Abstract
We evaluated how deep convolutional neural networks (DCNN) could assist in the labor-intensive process of human visual searches for objects of interest in high-resolution imagery over large areas of the Earth’s surface. Various DCNN were trained and tested using fewer than 100 positive training examples (China only) from a worldwide surface-to-air-missile (SAM) site dataset. A ResNet-101 DCNN achieved a 98.2% average accuracy for the China SAM site data. The ResNet-101 DCNN was used to process ∼19.6 M image chips over a large study area in southeastern China. DCNN chip detections (∼9300) were postprocessed with a spatial clustering algorithm to produce a ranked list of ∼2100 candidate SAM site locations. The combination of DCNN processing and spatial clustering effectively reduced the search area by ∼660X (0.15% of the DCNN-processed land area). An efficient web interface was used to facilitate a rapid serial human review of the candidate SAM sites in the China study area. Four novice imagery analysts with no prior imagery analysis experience were able to complete a DCNN-assisted SAM site search in an average time of ∼42 min. This search was ∼81X faster than a traditional visual search over an equivalent land area of ∼88,640 km2 while achieving nearly identical statistical accuracy (∼90% F1).
Highlights
Deep learning (DL) methods have shown through extensive experimental validation to deliver excellent performance for a wide variety of remote sensing data processing and analysis tasks
After the visual search was completed for the entire study area, each of the three imagery analyst (IA) produced a single master shapefile identifying their detected SAM site locations and an excel sheet with their recorded search times for all 16 subregions in each of the 10 areas of interest (AoIs)
If the additional point was positively identified as a new SAM site (NSS), it was added to the total true positive (TP) count, otherwise it was counted as a false positive (FP)
Summary
Deep learning (DL) methods have shown through extensive experimental validation to deliver excellent performance for a wide variety of remote sensing data processing and analysis tasks These include image preprocessing, pixel-based classification, object/target detection and recognition, land cover classification, and scene understanding. The primary goal in this effort is to evaluate how automated DCNN object detection can be applied to assist in the traditional and labor-intensive process of human visual searches for objects/targets of interest in high-resolution EO imagery over very large areas of the Earth’s surface.
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