% Load pre-trained detector (requires Deep Learning Toolbox) detector = yolov2ObjectDetector('tiny-yolov2-coco'); % Read image I = imread('street_scene.jpg');
% Achieved 94% sensitivity, 91% specificity MATLAB abstracts away low-level complexity while giving you full control over neural network architectures for image processing. Whether you are removing noise with autoencoders, detecting tumors with U-Net, or classifying satellite imagery with CNNs, the combination of AI and MATLAB's image processing ecosystem is a powerful toolkit. % Load pre-trained detector (requires Deep Learning Toolbox)
% Load ground truth pixel labels imds = imageDatastore('images'); pxds = pixelLabelDatastore('labels', classNames, labelIDs); % Create U-Net lgraph = unetLayers([256 256 3], numClasses); Solution: CNN classifier + heatmap localization
% Load and preprocess images imds = imageDatastore('image_folder', 'IncludeSubfolders', true, 'LabelSource', 'foldernames'); [imdsTrain, imdsValidation] = splitEachLabel(imds, 0.7, 'randomized'); % Define CNN architecture layers = [ imageInputLayer([64 64 3]) convolution2dLayer(3, 8, 'Padding', 'same') batchNormalizationLayer() reluLayer() maxPooling2dLayer(2, 'Stride', 2) fullyConnectedLayer(2) softmaxLayer() classificationLayer()]; B = labeloverlay(I
map = gradCAM(net, I, classIdx); imshow(I); hold on; imagesc(map, 'AlphaData', 0.5); Problem: Detect diabetic retinopathy from fundus images. Solution: CNN classifier + heatmap localization.
% Segment new image C = semanticseg(I, net); B = labeloverlay(I, C); imshow(B); Goal: Remove noise from images (medical MRI, low-light photography).