A wide variety of disciplines use eye-tracking techniques, including
cognitive science;
psychology (notably
psycholinguistics; the visual world paradigm);
human-computer interaction (HCI);
human factors and ergonomics;
marketing research and medical research (neurological diagnosis). Specific applications include the tracking eye movement in
language reading,
music reading, human
activity recognition, the perception of advertising, playing of sports, distraction detection and
cognitive load estimation of drivers and pilots and as a means of operating computers by people with severe motor impairment.
Commercial applications In recent years, the increased sophistication and accessibility of eye-tracking technologies have generated a great deal of interest in the commercial sector. Applications include
web usability, advertising, sponsorship, package design and automotive engineering. In general, commercial eye-tracking studies function by presenting a target stimulus to a sample of consumers while an eye tracker records eye activity. Examples of target stimuli may include websites, television programs, sporting events, films and commercials, magazines and newspapers, packages, shelf displays, consumer systems (ATMs, checkout systems, kiosks) and software. The resulting data can be statistically analyzed and graphically rendered to provide evidence of specific visual patterns. By examining fixations,
saccades, pupil dilation, blinks and a variety of other behaviors, researchers can determine a great deal about the effectiveness of a given medium or product. While some companies complete this type of research internally, there are many private companies that offer eye-tracking services and analysis. One field of commercial eye-tracking research is web usability. While traditional usability techniques are often quite powerful in providing information on clicking and scrolling patterns, eye-tracking offers the ability to analyze user interaction between the clicks and how much time a user spends between clicks, thereby providing valuable insight into which features are the most eye-catching, which features cause confusion and which are ignored altogether. Specifically, eye-tracking can be used to assess search efficiency, branding, online advertisements, navigation usability, overall design and many other site components. Analyses may target a prototype or competitor site in addition to the main client site. Eye-tracking is commonly used in a variety of different advertising media. Commercials, print ads, online ads and sponsored programs are all conducive to analysis with current eye-tracking technology. One example is the analysis of eye movements over advertisements in the
Yellow Pages. One study focused on what particular features caused people to notice an ad, whether they viewed ads in a particular order and how viewing times varied. The study revealed that ad size, graphics, color, and copy all influence attention to advertisements. Knowing this allows researchers to assess in great detail how often a sample of consumers fixates on the target logo, product or ad. Hence an advertiser can quantify the success of a given campaign in terms of actual visual attention. Another example of this is a study that found that in a
search engine results page, authorship snippets received more attention than the paid ads or even the first organic result. Yet another example of commercial eye-tracking research comes from the field of recruitment. A study analyzed how recruiters screen
LinkedIn profiles and presented results as
heat maps.
Safety applications Scientists in 2017 constructed a Deep Integrated Neural Network (DINN) out of a Deep Neural Network and a convolutional neural network. The goal was to use
deep learning to examine images of drivers and determine their level of drowsiness by "classify[ing] eye states." With enough images, the proposed DINN could ideally determine when drivers blink, how often they blink, and for how long. From there, it could judge how tired a given driver appears to be, effectively conducting an eye-tracking exercise. The DINN was trained on data from over 2,400 subjects and correctly diagnosed their states 96%-99.5% of the time. Most other artificial intelligence models performed at rates above 90%. It was then fed eye-tracking input data from 30 chess players of various skill levels. With this data, the CNN used gaze estimation to determine parts of the chess board to which a player was paying close attention. It then generated a saliency map to illustrate those parts of the board. Ultimately, the CNN would combine its knowledge of the board and pieces with its saliency map to predict the players' next move. Regardless of the
training dataset the neural network system was trained upon, it predicted the next move more accurately than if it had selected any possible move at random, and the saliency maps drawn for any given player and situation were more than 54% similar. as it is faster than single switch scanning techniques and intuitive to operate. Motor impairment caused by
cerebral palsy or
amyotrophic lateral sclerosis often affects speech, and users with severe speech and motor impairment (SSMI) use a type of software known as
augmentative and alternative communication (AAC) aid, that displays icons, words and letters on screen and uses text-to-speech software to generate spoken output. In recent times, researchers also explored eye tracking to control robotic arms and powered wheelchairs. Eye tracking is also helpful in analysing visual search patterns, detecting presence of
nystagmus and detecting early signs of learning disability by analysing eye gaze movement during reading.
Aviation applications Eye tracking has already been studied for flight safety by comparing scan paths and fixation duration to evaluate the progress of pilot trainees, for estimating pilots' skills, for analyzing crew's joint attention and shared situational awareness. Eye tracking technology was also explored to interact with helmet mounted display systems in military aircraft. Studies were conducted to investigate the utility of eye tracker for Head-up target locking and Head-up target acquisition in Helmet mounted display systems (HMDS). Pilots' feedback suggested that even though the technology is promising, its hardware and software components are yet to be matured. Eye tracking is also useful for detecting pilot fatigue. Eye tracking is being explored as a potential method to control IVIS (In-Vehicle Infotainment Systems), the multimedia and navigation systems frequently present in contemporary cars. Though initial research investigated the efficacy of eye tracking system for interaction with HDD (Head Down Display), it still required drivers to take their eyes off the road while performing a secondary task. Recent studies investigated eye gaze controlled interaction with HUD (Head Up Display) that eliminates eyes-off-road distraction. Eye tracking is also used to monitor cognitive load of drivers to detect potential distraction. Though researchers explored different methods to estimate
cognitive load of drivers from different physiological parameters, usage of ocular parameters explored a new way to use the existing eye trackers to monitor cognitive load of drivers in addition to interaction with IVIS.
Entertainment applications The 2021 video game
Before Your Eyes registers and reads the player's blinking, and uses it as the main way of interacting with the game.
Engineering applications The widespread use of eye-tracking technology has shed light to its use in empirical software engineering in the most recent years. The eye-tracking technology and data analysis techniques are used to investigate the understandability of software engineering concepts by the researchers. These include the understandability of business process models, and diagrams used in software engineering such as
UML activity diagrams and
EER diagrams. Eye-tracking metrics such as fixation, scan-path, scan-path precision, scan-path recall, fixations on area of interest/relevant region are computed, analyzed and interpreted in terms of model and diagram understandability. The findings are used to enhance the understandability of diagrams and models with proper model related solutions and by improving personal related factors such as working-memory capacity,
cognitive-load,
learning style and strategy of the software engineers and modelers.
Cartographic applications Cartographic research has widely adopted eye tracking techniques. Researchers have used them to see how individuals perceive and interpret
maps. For example, eye tracking has been used to study differences in perception of 2D and 3D visualization, comparison of map reading strategies between novices and experts or students and their geography teachers, and evaluation of the cartographic quality of maps. Besides, cartographers have employed eye tracking to investigate various factors affecting map reading, including attributes such as color or symbol density. Numerous studies about the usability of map applications took advantage of eye tracking, too. The cartographic community's daily engagement with visual and spatial data positioned it to contribute significantly to eye tracking data visualization methods and tools. For example, cartographers have developed methods for integrating eye tracking data with
GIS, utilizing GIS software for further visualization and analysis. The community has also delivered tools for visualizing eye tracking data ==Privacy concerns==