Dummy eye measurements of microsaccades: testing the influence of system noise and head movements on microsaccade detection in a popular video-based eye tracker

Whereas early studies of microsaccades have predominantly relied on custom-built eye trackers and manual tagging of microsaccades, more recent work tends to use video-based eye tracking and automated algorithms for microsaccade detection. While data from these newer studies suggest that microsaccades can be reliably detected with video-based systems, this has not been systematically evaluated. I here present a method and data examining microsaccade detection in an often used video-based system (the Eyelink II system) and a commonly used detection algorithm (Engbert & Kliegl, 2003; Engbert & Mergenthaler, 2006). Recordings from human participants and those obtained using a pair of dummy eyes, mounted on a pair of glasses either worn by a human participant (i.e., with head motion) or a dummy head (no head motion) were compared. Three experiments were conducted. The first experiment suggests that when microsaccade measurements make use of the pupil detection mode, microsaccade detections in the absence of eye movements are sparse in the absence of head movements, but frequent with head movements (despite the use of a chin rest). A second experiment demonstrates that by using measurements that rely on a combination of corneal reflection and pupil detection, false microsaccade detections can be largely avoided as long as a binocular criterion is used. A third experiment examines whether past results may have been affected by possible incorrect detections due to small head movements. It shows that despite the many detections due to head movements, the typical modulation of microsaccade rate after stimulus onset is found only when recording from the participants’ eyes

EyePACT: eye-based parallax correction on touch-enabled interactive displays

The parallax effect describes the displacement between the perceived and detected touch locations on a touch-enabled surface. Parallax is a key usability challenge for interactive displays, particularly for those that require thick layers of glass between the screen and the touch surface to protect them from vandalism. To address this challenge, we present EyePACT, a method that compensates for input error caused by parallax on public displays. Our method uses a display-mounted depth camera to detect the user's 3D eye position in front of the display and the detected touch location to predict the perceived touch location on the surface. We evaluate our method in two user studies in terms of parallax correction performance as well as multi-user support. Our evaluations demonstrate that EyePACT (1) significantly improves accuracy even with varying gap distances between the touch surface and the display, (2) adapts to different levels of parallax by resulting in significantly larger corrections with larger gap distances, and (3) maintains a significantly large distance between two users' fingers when interacting with the same object. These findings are promising for the development of future parallax-free interactive displays

Astigmatism and Pseudoaccommodation in Pseudophakic Eyes

noAdvanced IOLs with circumferential zones of different power provide pseudoaccommodation. We investigated the potential for power variation with meridian, namely astigmatism, to provide pseudo-accommodation. With appropriate power and axis orientations, acceptable pseudo-accommodation can be achieved

Perceptual modelling for 2D and 3D

Livrable D1.1 du projet ANR PERSEECe rapport a été réalisé dans le cadre du projet ANR PERSEE (n° ANR-09-BLAN-0170). Exactement il correspond au livrable D1.1 du projet

Development of new methodologies for the clinical, objective and automated evaluation of visual function based on the analysis of ocular movements : application in visual health

Healthy visual function not only relies on good visual acuity. Other systems such as accommodation or binocular vision need to be effective. Binocular vision is the ability of the visual system to coordinate and integrate the information received separately from the two eyes into a single binocular percept. Anomalies in the binocular vision system lead to dysfunctions which are often associated with symptoms like asthenopia, diplopia, or ocular strain. The most prevalent non-strabismic binocular dysfunction is convergence insufficiency. The tests typically used to evaluate binocular vision and diagnose binocular dysfunctions essentially consist in eliciting eye movements and asking the patients to report when they perceive diplopia or single vision. In a conventional optometric clinical setting, they are generally run subjectively, as their results depend on the answers of the patients or on the examiner’s criteria. However, there exist instruments to determine the gaze position and measure ocular movements objectively, i.e. eye-trackers. These instruments are used as research tools in a wide range of applications (neuroscience, psychology, marketing, computer science, ophthalmology, etc.). Eye tracking systems are seldom used in optometric clinical practice, although it seems reasonable to think that the evaluation of binocular vision could better rely on eye tracking systems rather than subjective observations. In this context, the main objective of this thesis is to develop new methodologies for the clinical, objective and automated evaluation of visual function based on the analysis of ocular movements. This thesis is divided in 4 studies. In the first study, new methods for an eye tracking system based on multiple corneal reflections are proposed. The other 3 studies aim to analyze ocular movements in clinically interesting situations for the objective and automated evaluation of binocular vision. The results of the first study showed that the light sources configurations that produced the reflections in the lower region of the cornea showed higher accuracy. Vertical accuracy was slightly better with a higher number of corneal reflections. However, the proposed normalization methods improved vertical accuracy and counteracted the tendency for increasing accuracy with the number of glints. As a result, if the light sources are optimally positioned to avoid the interference of the eyelids and the normalization methods are applied, there is no need for more than two light sources. In the second study, an automated and objective method to measure phoria was proposed. It was significantly more repeatable than two other conventional clinical methods. However, the phoria results of the three tests were not interchangeable. This study brings to light several advantages of using eye-trackers in optometric clinical settings. The third study analyzes the characteristics of saccadic movements that occur during the near point of convergence test. The results showed that saccadic amplitude increased and rate decrease at closer viewing distances. These changes might be explained by the more rapid change of vergence demand and the greater angular size of the fixation target at near than at far. In general, saccades contributed to correct vergence errors and fixation position errors of the dominant eye. Finally, the fourth study focuses on the effects of the stimulus’ predictability on the latency and response time of vergence step movements. The results confirmed that vergence movements to predictable stimulus had shorter latency and response time than when the stimulus was random. Latency of convergence and divergence movements was influenced by the direction of the phoria. Other factors such as attention or voluntary effort might also affect vergence responses. All these effects might influence the final result of the vergence facility test, although further research is needed to specify the impact on the clinical test.Una bona funció visual no és sinònim exclusivament de bona agudesa visual. Cal que altres sistemes com l’acomodatiu o la visió binocular siguin eficaços. La visió binocular és la capacitat del sistema visual per coordinar i integrar la informació que reben els dos ulls en una única percepció. Anomalies en el sistema de visió binocular poden donar lloc a disfuncions associades a símptomes com astenopia, o visió doble. La disfunció no estràbica de la visió binocular més prevalent és la insuficiència de convergència. Els tests que normalment es fan per avaluar la visió binocular es basen en estimular moviments oculars i demanar als pacients que indiquin quan veuen doble i quan fusionen. A la pràctica clínica convencional, aquests tests solen ser subjectius. No obstant, hi ha instruments que serveixen per determinar objectivament la posició de mirada i mesurar els moviments oculars: els eye-trackers o instruments de seguiment de mirada. Aquests instruments s’utilitzen en recerca en moltes disciplines (neurociència, psicologia, marketing, oftalmologia, etc.). Tot i que una aplicació directa dels eye-trackers podria ser en l’avaluació de la visió binocular, els sistemes de seguiment de mirada gairebé no s’utilitzen en la pràctica clínica optomètrica. En aquest context, l’objectiu principal d’aquesta tesi és desenvolupar noves metodologies per a l’avaluació clínica, objectiva i automatitzada de la funció visual basades en l’anàlisi dels moviments oculars. La tesi està estructurada en 4 estudis. En el primer, es proposen nous mètodes per a un eye-tracker basat en múltiples reflexos corneals. Els altres 3 estudis tenen com a objectiu analitzar els moviments oculars en situacions d’interès clínic per avaluar objectiva i automàticament la visió binocular. Els resultats del primer estudi demostren que les configuracions d’il·luminació dels eye-trackers que formen les reflexions corneals a la zona inferior de la còrnia són més precises. La precisió vertical és lleugerament millor amb més fonts de llum. Tot i això, els mètodes de normalització proposats milloren considerablement la precisió vertical i contraresten la tendència de més precisió amb més fonts de llum. D’aquesta manera, si les fonts de llum no interfereixen amb les parpelles i s’apliquen els mètodes de normalització, no cal que els eye-trackers tinguin més de dues fonts de llum. En el segon estudi s’ha proposat un mètode automàtic i objectiu per mesurar la fòria. Aquest mètode és significativament més repetitiu que dos altres mètodes clínics. Tot i això, els resultats amb els tres mètodes no són intercanviables. Aquest estudi posa de manifest avantatges que podrien tenir els eye-trackers a la pràctica clínica optomètrica. En el tercer estudi s’analitzen les característiques dels moviments sacàdics que es produeixen durant la prova del punt proper de convergència. Els resultats demostren que l’amplitud dels sacàdics augmenta i la freqüència disminueix a mesura que s’escurça la distància. Aquests canvis poden ser deguts a que la demanda de vergència canvia més ràpid a distàncies properes que llunyanes, i a l’increment de la mida angular de l’objecte de fixació. En general, els sacàdics contribueixen a corregir els errors de vergència i els errors de fixació de l’ull dominant. Finalment, el quart estudi se centra en els efectes de la predictibilitat de l’estímul en la latència i temps de resposta dels salts de vergència. Els resultats confirmen que els moviments de vergència tenen una latència i temps de resposta més curts quan l’estímul es predictible que quan és aleatori. La latència dels moviments de convergència i divergència està influenciada per la direcció de la fòria. Altres factors com el grau d’atenció o d’esforç voluntari pot ser que afectin els moviments de vergència. Tots aquests efectes probablement influencien en el resultat final de la prova de la instal·lació de vergència, encara que es necessiten més investigacions per especificar l'impacte en la prova clínica

A Real-time Range Finding System with Binocular Stereo Vision

To acquire range information for mobile robots, a TMS320DM642 DSP-based range finding system with binocular stereo vision is proposed. Firstly, paired images of the target are captured and a Gaussian filter, as well as improved Sobel kernels, are achieved. Secondly, a feature-based local stereo matching algorithm is performed so that the space location of the target can be determined. Finally, in order to improve the reliability and robustness of the stereo matching algorithm under complex conditions, the confidence filter and the left-right consistency filter are investigated to eliminate the mismatching points. In addition, the range finding algorithm is implemented in the DSP/BIOS operating system to gain real-time control. Experimental results show that the average accuracy of range finding is more than 99% for measuring single-point distances equal to 120cm in the simple scenario and the algorithm takes about 39ms for ranging a time in a complex scenario. The effectivity, as well as the feasibility, of the proposed range finding system are verified