Orthoimages, which are frequently employed for object detection, have certain drawbacks. A solution for this is to detect features in pixel space using oblique terrestrial data and then transform the detections into map space. Please refer to this blog<\/a> for the workflow using mosaic datasets to perform feature extraction on terrestrial data.<\/p>\n A critical requirement within this workflow has been the need for users to perform object detection on imagery prior to geometric adjustment (i.e. georeferencing and rectification).<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":2954586,"id":2954586,"title":"g7528833-transform-image-shapes-illustrations-1 2","filename":"g7528833-transform-image-shapes-illustrations-1-2.jpg","filesize":54432,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis-pro\/geoai\/real-time-object-detection-using-ai-for-terrestrial-data\/g7528833-transform-image-shapes-illustrations-1-2","alt":"","author":"178852","description":"","caption":"","name":"g7528833-transform-image-shapes-illustrations-1-2","status":"inherit","uploaded_to":2951408,"date":"2026-01-22 20:41:37","modified":"2026-01-22 20:41:37","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":510,"height":365,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2-213x200.jpg","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","medium-width":365,"medium-height":261,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","medium_large-width":510,"medium_large-height":365,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","large-width":510,"large-height":365,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","1536x1536-width":510,"1536x1536-height":365,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","2048x2048-width":510,"2048x2048-height":365,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","card_image-width":510,"card_image-height":365,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/g7528833-transform-image-shapes-illustrations-1-2.jpg","wide_image-width":510,"wide_image-height":365}},"image_position":"center","orientation":"horizontal","hyperlink":""},{"acf_fc_layout":"content","content":" Real-time detections <\/strong><\/p>\n Real-time detection is important for several reasons:<\/p>\n In both scenarios, there is a fundamental need to transform detections collected in pixel space into map space. Currently, the operational constraint requires users to either delay the detection process until the image collection is orthorectified or re-run the inference on the final orthorectified imagery, thereby nullifying the value of the initial real-time detections.<\/p>\n <\/p>\n The Transformation Image Shapes tool<\/strong><\/p>\n This is where the new Transform Image Shapes tool provides significant utility. The tool transforms the input pixel-space detections to map space using the geometric information contained within the image collection.<\/p>\n The tool accepts three key inputs:<\/p>\n <\/p>\n <\/p>\n"},{"acf_fc_layout":"image","image":{"ID":2951413,"id":2951413,"title":"Picture3","filename":"Picture3.png","filesize":47772,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis-pro\/geoai\/real-time-object-detection-using-ai-for-terrestrial-data\/picture3-85","alt":"","author":"178852","description":"","caption":"","name":"picture3-85","status":"inherit","uploaded_to":2951408,"date":"2025-12-11 21:03:55","modified":"2025-12-11 21:03:55","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":398,"height":278,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","medium-width":374,"medium-height":261,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","medium_large-width":398,"medium_large-height":278,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","large-width":398,"large-height":278,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","1536x1536-width":398,"1536x1536-height":278,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","2048x2048-width":398,"2048x2048-height":278,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","card_image-width":398,"card_image-height":278,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture3.png","wide_image-width":398,"wide_image-height":278}},"image_position":"center","orientation":"horizontal","hyperlink":""},{"acf_fc_layout":"content","content":" Consider an imagery collection captured from a street-level imaging system\u00a0in Southern California, where the objective was to detect trees next to the sidewalk. This is often done for tree species identification.<\/p>\n We processed street-level images of a neighborhood in San Bernardino, captured by vehicle-mounted cameras. The initial step involved running the Detect Object Using Deep Learning<\/a> tool on the folder containing 200 images. This provided raw tree detections in image space (pixel size\u00a0coordinates).<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":2951414,"id":2951414,"title":"Picture4","filename":"Picture4.png","filesize":449979,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis-pro\/geoai\/real-time-object-detection-using-ai-for-terrestrial-data\/picture4-82","alt":"","author":"178852","description":"","caption":"","name":"picture4-82","status":"inherit","uploaded_to":2951408,"date":"2025-12-11 21:03:56","modified":"2025-12-11 21:03:56","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":519,"height":390,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","medium-width":347,"medium-height":261,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","medium_large-width":519,"medium_large-height":390,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","large-width":519,"large-height":390,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","1536x1536-width":519,"1536x1536-height":390,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","2048x2048-width":519,"2048x2048-height":390,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","card_image-width":519,"card_image-height":390,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture4.png","wide_image-width":519,"wide_image-height":390}},"image_position":"center","orientation":"horizontal","hyperlink":""},{"acf_fc_layout":"content","content":" These image space detections are not very useful until they are accurately mapped to the ground. To achieve this, we created a rectified image collection for the area where the images were taken. The camera locations are visible within this reality-mapping-ready collection.<\/p>\n Once the image collection was prepared, we ran the new Transform Image Spaces<\/a> tool to convert the detections. Since there is a lot of overlap between the images, you will see a lot of duplication of features. \u00a0Following the transformation, the Non-Maximum Suppression<\/a> tool is\u00a0used to eliminate duplicate detections. Finally, the Feature to Point<\/a> tool was run to better visualize the results, which are now accurately mapped to the ground.<\/p>\n"},{"acf_fc_layout":"image","image":{"ID":2951415,"id":2951415,"title":"Picture5","filename":"Picture5.png","filesize":523275,"url":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","link":"https:\/\/www.esri.com\/arcgis-blog\/products\/arcgis-pro\/geoai\/real-time-object-detection-using-ai-for-terrestrial-data\/picture5-65","alt":"","author":"178852","description":"","caption":"","name":"picture5-65","status":"inherit","uploaded_to":2951408,"date":"2025-12-11 21:03:58","modified":"2025-12-11 21:03:58","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":624,"height":320,"sizes":{"thumbnail":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5-213x200.png","thumbnail-width":213,"thumbnail-height":200,"medium":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","medium-width":464,"medium-height":238,"medium_large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","medium_large-width":624,"medium_large-height":320,"large":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","large-width":624,"large-height":320,"1536x1536":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","1536x1536-width":624,"1536x1536-height":320,"2048x2048":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","2048x2048-width":624,"2048x2048-height":320,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","card_image-width":624,"card_image-height":320,"wide_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2025\/12\/Picture5.png","wide_image-width":624,"wide_image-height":320}},"image_position":"center","orientation":"horizontal","hyperlink":""}],"authors":[{"ID":178852,"user_firstname":"Sangeet","user_lastname":"Mathew","nickname":"Sangeet Mathew","user_nicename":"smathew","display_name":"Sangeet Mathew","user_email":"smathew@esri.com","user_url":"","user_registered":"2021-02-11 16:40:56","user_description":"Principal Product Engineer on the Imagery team at Esri, with a focus on AI & Image Analysis.","user_avatar":"\n
\n
"},{"ID":254042,"user_firstname":"Pavan","user_lastname":"Yadav","nickname":"Pavan Yadav","user_nicename":"pyadav","display_name":"Pavan Yadav","user_email":"PYadav@esri.com","user_url":"","user_registered":"2021-07-20 16:55:01","user_description":"Pavan Yadav is a Senior Software Product Engineer at Esri's Imagery team, leveraging AI to extract valuable insights from imagery data and contributing to the development of geospatial AI (GeoAI).","user_avatar":"
"}],"related_articles":"","show_article_image":false,"card_image":"https:\/\/www.esri.com\/arcgis-blog\/app\/uploads\/2026\/01\/transform-image-shapes-card.jpg","wide_image":false},"yoast_head":"\n