Saliency map explained

In computer vision, a saliency map is an image that highlights either the region on which people's eyes focus first or the most relevant regions for machine learning models.[1] The goal of a saliency map is to reflect the degree of importance of a pixel to the human visual system or an otherwise opaque ML model.

For example, in this image, a person first looks at the fort and light clouds, so they should be highlighted on the saliency map. Saliency maps engineered in artificial or computer vision are typically not the same as the actual saliency map constructed by biological or natural vision.

Application

Overview

Saliency maps have applications in a variety of different problems. Some general applications:

Human eye

It aims at resizing an image by expanding or shrinking the noninformative regions. Therefore, retargeting algorithms rely on the availability of saliency maps that accurately estimate all the salient image details.[4]

Explainable Artificial Intelligence

Saliency as a segmentation problem

Saliency estimation may be viewed as an instance of image segmentation. In computer vision, image segmentation is the process of partitioning a digital image into multiple segments (sets of pixels, also known as superpixels). The goal of segmentation is to simplify and/or change the representation of an image into something that is more meaningful and easier to analyze. Image segmentation is typically used to locate objects and boundaries (lines, curves, etc.) in images. More precisely, image segmentation is the process of assigning a label to every pixel in an image such that pixels with the same label share certain characteristics.[7]

Algorithms

Overview

There are three forms of classic saliency estimation algorithms implemented in OpenCV:

In addition to classic approaches, neural-network-based are also popular. There are examples of neural networks for motion saliency estimation:

Example implementation

First, we should calculate the distance of each pixel to the rest of pixels in the same frame:

SALS(Ik)=

N|I
\sum
k

-Ii|

Ii

is the value of pixel

i

, in the range of [0,255]. The following equation is the expanded form of this equation.

Where N is the total number of pixels in the current frame. Then we can further restructure our formula. We put the value that has same I together.

Where is the frequency of . And the value of n belongs to [0,255]. The frequencies is expressed in the form of histogram, and the computational time of histogram is time complexity.

Time complexity

This saliency map algorithm has time complexity. Since the computational time of histogram is time complexity which N is the number of pixel's number of a frame. Besides, the minus part and multiply part of this equation need 256 times operation. Consequently, the time complexity of this algorithm is which equals to .

Pseudocode

All of the following code is pseudo MATLAB code. First, read data from video sequences.for k = 2 : 1 : 13 % which means from frame 2 to 13, and in every loop K's value increase one. I = imread(currentfilename); % read current frame I1 = im2single(I); % convert double image into single(requirement of command vlslic) l = imread(previousfilename); % read previous frame I2 = im2single(l); regionSize = 10; % set the parameter of SLIC this parameter setting are the experimental result. RegionSize means the superpixel size. regularizer = 1; % set the parameter of SLIC segments1 = vl_slic(I1, regionSize, regularizer); % get the superpixel of current frame segments2 = vl_slic(I2, regionSize, regularizer); % get superpixel of the previous frame numsuppix = max(segments1(:)); % get the number of superpixel all information about superpixel is in this link http://www.vlfeat.org/overview/slic.html regstats1 = regionprops(segments1, ’all’); regstats2 = regionprops(segments2, ’all’); % get the region characteristic based on segments1After we read data, we do superpixel process to each frame.Spnum1 and Spnum2 represent the pixel number of current frame and previous pixel.

% First, we calculate the value distance of each pixel.% This is our core codefor i = 1:1:spnum1 % From the first pixel to the last one. And in every loop i++ for j = 1:1:spnum2 % From the first pixel to the last one. j++. previous frame centredist(i:j) = sum((center(i) - center(j))); % calculate the center distance endend

Then we calculate the color distance of each pixel, this process we call it contract function.for i = 1:1:spnum1 % From first pixel of current frame to the last one pixel. I ++ for j = 1:1:spnum2 % From first pixel of previous frame to the last one pixel. J++ posdiff(i, j) = sum((regstats1(j).Centroid’ - mupwtd(:, i))); % Calculate the color distance. endendAfter this two process, we will get a saliency map, and then store all of these maps into a new FileFolder.

Difference in algorithms

The major difference between function one and two is the difference of contract function. If spnum1 and spnum2 both represent the current frame's pixel number, then this contract function is for the first saliency function. If spnum1 is the current frame's pixel number and spnum2 represent the previous frame's pixel number, then this contract function is for second saliency function. If we use the second contract function which using the pixel of the same frame to get center distance to get a saliency map, then we apply this saliency function to each frame and use current frame's saliency map minus previous frame's saliency map to get a new image which is the new saliency result of the third saliency function.

Datasets

The saliency dataset usually contains human eye movements on some image sequences. It is valuable for new saliency algorithm creation or benchmarking the existing one. The most valuable dataset parameters are spatial resolution, size, and eye-tracking equipment. Here is part of the large datasets table from MIT/Tübingen Saliency Benchmark datasets, for example.

Saliency datasets!Dataset!Resolution!Size!Observers!Durations!Eyetracker
CAT20001920×1080px4000 images245 secEyeLink 1000 (1000Hz)
EyeTrackUAV21280×720px43 videos3033 secEyeLink 1000 Plus (1000 Hz, binocular)
CrowdFix1280×720px434 videos261-3 secThe Eyetribe Eyetracker (60 Hz)
SAVAM1920×1080px43 videos5020 secSMI iViewXTM Hi-Speed 1250 (500Hz)
To collect a saliency dataset, image or video sequences and eye-tracking equipment must be prepared, and observers must be invited. Observers must have normal or corrected to normal vision and must be at the same distance from the screen. At the beginning of each recording session, the eye-tracker recalibrates. To do this, the observer fixates his gaze on the screen center. Then the session started, and saliency data are collected by showing sequences and recording eye gazes.

The eye-tracking device is a high-speed camera, capable of recording eye movements at least 250 frames per second. Images from the camera are processed by the software, running on a dedicated computer returning gaze data.

External links

See also

Notes and References

  1. News: Subhash . Bijil . Explainable AI: Saliency Maps . 26 May 2024 . Medium . 6 March 2022 . en.
  2. Guo. Chenlei. Zhang. Liming. Jan 2010. A Novel Multiresolution Spatiotemporal Saliency Detection Model and Its Applications in Image and Video Compression. IEEE Transactions on Image Processing. 19. 1. 185–198. 10.1109/TIP.2009.2030969. 19709976 . 2010ITIP...19..185G . 1154218 . 1057-7149.
  3. Tong. Yubing. Konik. Hubert. Cheikh. Faouzi. Tremeau. Alain. 2010-05-01. Full Reference Image Quality Assessment Based on Saliency Map Analysis. Journal of Imaging Science and Technology. 54. 3. 30503–1–30503-14. 10.2352/J.ImagingSci.Technol.2010.54.3.030503. free. 11250/142490. free.
  4. Goferman. Stas. Zelnik-Manor. Lihi. Tal. Ayellet. Oct 2012. Context-Aware Saliency Detection. IEEE Transactions on Pattern Analysis and Machine Intelligence. 34. 10. 1915–1926. 10.1109/TPAMI.2011.272. 22201056 . 1939-3539.
  5. Book: Jiang. Huaizu. Wang. Jingdong. Yuan. Zejian. Wu. Yang. Zheng. Nanning. Li. Shipeng. 2013 IEEE Conference on Computer Vision and Pattern Recognition . Salient Object Detection: A Discriminative Regional Feature Integration Approach . June 2013. http://dx.doi.org/10.1109/cvpr.2013.271. 2083–2090 . IEEE. 10.1109/cvpr.2013.271. 1410.5926. 978-0-7695-4989-7 .
  6. Müller . Romy . How explainable AI affects human performance: A systematic review of the behavioural consequences of saliency maps . 2024 . cs.HC . 2404.16042.
  7. A. Maity . Improvised Salient Object Detection and Manipulation . 2015. 1511.02999. cs.CV.