Are you working with complex scientific multidimensional datasets? Would you like to explore and learn how to use powerful tools and capabilities to help solve your problems? Many workflows can help with your analytical needs, but you may be wondering where to start. In this post, we will walk you through how to incorporate a multidimensional scientific data workflow (ingest, visualize, analyze, and share) within ArcGIS and which of Esri\u2019s latest multidimensional geoprocessing tools you can use.\u00a0 You will also learn a simple way to build and share your analytical science products using NetCDF, HDF, and GRIB (curated by NOAA and NASA).<\/p>\n
One effect of climate change is changes in precipitation patterns. As sea surface temperatures increase, these patterns change and areas around the globe experience either an increase or decrease in their annual precipitation<\/a>. Current studies indicate that the Sahara Desert is expanding<\/a> due to decreased precipitation over the region. At the same time, South America is experiencing a slight increase in precipitation in past and severe storms<\/a> . Much of the world\u2019s freshwater supply is replenished through precipitation, so it is vital that we understand the changes already occurring. In this brief investigation, we will use multidimensional NOAA data<\/a> showing monthly global precipitation from 1900 to 2017 to analyze and predict precipitation trends around the globe. We will also take a closer look at the Sahara desert and Amazon rainforest regions. If you wish to follow along, you can download the data here<\/a>. We will use the ArcPy<\/a> to ingest the data and analyze it in ArcGIS Notebooks<\/a> and ArcGIS Pro<\/a>.<\/p>\n The first step is to ingest the data so you can visualize it in ArcGIS Pro. We will do this using the ArcPy GP tools<\/a>. The ArcGIS Notebook code shown here creates a raster object from a multidimensional raster dataset and applies the stretch function for better visualization.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870441,"id":870441,"title":"Ingest multid data","filename":"code_1-1.png","filesize":12565,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_1-2","alt":"Load netcdf as multidim raster","author":"10492","description":"","caption":"","name":"code_1-2","status":"inherit","uploaded_to":869051,"date":"2020-05-27 19:54:10","modified":"2020-05-27 19:54:43","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1296,"height":191,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1-213x191.png","thumbnail-width":213,"thumbnail-height":191,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","medium-width":464,"medium-height":68,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","medium_large-width":768,"medium_large-height":113,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","large-width":1296,"large-height":191,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","1536x1536-width":1296,"1536x1536-height":191,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","2048x2048-width":1296,"2048x2048-height":191,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1-826x122.png","card_image-width":826,"card_image-height":122,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png","wide_image-width":1296,"wide_image-height":191}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_1-1.png"},{"acf_fc_layout":"content","content":" The multidimensional information is then added to the raster object and it can be saved as an optimized Cloud Raster Format<\/a> (CRF).<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870601,"id":870601,"title":"save","filename":"code_2-2.png","filesize":6546,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_2-3","alt":"save raster","author":"10492","description":"","caption":"","name":"code_2-3","status":"inherit","uploaded_to":869051,"date":"2020-05-27 20:36:07","modified":"2020-05-27 20:36:25","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1234,"height":96,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2-213x96.png","thumbnail-width":213,"thumbnail-height":96,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","medium-width":464,"medium-height":36,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","medium_large-width":768,"medium_large-height":60,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","large-width":1234,"large-height":96,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","1536x1536-width":1234,"1536x1536-height":96,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","2048x2048-width":1234,"2048x2048-height":96,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2-826x64.png","card_image-width":826,"card_image-height":64,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png","wide_image-width":1234,"wide_image-height":96}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_2-2.png"},{"acf_fc_layout":"content","content":" Once you ingest the data, now you can explore the data structure and its variables as shown below.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870621,"id":870621,"title":"variables exploration","filename":"code_3a.png","filesize":32041,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_3a","alt":"variables exploration","author":"10492","description":"","caption":"","name":"code_3a","status":"inherit","uploaded_to":869051,"date":"2020-05-27 20:37:27","modified":"2020-05-27 20:37:50","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1272,"height":640,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","medium-width":464,"medium-height":233,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","medium_large-width":768,"medium_large-height":386,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","large-width":1272,"large-height":640,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","1536x1536-width":1272,"1536x1536-height":640,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","2048x2048-width":1272,"2048x2048-height":640,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a-826x416.png","card_image-width":826,"card_image-height":416,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png","wide_image-width":1272,"wide_image-height":640}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_3a.png"},{"acf_fc_layout":"content","content":" Working with ArcGIS Notebooks allows you to access external python libraries to extend your analysis, but it also allows you to visualize and manipulate your data using ArcGIS Pro. Data may be displayed in the ArcGIS Notebooks window, but it can also be added to a map in your ArcGIS Pro project where you can work with it as you would in any other project.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":871201,"id":871201,"title":"Notebook pro","filename":"Figure_X-2.jpg","filesize":99524,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_x-2","alt":"Notebook pro","author":"10492","description":"","caption":"","name":"figure_x-2","status":"inherit","uploaded_to":869051,"date":"2020-05-27 23:14:14","modified":"2020-05-27 23:14:38","menu_order":0,"mime_type":"image\/jpeg","type":"image","subtype":"jpeg","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1671,"height":524,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2-213x200.jpg","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","medium-width":464,"medium-height":146,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","medium_large-width":768,"medium_large-height":241,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","large-width":1671,"large-height":524,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2-1536x482.jpg","1536x1536-width":1536,"1536x1536-height":482,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","2048x2048-width":1671,"2048x2048-height":524,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2-826x259.jpg","card_image-width":826,"card_image-height":259,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg","wide_image-width":1671,"wide_image-height":524}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_X-2.jpg"},{"acf_fc_layout":"content","content":" Once the precipitation data has been loaded into the new multidimensional raster, you can begin to explore the data and look for trends. This data includes monthly precipitation totals from 1900 to 2017. This means there are 1,404 slices of precipitation data represented here (117 years of monthly data), which gives you enough data points for your trend analysis. To begin, you will need to aggregate your monthly precipitation data into yearly precipitation.<\/p>\n The Aggregate Multidimensional Raster<\/a> tool will aggregate your existing raster precipitation data by time.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870651,"id":870651,"title":"aggregate multiD data","filename":"code_4.png","filesize":55076,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_4","alt":"aggregate multiD data","author":"10492","description":"","caption":"","name":"code_4","status":"inherit","uploaded_to":869051,"date":"2020-05-27 20:46:20","modified":"2020-05-27 20:46:43","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1304,"height":234,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","medium-width":464,"medium-height":83,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","medium_large-width":768,"medium_large-height":138,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","large-width":1304,"large-height":234,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","1536x1536-width":1304,"1536x1536-height":234,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","2048x2048-width":1304,"2048x2048-height":234,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4-826x148.png","card_image-width":826,"card_image-height":148,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png","wide_image-width":1304,"wide_image-height":234}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_4.png"},{"acf_fc_layout":"content","content":" Now that the data has been aggregated to mean annual precipitation, let\u2019s take a look at the Sahara desert and Amazon rainforest regions using the Temporal Profile Charting tool<\/a>.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870701,"id":870701,"title":"Region of Interest used for charting precipitation change","filename":"Figure_3.jpg","filesize":128134,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_3","alt":"Temporal charting tool","author":"10492","description":"","caption":"Figure 3: Region of Interest used for charting precipitation change","name":"figure_3","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:03:44","modified":"2020-06-03 14:04:20","menu_order":0,"mime_type":"image\/jpeg","type":"image","subtype":"jpeg","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1408,"height":755,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3-213x200.jpg","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","medium-width":464,"medium-height":249,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","medium_large-width":768,"medium_large-height":412,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","large-width":1408,"large-height":755,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","1536x1536-width":1408,"1536x1536-height":755,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","2048x2048-width":1408,"2048x2048-height":755,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3-826x443.jpg","card_image-width":826,"card_image-height":443,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg","wide_image-width":1408,"wide_image-height":755}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_3.jpg"},{"acf_fc_layout":"image","image":{"ID":870711,"id":870711,"title":"Precipitation change in the Sahara desert region","filename":"Figure_4.png","filesize":20644,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_4","alt":"Precipitation change in the Sahara desert region","author":"10492","description":"","caption":"Figure 4: Precipitation change in the Sahara desert region","name":"figure_4","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:05:25","modified":"2020-05-27 21:42:30","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1188,"height":371,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","medium-width":464,"medium-height":145,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","medium_large-width":768,"medium_large-height":240,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","large-width":1188,"large-height":371,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","1536x1536-width":1188,"1536x1536-height":371,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","2048x2048-width":1188,"2048x2048-height":371,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4-826x258.png","card_image-width":826,"card_image-height":258,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png","wide_image-width":1188,"wide_image-height":371}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_4.png"},{"acf_fc_layout":"image","image":{"ID":870721,"id":870721,"title":"Precipitation changes in the Amazon rainforest region","filename":"Figure_5.png","filesize":18864,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_5","alt":"Precipitation changes in the Amazon rainforest region","author":"10492","description":"","caption":"Figure 5: Precipitation changes in the Amazon rainforest region","name":"figure_5","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:06:10","modified":"2020-05-27 21:42:56","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1140,"height":272,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","medium-width":464,"medium-height":111,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","medium_large-width":768,"medium_large-height":183,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","large-width":1140,"large-height":272,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","1536x1536-width":1140,"1536x1536-height":272,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","2048x2048-width":1140,"2048x2048-height":272,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5-826x197.png","card_image-width":826,"card_image-height":197,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png","wide_image-width":1140,"wide_image-height":272}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_5.png"},{"acf_fc_layout":"content","content":" The Temporal Profile Charting tool plots the mean annual precipitation on the vertical axis and time on the horizontal axis. It can also be used to generate trend lines, shown here in red. From these trend lines, we can see that the average annual precipitation in the Sahara desert region has decreased over time. Trends in the Amazon rainforest region are less clear, but precipitation appears to have slightly increased in this region over time.<\/p>\n Another way to look at changes in precipitation is by detecting anomalies. The term \u201canomaly\u201d means a departure from a reference value or long-term average. A positive anomaly value indicates that the observed precipitation was greater than the long-term average precipitation, while a negative anomaly indicates that the observed precipitation was less than the long-term average precipitation. To do this, we will use the Generate Multidimensional Anomaly<\/a> tool. We will use this tool to compute the anomaly for each time slice in the multidimensional precipitation raster. The anomaly data will let us see how the precipitation deviates from the average at each location over time.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870751,"id":870751,"title":"Calculate Anomaly","filename":"code_5.png","filesize":19637,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_5","alt":"Anomaly detection","author":"10492","description":"","caption":"","name":"code_5","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:11:08","modified":"2020-05-27 21:11:36","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1306,"height":395,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","medium-width":464,"medium-height":140,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","medium_large-width":768,"medium_large-height":232,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","large-width":1306,"large-height":395,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","1536x1536-width":1306,"1536x1536-height":395,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","2048x2048-width":1306,"2048x2048-height":395,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5-826x250.png","card_image-width":826,"card_image-height":250,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png","wide_image-width":1306,"wide_image-height":395}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_5.png"},{"acf_fc_layout":"content","content":" We can use the charting tool to look at the anomaly data through time. Figures 6 and 7 shows how the average annual precipitation compares to the long-term average (the average over all 117 years). Years with positive anomaly values had more precipitation than the long-term average, and years with negative anomaly values had less precipitation than the long-term average.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870771,"id":870771,"title":"Anomaly in Sahara desert region","filename":"Figure_6.png","filesize":21720,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_6","alt":"Anomaly Sahara","author":"10492","description":"","caption":"Figure 6: Precipitation anomaly in Sahara desert region","name":"figure_6","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:13:24","modified":"2020-05-27 21:14:27","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1198,"height":396,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","medium-width":464,"medium-height":153,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","medium_large-width":768,"medium_large-height":254,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","large-width":1198,"large-height":396,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","1536x1536-width":1198,"1536x1536-height":396,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","2048x2048-width":1198,"2048x2048-height":396,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6-826x273.png","card_image-width":826,"card_image-height":273,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png","wide_image-width":1198,"wide_image-height":396}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_6.png"},{"acf_fc_layout":"image","image":{"ID":870791,"id":870791,"title":"Anomaly in amazon rainforest region","filename":"Figure_7.png","filesize":21891,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_7","alt":"Anomaly in amazon rainforest region","author":"10492","description":"","caption":"Figure 7: Precipitation anomaly in Amazon rainforest region","name":"figure_7","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:15:45","modified":"2020-05-27 21:16:55","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1140,"height":316,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","medium-width":464,"medium-height":129,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","medium_large-width":768,"medium_large-height":213,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","large-width":1140,"large-height":316,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","1536x1536-width":1140,"1536x1536-height":316,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","2048x2048-width":1140,"2048x2048-height":316,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7-826x229.png","card_image-width":826,"card_image-height":229,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png","wide_image-width":1140,"wide_image-height":316}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_7.png"},{"acf_fc_layout":"content","content":" Using these graphs, we can see the overall trends in the Amazon rainforest region and the Sahara desert region. Over this time period, annual precipitation has steadily declined in the Sahara desert region to the point where it is now consistently below the long-term average. Annual precipitation trends in the Amazon rainforest region are again harder to identify, but it appears they have slowly but steadily increased. Additional data points in upcoming years will help to separate the trend from the noise in this region.<\/p>\n Another way to look at this precipitation data is to use a simple regression model to look at the trends and predict future precipitation. To begin, we will use the Generate Trend Raster<\/a> tool. This tool helps estimate the overall trend for each pixel along a dimension (time in this case). You can calculate the trends for one or more variables in a multidimensional raster. For this analysis, we will use the original monthly precipitation dataset and use a harmonic regression to account for seasonal fluctuations in precipitation. \u00a0Here is the code block.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":874531,"id":874531,"title":"generate trend raster","filename":"code_6_A.png","filesize":19087,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/code_6_a","alt":"generate trend raster","author":"10492","description":"","caption":"","name":"code_6_a","status":"inherit","uploaded_to":869051,"date":"2020-06-02 21:04:17","modified":"2020-06-02 21:04:41","menu_order":0,"mime_type":"image\/png","type":"image","subtype":"png","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1540,"height":247,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","medium-width":464,"medium-height":74,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","medium_large-width":768,"medium_large-height":123,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","large-width":1540,"large-height":247,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A-1536x246.png","1536x1536-width":1536,"1536x1536-height":246,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","2048x2048-width":1540,"2048x2048-height":247,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A-826x132.png","card_image-width":826,"card_image-height":132,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png","wide_image-width":1540,"wide_image-height":247}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/code_6_A.png"},{"acf_fc_layout":"content","content":" The result is a 3-band dataset, with the slope of the trend as band 1. Positive slope values (purple areas in figure 8) indicate the average precipitation is in an increasing trend over time and negative values (green areas) indicate that precipitation is in a decreasing trend.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":870841,"id":870841,"title":"Trend Raster","filename":"Figure_8.jpg","filesize":127329,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis\/imagery\/precipitation-patterns-and-trends-predictions-multidimensional-data\/figure_8","alt":"global precipitation trend","author":"10492","description":"","caption":"Figure 8: Precipitation trend, with the Amazon rainforest region outlined in blue and the Sahara desert region outlined in red","name":"figure_8","status":"inherit","uploaded_to":869051,"date":"2020-05-27 21:24:35","modified":"2020-05-27 21:25:07","menu_order":0,"mime_type":"image\/jpeg","type":"image","subtype":"jpeg","icon":"https:\/\/www.esri.com\/arcgis-blog\/wp-includes\/images\/media\/default.png","width":1408,"height":755,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8-213x200.jpg","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","medium-width":464,"medium-height":249,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","medium_large-width":768,"medium_large-height":412,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","large-width":1408,"large-height":755,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","1536x1536-width":1408,"1536x1536-height":755,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","2048x2048-width":1408,"2048x2048-height":755,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8-826x443.jpg","card_image-width":826,"card_image-height":443,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg","wide_image-width":1408,"wide_image-height":755}},"image_position":"center","orientation":"horizontal","hyperlink":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/Figure_8.jpg"},{"acf_fc_layout":"content","content":" As we inspect this trend map, we can see that the Amazon rainforest region is mostly dark purple and is experiencing an overall increase in precipitation. The Sahara desert region is primarily a light green and is experiencing an overall decrease in precipitation.<\/p>\nDetecting Precipitation Anomaly<\/strong><\/h2>\n
Precipitation Patterns and Trends <\/strong><\/h2>\n
Predicting Future Precipitation<\/strong><\/h2>\n
"}],"related_articles":"","card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/small_backgroud.jpg","wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2020\/05\/large-background-prediction.jpg"},"yoast_head":"\n