences, temperaturePresence, tempPoints, aouLims, envtNames, i, indices, layerNames, tempLims) ``` # Plotting points There are two functions in `voluModel` for plotting occurrence points. The first, `pointMap()`, plots a single set of horizontal geographic points. The title generated is the species name the user supplies and a count of the number of points that have been plotted. ```{r pointMap, warning=FALSE, message=FALSE, eval=TRUE} pointMap(occs = occs, land = land, landCol = "black", spName = "Steindachneria argentea", ptSize = 2, ptCol = "orange") ``` The second, `pointCompMap()` plots a map that maps the extents of two sets of horizontal geographic points in different colors. This might be useful, for example, if you want to compare a raw dataset to a cleaned dataset. If any points overlap, they can be plotted as a third color. ```{r pointCompMap, warning=FALSE, message=FALSE} pointCompMap(occs1 = occs, occs1Col = "red", occs1Name = "Raw", occs2 = occsWdata, occs2Col = "orange", occs2Name = "Clean", spName = "Steindachneria argentea", agreeCol = "purple", land = land, landCol = "black", ptSize = 2, verbose = FALSE) ``` # Plotting rasters If you have a horizontal raster you would like to map that contains continuous data, the function for you might be `oneRasterPlot()`. It is a wrapper around `spplot()` from `sp` (Pebesma and Bivand, 2005; Bivand *et al.* 2013) that implements the high-contrast, colorblind-friendly color palettes offered in `viridis()` from `viridisLite` (Garnier *et al.*, 2021). The function optionally takes arguments to the `spplot()` and `viridis()` functions (so, for example, you can choose a palette other than the default). ```{r oneRasterPlot} oneRasterPlot(rast = temperature[[1]], land = land, title = "Sea Surface Temperature, WOA 2018", landCol = "black", n = 11, option = "mako", varName = "Temperature") ``` Suppose you want to compare the extents of two presence-absence rasters--perhaps you are comparing two species distribution model method outputs, or comparing potential distributions at two different depths. We have a function for that, too. ```{r rasterComp} rasterComp(rast1 = envelopeModel3D[[1]], rast1Name = "Surface", rast2 = envelopeModel3D[[10]], rast2Name = "45m", land = land, landCol = "black", title = "Suitability of Habitat for Luminous Hake\nAt Two Different Depths") ``` Of course, 3D models such as the ones `voluModel` is designed to help you produce, are difficult to visualize. We have given it a try, though. `plotLayers()` plots a transparent layer of suitable habitat for each depth layer. The redder the color, the shallower the layer, the bluer, the deeper. The more saturated the color, the more layers with suitable habitat. Here, I am plotting suitability from 20 to 700 m, the depth range of occurrences used to train the envelope model. ```{r plotLayers} layerNames <- as.numeric(names(envelopeModel3D)) occsWdata$index <- unlist(lapply(occsWdata$depth, FUN = function(x) which.min(abs(layerNames - x)))) indices <- unique(occsWdata$index) layerPlot <- plotLayers(envelopeModel3D[[min(indices):max(indices)]], title = "Envelope Model of Luminous Hake,\n 20 to 700m", land = land, landCol = "black") ``` # Tidying up Last, we need to close the temporary directory we opened when we opened the data. ```{r cleanup temporary directory} unlink(td, recursive = T) ``` # References Bakis Y (2021): TU_Fish. v1.1. No organization. Dataset/Occurrence. https://web.archive.org/web/20221202141213/https://bgnn.tulane.edu/ipt/resource?r=tu_fish&v=1.1 Accessed via OBIS on 2020-11-04. Bentley A (2022). KUBI Ichthyology Collection. Version 17.80. University of Kansas Biodiversity Institute. DOI: 10.15468/mgjasg. Accessed via GBIF on 2020-10-13. Bentley A (2022). KUBI Ichthyology Tissue Collection. Version 18.68. University of Kansas Biodiversity Institute. DOI: 10.15468/jmsnwg. Accessed via GBIF on 2020-10-13. Buckup P A (2022). Coleção Ictiológica (MNRJ), Museu Nacional (MN), Universidade Federal do Rio de Janeiro(UFRJ). Version 157.1487. Museu Nacional / UFRJ. DOI: 10.15468/lluzfl. Accessed via GBIF on 2020-10-13. Catania D, Fong J (2022). CAS Ichthyology (ICH). Version 150.300. California Academy of Sciences. DOI: 10.15468/efh2ib. Accessed via GBIF on 2020-10-13. Chakrabarty P (2019). LSUMZ (LSU MNS) Fishes Collection. Version 2.2. Louisiana State University Museum of Natural Science. DOI: 10.15468/gbnym3. Accessed via GBIF on 2020-10-13. Chamberlain S, Barve V, Mcglinn D, Oldoni D, Desmet P, Geffert L, Ram K (2021). rgbif: Interface to the Global Biodiversity Information Facility API. R package version 3.6.0, https://CRAN.R-project.org/package=rgbif. Chamberlain S, Boettiger C (2017). “R Python, and Ruby clients for GBIF species occurrence data.” PeerJ PrePrints. DOI: 10.7287/peerj.preprints.3304v1. Davis Rabosky AR, Cox CL, Rabosky DL, Title PO, Holmes IA, Feldman A, McGuire JA (2016). Coral snakes predict the evolution of mimicry across New World snakes. Nature Communications 7:11484. Espinosa Pérez H, Comisión nacional para el conocimiento y uso de la biodiversidad C (2021). Computarización de la Colección Nacional de Peces del Instituto de Biología UNAM. Version 1.9. Comisión nacional para el conocimiento y uso de la biodiversidad. DOI: 10.15468/zb2odl. Accessed via GBIF on 2020-10-13. Frable B (2019). SIO Marine Vertebrate Collection. Version 1.7. Scripps Institution of Oceanography. DOI: 10.15468/ad1ovc. Accessed via GBIF on 2020-10-13. Fishnet2 Portal, http://www.fishnet2.net, [Access date] Accessed via OBIS on 2020-11-04. Froese, R. and D. Pauly. Editors. 200x. FishBase. World Wide Web electronic publication. www.fishbase.org, version (xx/200x). Accessed via OBIS on 2020-11-04. Gall L (2021). Vertebrate Zoology Division - Ichthyology, Yale Peabody Museum. Yale University Peabody Museum. DOI: 10.15468/mgyhok. Accessed via GBIF on 2020-10-13. García, CB, and Duarte, LO, 'Columbian Caribbean Sea', in J.H. Nicholls (comp.) HMAP Data Pages https://oceanspast.org/hmap_db.php Accessed via OBIS on 2020-11-04. Garcia HE, Weathers K, Paver CR, Smolyar I, Boyer TP, Locarnini RA, Zweng MM, Mishonov AV, Baranova OK, Seidov D, Reagan JR (2018). World Ocean Atlas 2018, Volume 3: Dissolved Oxygen, Apparent Oxygen Utilization, and Oxygen Saturation. A Mishonov Technical Ed.; NOAA Atlas NESDIS 83, 38pp. Garnier S, Ross N, Rudis R, Camargo AP, Sciaini M, Scherer C (2021). Rvision - Colorblind-Friendly Color Maps for R. R package version 0.6.2. GBIF.org (24 September 2020) GBIF Occurrence Download DOI: 10.15468/dl.efuutj. Grant S, McMahan C (2020). Field Museum of Natural History (Zoology) Fish Collection. Version 13.12. Field Museum. DOI: 10.15468/alz7wu. Accessed via GBIF on 2020-10-13. Harvard University M, Morris P J (2022). Museum of Comparative Zoology, Harvard University. Version 162.296. Museum of Comparative Zoology, Harvard University. DOI: 10.15468/p5rupv. Accessed via GBIF on 2020-10-13. Hendrickson D A, Cohen A E, Casarez M J (2022). University of Texas, Biodiversity Center, Ichthyology Collection (TNHCi). Version 5.175. University of Texas at Austin, Biodiversity Collections. DOI: 10.15468/h8gxdr. Accessed via GBIF on 2020-10-13. INVEMAR. SIBM en línea: Sistema de Información sobre Biodiversidad Marina. Santa Marta: Instituto de investigaciones Marinas y Costeras José Benito Vives de Andréis,. https://siam.invemar.org.co/ Accessed via OBIS on 2020-11-04. Locarnini RA, Mishonov AV, Baranova OK, Boyer TP, Zweng MM, Garcia HE, Reagan JR, Seidov D, Weathers K, Paver CR, Smolyar I (2018). World Ocean Atlas 2018, Volume 1: Temperature. A. Mishonov Technical Ed.; NOAA Atlas NESDIS 81, 52pp. McLean, M.W. (2014). Straightforward Bibliography Management in R Using the RefManager Package. NA, NA. https://arxiv.org/abs/1403.2036. McLean, M.W. (2017). RefManageR: Import and Manage BibTeX and BibLaTeX References in R. The Journal of Open Source Software. Mertz W (2021). LACM Vertebrate Collection. Version 18.9. Natural History Museum of Los Angeles County. DOI: 10.15468/77rmwd. Accessed via GBIF on 2020-10-13. Nakae M, Shinohara G (2018). Fish collection of National Museum of Nature and Science. National Museum of Nature and Science, Japan. Occurrence dataset DOI: 10.15468/w3dzv1 accessed via GBIF.org on yyyy-mm-dd. Accessed via OBIS on 2020-11-04. Natural History Museum (2021). Natural History Museum (London) Collection Specimens. DOI: 10.5519/0002965. Accessed via GBIF on 2020-10-13. National Museum of Natural History, Smithsonian Institution NMNH Fishes Collection Database. National Museum of Natural History, Smithsonian Institution, 10th and Constitution Ave. N.W., Washington, DC 20560-0193, 2007. Accessed via OBIS on 2020-11-04. Norén M, Shah M (2017). Fishbase. FishBase. DOI: 10.15468/wk3zk7. Accessed via GBIF on 2020-10-13. Norton B, Hogue G (2021). NCSM Ichthyology Collection. Version 22.8. North Carolina State Museum of Natural Sciences. DOI: 10.36102/dwc.1. Accessed via GBIF on 2020-10-13. Nychka D, Furrer R, Paige J, Sain S (2021). “fields: Tools for spatial data.” R package version 13.3, . Orrell T, Informatics Office (2021). NMNH Extant Specimen Records (USNM, US). Version 1.49. National Museum of Natural History, Smithsonian Institution. DOI: 10.15468/hnhrg3. Accessed via GBIF on 2020-10-13. Owens H, Merow C, Maitner B, Kass J, Barve V, Guralnick R (2021). occCite: Querying and Managing Large Biodiversity Occurrence Datasets_. doi: 10.5281/zenodo.4726676 (URL: DOI: 10.5281/zenodo.4726676), R package version 0.4.9.9000, (). Pebesma, E.J., R.S. Bivand (2005). Classes and methods for spatial data in R. R News 5 (2), https://cran.r-project.org/doc/Rnews/. Prestridge H (2021). Biodiversity Research and Teaching Collections - TCWC Vertebrates. Version 9.4. Texas A&M University Biodiversity Research and Teaching Collections. DOI: 10.15468/szomia. Accessed via GBIF on 2020-10-13. Provoost P, Bosch S (2019). “robis: R Client to access data from the OBIS API.” Ocean Biogeographic Information System. Intergovernmental Oceanographic Commission of UNESCO. R package version 2.1.8, https://cran.r-project.org/package=robis. Pugh W (2021). UAIC Ichthyological Collection. Version 3.3. University of Alabama Biodiversity and Systematics. DOI: 10.15468/a2laag. Accessed via GBIF on 2020-10-13. R Core Team (2017). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/. Robins R (2021). UF FLMNH Ichthyology. Version 117.342. Florida Museum of Natural History. DOI: 10.15468/8mjsel. Accessed via GBIF on 2020-10-13. Bivand RS, Pebesma E, Gomez-Rubio V (2013). Applied spatial data analysis with R, Second edition. Springer, NY. https://asdar-book.org/ Sarkar D (2008). Lattice: Multivariate Data Visualization with R. Springer, New York. ISBN 978-0-387-75968-5 Tavera L, Tavera M. L (2021). Biodiversidad de los recursos marinos y costeros entre Cartagena y el Golfo de Urabá, Caribe colombiano. Version 2.4. Instituto de Investigaciones Marinas y Costeras - Invemar. DOI: 10.15472/d2jusp. Accessed via GBIF on 2020-10-13. UNIBIO, IBUNAM. CNPE/Coleccion Nacional de Peces. DOI: 10.15468/o5d48z. Accessed via GBIF on 2020-10-13. Wagner M (2017). MMNS Ichthyology Collection. Mississippi Museum of Natural Science. DOI: 10.15468/4c3qeq. Accessed via GBIF on 2020-10-13. Werneke D (2019). AUM Fish Collection. Version 8.1. Auburn University Museum. DOI: 10.15468/dm3oyz. Accessed via GBIF on 2020-10-13. Wickham H (2016). ggplot2: Elegant Graphics for Data Analysis. Springer-Verlag New York.