Your search keyword '"Haptic technology"' showing total 23,706 results

51. The Technology of Haptics in Dental Education

Author

Gali, Sivaranjani and Patil, Archana

Published

2018

52. Prior visual experience increases children's use of effective haptic exploration strategies in audio-tactile sound-shape correspondences.

Author

Cao S, Kelly J, Nyugen C, Chow HM, Leonardo B, Sabov A, and Ciaramitaro VM

Subjects

Child, Humans, Touch, Sound, Emotions, Haptic Technology, Vision, Ocular

Abstract

Sound-shape correspondence refers to the preferential mapping of information across the senses, such as associating a nonsense word like bouba with rounded abstract shapes and kiki with spiky abstract shapes. Here we focused on audio-tactile (AT) sound-shape correspondences between nonsense words and abstract shapes that are felt but not seen. Despite previous research indicating a role for visual experience in establishing AT associations, it remains unclear how visual experience facilitates AT correspondences. Here we investigated one hypothesis: seeing the abstract shapes improve haptic exploration by (a) increasing effective haptic strategies and/or (b) decreasing ineffective haptic strategies. We analyzed five haptic strategies in video-recordings of 6- to 8-year-old children obtained in a previous study. We found the dominant strategy used to explore shapes differed based on visual experience. Effective strategies, which provide information about shape, were dominant in participants with prior visual experience, whereas ineffective strategies, which do not provide information about shape, were dominant in participants without prior visual experience. With prior visual experience, poking-an effective and efficient strategy-was dominant, whereas without prior visual experience, uncategorizable and ineffective strategies were dominant. These findings suggest that prior visual experience of abstract shapes in 6- to 8-year-olds can increase the effectiveness and efficiency of haptic exploration, potentially explaining why prior visual experience can increase the strength of AT sound-shape correspondences., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

53. Exploring Bimanual Haptic Feedback for Spatial Search in Virtual Reality.

Author

Gao B, Shao T, Tu H, Ma Q, Liu Z, and Han T

Subjects

Humans, Feedback, Computer Graphics, Feedback, Sensory, Haptic Technology, Virtual Reality

Abstract

Spatial search tasks are common and crucial in many Virtual Reality (VR) applications. Traditional methods to enhance the performance of spatial search often employ sensory cues such as visual, auditory, or haptic feedback. However, the design and use of bimanual haptic feedback with two VR controllers for spatial search in VR remains largely unexplored. In this work, we explored bimanual haptic feedback with various combinations of haptic properties, where four types of bimanual haptic feedback were designed, for spatial search tasks in VR. Two experiments were designed to evaluate the effectiveness of bimanual haptic feedback on spatial direction guidance and search in VR. The results from the first experiment reveal that our proposed bimanual haptic schemes significantly enhanced the recognition of spatial directions in terms of accuracy and speed compared to spatial audio feedback. The second experiment's findings suggest that the performance of bimanual haptic feedback was comparable to or even better than the visual arrow, especially in reducing the angle of head movement and enhancing searching targets behind the participants, which was supported by subjective feedback as well. Based on these findings, we have derived a set of design recommendations for spatial search using bimanual haptic feedback in VR.

Published

2024

54. MusiKeys: Exploring Haptic-to-Auditory Sensory Substitution to Improve Mid-Air Text-Entry.

Author

Krasner A and Gabbard J

Subjects

Humans, Equipment Design, Computer Graphics, Touch, User-Computer Interface, Haptic Technology, Touch Perception

Abstract

Physical QWERTY keyboards are the current standard for performing precision text-entry with extended reality devices. Ideally, there would exist a comparable, self-contained solution that works anywhere, without requiring external keyboards. Unfortunately, when physical keyboards are recreated virtually, we currently lose critical haptic feedback information from the sense of touch, which impedes typing. In this paper, we introduce the MusiKeys Technique, which uses auditory feedback in virtual reality to communicate missing haptic feedback information typists normally receive when using a physical keyboard. To examine this concept, we conducted a user study with 24 participants which encompassed four mid-air virtual keyboards augmented with increasing amounts of feedback information, along with a fifth physical keyboard for reference. Results suggest that providing clicking feedback on key-press and key-release improves typing performance compared to not providing auditory feedback, which is consistent with the literature. We also found that audio can serve as a substitute for information contained in haptic feedback, in that users can accurately perceive the presented information. However, under our specific study conditions, this awareness of the feedback information did not yield significant differences in typing performance. Our results suggest this kind of feedback replacement can be perceived by users but needs more research to tune and improve the specific techniques.

Published

2024

55. Developmental changes in the visual, haptic, and bimodal perception of geometric angles.

Author

Holmes CA, Cooney SM, Dempsey P, and Newell FN

Subjects

Adult, Child, Humans, Adolescent, Haptic Technology, Vision, Ocular, Spatial Learning, Knowledge, Visual Perception, Touch Perception

Abstract

Geometrical knowledge is typically taught to children through a combination of vision and repetitive drawing (i.e. haptics), yet our understanding of how different spatial senses contribute to geometric perception during childhood is poor. Studies of line orientation suggest a dominant role of vision affecting the calibration of haptics during development; however, the associated multisensory interactions underpinning angle perception are unknown. Here we examined visual, haptic, and bimodal perception of angles across three age groups of children: 6 to 8 years, 8 to 10 years, and 10 to 12 years, with age categories also representing their class (grade) in primary school. All participants first learned an angular shape, presented dynamically, in one of three sensory tracing conditions: visual only, haptic only, or bimodal exploration. At test, which was visual only, participants selected a target angle from four possible alternatives with distractor angle sizes varying relative to the target angle size. We found a clear improvement in accuracy of angle perception with development for all learning modalities. Angle perception in the youngest group was equally poor (but above chance) for all modalities; however, for the two older child groups, visual learning was better than haptics. Haptic perception did not improve to the level of vision with age (even in a comparison adult group), and we found no specific benefit for bimodal learning over visual learning in any age group, including adults. Our results support a developmental increment in both spatial accuracy and precision in all modalities, which was greater in vision than in haptics, and are consistent with previous accounts of cross-sensory calibration in the perception of geometric forms., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

56. Visuo-Haptic VR and AR Guidance for Dental Nerve Block Education.

Author

Samuel S, Elvezio C, Khan S, Bitzer LZ, Moss-Salentijn L, and Feiner S

Subjects

Humans, Haptic Technology, Mandibular Nerve, Computer Graphics, Augmented Reality, Nerve Block methods, Virtual Reality

Abstract

The inferior alveolar nerve block (IANB) is a dental anesthetic injection that is critical to the performance of many dental procedures. Dental students typically learn to administer an IANB through videos and practice on silicone molds and, in many dental schools, on other students. This causes significant stress for both the students and their early patients. To reduce discomfort and improve clinical outcomes, we created an anatomically informed virtual reality headset-based educational system for the IANB. It combines a layered 3D anatomical model, dynamic visual guidance for syringe position and orientation, and active force feedback to emulate syringe interaction with tissue. A companion mobile augmented reality application allows students to step through a visualization of the procedure on a phone or tablet. We conducted a user study to determine the advantages of preclinical training with our IANB simulator. We found that in comparison to dental students who were exposed only to traditional supplementary study materials, dental students who used our IANB simulator were more confident administering their first clinical injections, had less need for syringe readjustments, and had greater success in numbing patients.

Published

2024

57. Reconsidering Luria's speech mediation: Verbalization and haptic picture identification in children with congenital total blindness.

Author

D'Angiulli A, Wymark D, Temi S, Bahrami S, and Telfer A

Subjects

Child, Humans, Blindness psychology, Vision Disorders, Touch, Speech, Haptic Technology

Abstract

Current accounts of behavioral and neurocognitive correlates of plasticity in blindness are just beginning to incorporate the role of speech and verbal production. We assessed Vygotsky/Luria's speech mediation hypothesis, according to which speech activity can become a mediating tool for perception of complex stimuli, specifically, for encoding tactual/haptic spatial patterns which convey pictorial information (haptic pictures). We compared verbalization in congenitally totally blind (CTB) and age-matched sighted but visually impaired (VI) children during a haptic picture naming task which included two repeated, test-retest, identifications. The children were instructed to explore 10 haptic schematic pictures of objects (e.g., cup) and body parts (e.g., face) and provide (without experimenter's feedback) their typical name. Children's explorations and verbalizations were videorecorded and transcribed into audio segments. Using the Computerized Analysis of Language (CLAN) program, we extracted several measurements from the observed verbalizations, including number of utterances and words, utterance/word duration, and exploration time. Using the Word2Vec natural language processing technique we operationalized semantic content from the relative distances between the names provided. Furthermore, we conducted an observational content analysis in which three judges categorized verbalizations according to a rating scale assessing verbalization content. Results consistently indicated across all measures that the CTB children were faster and semantically more precise than their VI counterparts in the first identification test, however, the VI children reached the same level of precision and speed as the CTB children at retest. Overall, the task was harder for the VI group. Consistent with current neuroscience literature, the prominent role of speech in CTB and VI children's data suggests that an underlying cross-modal involvement of integrated brain networks, notably associated with Broca's network, likely also influenced by Braille, could play a key role in compensatory plasticity via the mediational mechanism postulated by Luria., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

58. Field experiment of a telesurgery system using a surgical robot with haptic feedback.

Author

Ota M, Oki E, Nakanoko T, Tanaka Y, Toyota S, Hu Q, Nakaji Y, Nakanishi R, Ando K, Kimura Y, Hisamatsu Y, Mimori K, Takahashi Y, Morohashi H, Kanno T, Tadano K, Kawashima K, Takano H, Ebihara Y, Shiota M, Inokuchi J, Eto M, Yoshizumi T, Hakamada K, Hirano S, and Mori M

Subjects

Animals, Humans, Feedback, Haptic Technology, Robotics, Robotic Surgical Procedures, Surgeons

Abstract

Purpose: To verify the usefulness of haptic feedback in telesurgery and improve the safety of telerobotic surgery., Methods: The surgeon's console was installed at two sites (Fukuoka and Beppu; 140 km apart), and the patient cart was installed in Fukuoka. During the experiment, the surgeon was blinded to the haptic feedback levels and asked to grasp the intestinal tract in an animal model. The surgeon then performed the tasks at each location., Results: No marked differences in task accuracy or average grasping force were observed between the surgeon locations. However, the average task completion time was significantly longer, and the system usability scale (SUS) was significantly lower rating for remote operations than for local ones. No marked differences in task accuracy or task completion time were observed between the haptic feedback levels. However, with haptic feedback, the organ was grasped with a significantly weaker force than that without it. Furthermore, with haptic feedback, experienced surgeons in robotic surgery tended to perform an equivalent task with weaker grasping forces than inexperienced surgeons., Conclusion: The haptic feedback function is a tool that allows the surgeon to perform surgery with an appropriate grasping force, both on site and remotely. Improved safety is necessary in telesurgery; haptic feedback will thus be an essential technology in robotic telesurgery going forward., (© 2023. The Author(s) under exclusive licence to Springer Nature Singapore Pte Ltd.)

Published

2024

59. Haptics: The Science of Touch As a Foundational Pathway to Precision Education and Assessment.

Author

Perrone KH, Abdelaal AE, Pugh CM, and Okamura AM

Subjects

Humans, Artificial Intelligence, Physician-Patient Relations, User-Computer Interface, Touch, Haptic Technology

Abstract

Abstract: Clinical touch is the cornerstone of the doctor-patient relationship and can impact patient experience and outcomes. In the current era, driven by an ever-increasing infusion of point-of-care technologies, physical exam skills have become undervalued. Moreover, touch and hands-on skills have been difficult to teach due to inaccurate assessments and difficulty with learning transfer through observation. In this article, the authors argue that haptics, the science of touch, provides a unique opportunity to explore new pathways to facilitate touch training. Furthermore, haptics can dramatically increase the density of touch-based assessments without increasing human rater burden-essential for realizing precision assessment. The science of haptics is reviewed, including the benefits of using haptics-informed language for objective structured clinical examinations. The authors describe how haptic devices and haptic language have and can be used to facilitate learning, communication, documentation and a much-needed reinvigoration of physical examination, and touch excellence at the point of care. The synergy of haptic devices, artificial intelligence, and virtual reality environments are discussed. The authors conclude with challenges of scaling haptic technology in medical education, such as cost and translational needs, and opportunities to achieve wider adoption of this transformative approach to precision education., (Copyright © 2023 the Association of American Medical Colleges.)

Published

2024

60. Quality and haptic feedback of three-dimensionally printed models for simulating dental implant surgery.

Author

Wang X, Shujaat S, Shaheen E, and Jacobs R

Subjects

Humans, Middle Aged, Computer-Aided Design, Feedback, Haptic Technology, Printing, Three-Dimensional, Stereolithography, Male, Dental Implants

Abstract

Statement of Problem: A model offering anatomic replication and haptic feedback similar to that of real bone is essential for hands-on surgical dental implant training. Patient-specific skeletal models can be produced with 3-dimensional (3D) printing, but whether these models can offer optimal haptic feedback for simulating implant surgery is unknown., Purpose: The purpose of this trial was to compare the haptic feedback of different 3D printed models for simulating dental implant surgery., Material and Methods: A cone beam computed tomography image of a 60-year-old man with a partially edentulous mandible was manipulated to segment the mandible and isolated from the rest of the scan. Three-dimensional models were printed with 6 different printers and materials: material jetting-based printer (MJ, acrylic-based resin); digital light processing-based printer (DLP, acrylic-based resin); fused filament fabrication-based printer (FFF1, polycarbonate filament; FFF2, polylactic acid filament); stereolithography-based printer (SLA, acrylic-based resin); and selective laser sintering-based printer (SLS, polyamide filament). Five experienced maxillofacial surgeons performed a simulated implant surgery on the models. A 5-point Likert scale questionnaire was established to assess the haptic feedback. The Friedman test and cumulative logit models were applied to evaluate differences among the models (α=.05)., Results: The median score for drilling perception and implant insertion was highest for the MJ-based model and lowest for the SLS-based model. In relation to the drill chips, a median score of ≥3 was observed for all models. The score for corticotrabecular transition was highest for the MJ-based model and lowest for the FFF2-based model. Overall, the MJ-based model offered the highest score compared with the other models., Conclusions: The 3D printed model with MJ technology and acrylic-based resin provided the best haptic feedback for performing implant surgery. However, none of the models were able to completely replicate the haptic perception of real bone., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

61. "Braking bad": The influence of haptic feedback and tram driver experience on emergency braking performance.

Author

Callari TC, Moody L, Mortimer M, Stefan H, Horan B, and Birrell S

Subjects

Humans, Feedback, Haptic Technology, Motor Vehicles, Accidents, Traffic, Automobile Driving

Abstract

Trams are experiencing a resurgence with worldwide network expansion driven by the need for sustainable and efficient cities. Trams often operate in shared or mixed-traffic environments, which raise safety concerns, particularly in hazardous situations. This paper adopts an international, mixed-methods approach, conducted through two interconnected studies in Melbourne (Australia) and Birmingham (UK). The first study involved qualitative interviews, while the second was an experimental study involving a virtual reality (VR) simulator and haptic master controller (i.e., speed lever). In tram operations, master controllers play a critical role in ensuring a smooth ride, which directly influences passenger safety and comfort. The objective was to understand how a master control system, enhanced with additional haptic feedback, could improve tram driver braking performance and perceptions in safety-critical scenarios. Interview results indicate that the use of the emergency brake is considered the final or ultimate choice by drivers, and their driving experience is a moderating factor in limiting its application. Combined with the experimental results, this paper highlights how implementing haptic feedback within a master controller can reduce the performance disparity between novice and experienced tram drivers., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

62. Influence of a Capsular Tension Ring on Capsular Bag Behavior of a Plate Haptic Intraocular Lens: An Intraindividual Randomized Trial.

Author

Schartmüller D, Röggla V, Schwarzenbacher L, Meyer EL, Abela-Formanek C, Leydolt C, and Menapace R

Subjects

Humans, Lens Implantation, Intraocular methods, Haptic Technology, Phacoemulsification methods, Lenses, Intraocular, Lens Capsule, Crystalline surgery, Cataract

Abstract

Purpose: To evaluate the influence of a capsular tension ring (CTR) on rotational stability, decentration, tilt, and axial stability of an 11.0-mm plate haptic intraocular lens (IOL)., Design: Intraindividual, randomized, double-masked, controlled clinical trial., Participants: Patients scheduled for sequential same-day bilateral cataract surgery., Methods: All patients were randomized to receive a CTR and a plate haptic IOL in one eye and a plate haptic IOL in the fellow eye only. Intraocular lens axis assessment was performed at the end of surgery, 1 hour, 1 week, 1 month, and 6 months using a high-precision evaluation method. Decentration and tilt of the crystalline and pseudophakic lenses were assessed before surgery and at 1 week and 6 months using an anterior segment OCT., Main Outcome Measures: Rotational stability from the end of surgery to 6 months and at all follow-up visits, decentration and tilt at 6 months, and differences in axial shift between 1 week and 6 months., Results: One hundred thirty eyes of 65 patients were included in the study. Absolute rotation from the end of surgery to 6 months was 2.8 ± 3.9° and 3.2 ± 5.3° for the CTR and control groups, respectively (P = 0.613). Intraocular lens decentration and IOL tilt at 6 months were 0.29 ± 0.1 mm and 0.24 ± 0.1 mm and 6.7 ± 2.8° and 5.6 ± 1.6° for the CTR and control groups, respectively (P = 0.058; P < 0.01). A posterior IOL shift of 0.31 ± 0.31 mm and 0.19 ± 0.14 mm was observed in the CTR and control groups, respectively., Conclusions: Concomitant implantation of a CTR and a plate haptic IOL did not improve the overall rotational stability of the IOL compared with the control group. Against expectations, higher values of decentration, tilt, and axial shift were observed in the CTR group. The simultaneous use of a CTR and a plate haptic IOL in the absence of zonular weakness at the time of cataract surgery should be considered with caution., Financial Disclosure(s): Proprietary or commercial disclosure may be found in the Footnotes and Disclosures at the end of this article., (Copyright © 2023 American Academy of Ophthalmology. Published by Elsevier Inc. All rights reserved.)

Published

2024

63. Validation of a Virtual Simulator With Haptic Feedback for Endotracheal Intubation Training.

Author

Ryason A, Xia Z, Jackson C, Wong VT, Li H, De S, and Jones SB

Subjects

Humans, Feedback, Computer Simulation, Learning Curve, Clinical Competence, Haptic Technology, Intubation, Intratracheal

Abstract

Introduction: Endotracheal intubation (ETI) is a procedure that varies in difficulty because of patient characteristics and clinical conditions. Existing physical simulators do not encompass these variations. The Virtual Airway Skills Trainer for Endotracheal Intubation (VAST-ETI) was developed to provide different patient characteristics and high-fidelity haptic feedback to improve training., Methods: We demonstrate the effectiveness of VAST-ETI as a training and evaluation tool for ETI. Construct validation was evaluated by scoring the performance of experts ( N = 15) and novices ( N = 15) on the simulator to ensure its ability to distinguish technical proficiency. Convergent and predictive validity were evaluated by performing a learning curve study, in which a group of novices ( N = 7) were trained for 2 weeks using VAST-ETI and then compared with a control group ( N = 9)., Results: The VAST-ETI was able to distinguish between expert and novice based on mean simulator scores ( t [88] = -6.61, P < 0.0005). When used during repeated practice, individuals demonstrated a significant increase in their score on VAST-ETI over the learning period ( F [11,220] = 7206, P < 0.001); however when compared with a control group, there was not a significant interaction effect on the simulator score. There was a significant difference between the simulator-trained and control groups ( t [12.85] = -2.258, P = 0.042) when tested in the operating room., Conclusions: Our results demonstrate the effectiveness of virtual simulation with haptic feedback for assessing performance and training of ETI. The simulator was not able to differentiate performance between more experienced trainees and experts because of limits in simulator difficulty., Competing Interests: The authors declare no conflict of interest., (Copyright © 2023 Society for Simulation in Healthcare.)

Published

2024

64. Comparative analysis of outcomes of two (popular) techniques of haptic exteriorization in scleral fixation intra-ocular lens surgery - A retrospective study.

Author

Baskaran P, Srinivasan K, Govindaraj I, Rajendran A, Rajamani A, Mahalingam M, and Ramakrishnan S

Subjects

Humans, Retrospective Studies, Haptic Technology, Visual Acuity, Sclera surgery, Suture Techniques, Lens Implantation, Intraocular methods, Lenses, Intraocular

Abstract

Purpose: To compare the visual outcomes and complication rates between the extra-ocular needle-guided haptic insertion technique (XNIT) and the conventional handshake (HS) technique of scleral fixation intra-ocular lens (SFIOL)., Methods: In this retrospective study, we retrieved data of those patients who had undergone SFIOL surgery from January 2018 to May 2022 at our institute for aphakia following either a complicated cataract surgery or an ocular trauma and had a minimum follow-up of 3 months., Results: Of the 156 eyes, the HS technique was done in 80 eyes and the remaining 76 eyes with XNIT. At 3 months follow-up visit, there was no significant difference in the median best corrected visual acuity (BCVA) ( P = 0.988) and uncorrected visual acuity (UCVA) ( P = 0.765) between the two techniques. There was no statistically significant difference between pre-operative median BCVA and post-operative UCVA in XNIT ( P = 0.961) and the HS technique ( P = 0.831) at 3 months follow-up visit. The complication rates between the two techniques were minimal and comparable. The most common post-operative complication was corneal edema. The incidence of cystoid macular edema was slightly more in the XNIT group but not statistically significant ( P = 0.05). Two patients in the HS group developed retinal detachment, which settled after repeat surgery., Conclusion: The newer XNIT technique was found to be as safe and effective as compared to the conventional HS technique., (Copyright © 2024 Copyright: © 2024 Indian Journal of Ophthalmology.)

Published

2024

65. Robot-Assisted and Haptic-Guided Endodontic Surgery: A Case Report.

Author

Isufi A, Hsu TY, and Chogle S

Subjects

Humans, Root Canal Therapy methods, Haptic Technology, Bicuspid diagnostic imaging, Bicuspid surgery, Cone-Beam Computed Tomography, Robotics, Endodontics methods

Abstract

There has been a significant increase in robot-assisted dental procedures in the past decade, particularly in the area of robot-assisted implant placement. The objective of this case report was to assess the initial use of the Yomi Robot's assistance and haptic guidance during endodontic microsurgery. The robot was used during the osteotomy and root-end resection of the first and second upper left premolars. The report aims to inform clinicians of the initial implementation of this cutting-edge technology in endodontics and its potential to enhance endodontic microsurgery. The Yomi Robot was used in performing osteotomy and root-end resection during apical surgery in a patient presenting with symptomatic upper left first and second premolars. The treatment procedure was decided after clinical examination, chart data, and radiographic examinations, which showed periapical lesions on both premolars, taking into consideration the failed endodontic retreatment on the first premolar, the post and ceramic coronal restorations on both teeth, and the desire of the patient to save them. The Yomi Robot system provides auditory, visual, and physical guidance to clinicians during surgery while using a cone-beam computed tomography scan for precision planning with greater accuracy and minimized potential for human error. Further studies are needed to prepare a protocol for robotic-guided procedures in endodontics., (Copyright © 2024 American Association of Endodontists. Published by Elsevier Inc. All rights reserved.)

Published

2024

66. Flapless dental implant surgery enabled by haptic robotic guidance: A case report.

Author

Ali M

Subjects

Humans, Dental Implantation, Endosseous methods, Haptic Technology, Maxilla diagnostic imaging, Maxilla surgery, Dental Implants, Surgery, Computer-Assisted methods, Tooth

Abstract

This case report presents the use of haptic robotic technology in one patient with six implants placed in the maxilla and five implants in the lower mandible with the goal of individual single implant supported crowns to be placed over each implant after 6 months. All implants were placed using a flapless technique, with one immediate implant placement after extraction. All implants were placed with a high degree of accuracy relative to the pre-operative plan as determined by post-op CBCT analysis with an average angular deviation of 2.58° and positional deviations at the coronal and apical aspects of the implant around 1 mm (0.93 and 1.06 mm, respectively). Total surgical time of less than 2 h. Haptic robotics physically guides the location, orientation, and depth of the tools during both drilling and implantation and thus allows for accurate placement as well as the intra-operative flexibility to change the plan as necessary while providing excellent visualization and irrigation. This robotic technology provides a treatment that focuses on accuracy and safety providing the best chance at excellent surgical outcomes for the patient., (© 2023 The Authors. Clinical Implant Dentistry and Related Research published by Wiley Periodicals LLC.)

Published

2024

67. Modeling Human Steering Behavior in Haptic Shared Control of Autonomy-Enabled Unmanned Ground Vehicles.

Author

Li C, Cole M, Jayakumar P, and Ersal T

Subjects

Humans, Computer Simulation, Man-Machine Systems, Haptic Technology, Automobile Driving

Abstract

Objective: A human steering model for teleoperated driving is extended to capture the human steering behavior in haptic shared control of autonomy-enabled Unmanned Ground Vehicles (UGVs)., Background: Prior studies presented human steering models for teleoperation of a passenger-sized Unmanned Ground Vehicle, where a human is fully in charge of driving. However, these models are not applicable when a human needs to interact with autonomy in haptic shared control of autonomy-enabled UGVs. How a human operator reacts to the presence of autonomy needs to be studied and mathematically encapsulated in a module to capture the collaboration between human and autonomy., Method: Human subject tests are conducted to collect data in haptic shared control for model development and validation. The ACT-R architecture and two-point steering model used in the previous literature are adopted to predict the operator's desired steering angle. A torque conversion module is developed to convert the steering command from the ACT-R model to human torque input, thus enabling haptic shared control with autonomy. A parameterization strategy is described to find the set of model parameters that optimize the haptic shared control performance in terms of minimum average lane keeping error (ALKE)., Results: The model predicts the minimum ALKE human subjects achieve in shared control., Conclusions: The extended model can successfully predict the best haptic shared control performance as measured by ALKE., Application: This model can be used in place of human operators, enabling fully simulation-based engineering, in the development and evaluation of haptic shared control technologies for autonomy-enabled UGVs, including control negotiation strategies and autonomy capabilities.

Published

2024

68. Modality-Independent Effect of Gravity in Shaping the Internal Representation of 3D Space for Visual and Haptic Object Perception.

Author

Morfoisse T, Herrera Altamira G, Angelini L, Clément G, Beraneck M, McIntyre J, and Tagliabue M

Subjects

Humans, Male, Female, Visual Perception, Haptic Technology, Cognition, Space Perception, Vestibule, Labyrinth, Touch Perception

Abstract

Visual and haptic perceptions of 3D shape are plagued by distortions, which are influenced by nonvisual factors, such as gravitational vestibular signals. Whether gravity acts directly on the visual or haptic systems or at a higher, modality-independent level of information processing remains unknown. To test these hypotheses, we examined visual and haptic 3D shape perception by asking male and female human subjects to perform a "squaring" task in upright and supine postures and in microgravity. Subjects adjusted one edge of a 3D object to match the length of another in each of the three canonical reference planes, and we recorded the matching errors to obtain a characterization of the perceived 3D shape. The results show opposing, body-centered patterns of errors for visual and haptic modalities, whose amplitudes are negatively correlated, suggesting that they arise in distinct, modality-specific representations that are nevertheless linked at some level. On the other hand, weightlessness significantly modulated both visual and haptic perceptual distortions in the same way, indicating a common, modality-independent origin for gravity's effects. Overall, our findings show a link between modality-specific visual and haptic perceptual distortions and demonstrate a role of gravity-related signals on a modality-independent internal representation of the body and peripersonal 3D space used to interpret incoming sensory inputs., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 the authors.)

Published

2024

69. Dislocation force of scleral flange-fixated intraocular lens haptics.

Author

Stunf Pukl S, Kronschläger M, Ruiss M, Blouin S, Akcan ER, and Findl O

Subjects

Humans, Polymethyl Methacrylate, Sclera surgery, Haptic Technology, Lenses, Intraocular, Fluorocarbon Polymers, Polyvinyls

Abstract

Purpose: To measure the dislocation forces in relation to haptic material, flange size and needle used., Setting: Hanusch Hospital, Vienna, Austria., Design: Laboratory Investigation., Methods, Main Outcome Measures: 30 G (gauge) thin wall and 27 G standard needles were used for a 2 mm tangential scleral tunnel in combination with different PVDF (polyvinylidene fluoride) and PMMA (polymethylmethacrylate haptics). Flanges were created by heating 1 mm of the haptic end, non-forceps assisted in PVDF and forceps assisted in PMMA haptics. The dislocation force was measured in non-preserved cadaver sclera using a tensiometer device., Results: PVDF flanges achieved were of a mushroom-like shape and PMMA flanges were of a conic shape. For 30 G needle tunnels the dislocation forces for PVDF and PMMA haptic flanges were 1.58 ± 0.68 N (n = 10) and 0.70 ± 0.14 N (n = 9) (p = 0.003) respectively. For 27 G needle tunnels the dislocation forces for PVDF and PMMA haptic flanges were 0.31 ± 0.35 N (n = 3) and 0.0 N (n = 4), respectively. The flange size correlated with the occurring dislocation force in experiments with 30 G needle tunnels (r = 0.92), when flanges were bigger than 384 micrometres., Conclusions: The highest dislocation forces were found for PVDF haptic flanges and their characteristic mushroom-like shape for 30 G thin wall needle scleral tunnels. Forceps assisted flange creation in PMMA haptics did not compensate the disadvantage of PMMA haptics with their characteristic conic shape flange., (© 2024. The Author(s).)

Published

2024

70. [Interactive Virtual Simulation with Haptics for Neurosurgery].

Author

Oishi M and Ogura R

Subjects

Humans, Haptic Technology, Neurosurgical Procedures methods, Neurosurgery, Meningioma diagnostic imaging, Meningioma surgery, Skull Base Neoplasms surgery, Meningeal Neoplasms surgery

Abstract

We established a unique pre-surgical simulation method by applying interactive virtual simulation(IVS)using multi-fusion three-dimensional imaging data, presenting high-quality visualization of microsurgical anatomies. Our IVS provided a realistic environment for imitating surgical manipulations, such as dissecting bones, retracting brain tissues, and removing tumors, with tactile and kinesthetic sensations delivered through a specific haptic device. The great advantage of our IVS was in deciding the most appropriate craniotomy and bone resection to create the optimal surgical window and obtain the best working space with a thorough understanding of the lesion-bone relationship. Particularly for skull-base tumors, tailoring the procedures to individual patients for craniotomy and bone resection was sufficiently achieved using our IVS. In cases of large skull base meningiomas, our IVS was also helpful preoperatively regarding tumors, as several compartments were achievable in every potentially usable surgical direction. Additionally, the non-risky realistic microsurgical environments of the IVS provided improvement in the microsurgical senses and skills of young trainees through the repetition of surgical tasks. Finally, our presurgical IVS simulation method provided a realistic environment for practicing microsurgical procedures virtually and enabled us to ascertain the complex microsurgical anatomy, determine optimal surgical strategies, and efficiently educate neurosurgical trainees.

Published

2024

71. Risk factors associated with haptic malposition in eyes implanted with implantable collamer lenses.

Author

Chang W, Niu L, Zhou X, Wang X, Yu Z, and Qian Y

Subjects

Humans, Haptic Technology, Prospective Studies, Lens Implantation, Intraocular, Visual Acuity, China, Iris, Risk Factors, Retrospective Studies, Myopia surgery, Phakic Intraocular Lenses

Abstract

Purpose: To examine the risk factors for haptic malposition in eyes with implantable collamer lens (ICL)., Setting: Eye and ENT Hospital, Fudan University, Shanghai, China., Design: Prospective nonrandomized observational study., Methods: This study included 134 (77.9%) of 172 initially enrolled patients who underwent ICL implantation and completed a 1-year follow-up. The extent of haptics present in the ciliary sulcus (ICS) was measured. Patients were categorized based on ICS count (0 to 4). The position of the haptics was quantified as the distance between the iris root and the terminal tip of ICL haptics (iris root to haptic tip, IRH). The related factors to the ICS count and its correlation with the central vault were analyzed., Results: ICS distribution was 0 ICS in 19 eyes (14.2%), 1 in 22 eyes (16.4%), 2 in 32 eyes (23.9%), 3 in 29 eyes (21.6%), and 4 in 32 eyes (23.9%). Parameters like maximum ciliary body thickness (CBTmax, P = .008), iris-ciliary process distance (ICPD, P < .001), and ciliary process length ( P = .034) varied significantly across ICS groups. A multiple linear regression analysis revealed that the iris-ciliary angle ( P = .006), CBTmax ( P = .007), the distance between the sulcus-to-sulcus plane and the anterior crystalline lens surface (STSL, P = .035), and ICL size ( P = .015) were significantly associated with IRH. Spherical equivalents ( P = .042), STSL ( P = .001), and ICS count ( P = .020) significantly correlated with the central vault., Conclusions: Shortened ciliary process is a primary risk for haptic malposition. The ICS count significantly relates to the central vault., (Copyright © 2023 The Author(s). Published by Wolters Kluwer Health, Inc. on behalf of ASCRS and ESCRS.)

Published

2024

72. Enhancement of sense of ownership using virtual and haptic feedback.

Author

Altukhaim S, George D, Nagaratnam K, Kondo T, and Hayashi Y

Subjects

Humans, Female, Male, Feedback, Hand, Upper Extremity, Haptic Technology, Ownership

Abstract

Accomplishing motor function requires multimodal information, such as visual and haptic feedback, which induces a sense of ownership (SoO) over one's own body part. In this study, we developed a visual-haptic human machine interface that combines three different types of feedback (visual, haptic, and kinesthetic) in the context of passive hand-grasping motion and aimed to generate SoO over a virtual hand. We tested two conditions, both conditions the three set of feedback were synchronous, the first condition was in-phase, and the second condition was in antiphase. In both conditions, we utilized passive visual feedback (pre-recorded video of a real hand displayed), haptic feedback (balloon inflated and deflated), and kinesthetic feedback (finger movement following the balloon curvature). To quantify the SoO, the participants' reaction time was measured in response to a sense of threat. We found that most participants had a shorter reaction time under anti-phase condition, indicating that synchronous anti-phase of the multimodal system was better than in-phase condition for inducing a SoO of the virtual hand. We conclude that stronger haptic feedback has a key role in the SoO in accordance with visual information. Because the virtual hand is closing and the high pressure from the balloon against the hand creates the sensation of grasping and closing the hand, it appeared as though the person was closing his/her hand at the perceptual level., (© 2024. The Author(s).)

Published

2024

73. Impact of Haptic Cues and an Active Ankle Exoskeleton on Gait Characteristics.

Author

Wu MI, Stegall P, Siu HC, and Stirling L

Subjects

Humans, Cues, Haptic Technology, Biomechanical Phenomena, Gait, Walking, Ankle, Exoskeleton Device

Abstract

Objective: This study examined the interaction of gait-synchronized vibrotactile cues with an active ankle exoskeleton that provides plantarflexion assistance., Background: An exoskeleton that augments gait may support collaboration through feedback to the user about the state of the exoskeleton or characteristics of the task., Methods: Participants ( N = 16) were provided combinations of torque assistance and vibrotactile cues at pre-specified time points in late swing and early stance while walking on a self-paced treadmill. Participants were either given explicit instructions ( N = 8) or were allowed to freely interpret (N=8) how to coordinate with cues., Results: For the free interpretation group, the data support an 8% increase in stride length and 14% increase in speed with exoskeleton torque across cue timing, as well as a 5% increase in stride length and 7% increase in speed with only vibrotactile cues. When given explicit instructions, participants modulated speed according to cue timing-increasing speed by 17% at cues in late swing and decreasing speed 11% at cues in early stance compared to no cue when exoskeleton torque was off. When torque was on, participants with explicit instructions had reduced changes in speed., Conclusion: These findings support that the presence of torque mitigates how cues were used and highlights the importance of explicit instructions for haptic cuing. Interpreting cues while walking with an exoskeleton may increase cognitive load, influencing overall human-exoskeleton performance for novice users., Application: Interactions between haptic feedback and exoskeleton use during gait can inform future feedback designs to support coordination between users and exoskeletons.

Published

2024

74. Planning lane changes using advance visual and haptic information.

Author

Frissen I and Mars F

Subjects

Humans, Haptic Technology, Reaction Time, Cues, Movement, Automobile Driving psychology

Abstract

Taking a motor planning perspective, this study investigates whether haptic force cues displayed on the steering wheel are more effective than visual cues in signaling the direction of an upcoming lane change. Licensed drivers drove in a fixed-base driving simulator equipped with an active steering system for realistic force feedback. They were instructed to make lane changes upon registering a directional cue. Cues were delivered according to the movement precuing technique employing a pair of precues and imperative cues which could be either visual, haptic, or crossmodal (a visual precue with a haptic imperative cue, and vice versa). The main dependent variable was response time. Additional analyses were conducted on steering wheel angle profiles and the rate of initial steering errors. Conditions with a haptic imperative cue produced considerably faster responses than conditions with a visual imperative cue, irrespective of the precue modality. Valid and invalid precues produced the typical gains and costs, with one exception. There appeared to be little cost in response time or initial steering errors associated with invalid cueing when both cues were haptic. The results are consistent with the hypothesis that imperative haptic cues facilitate action selection while visual stimuli require additional time-consuming cognitive processing., (© 2023. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

75. Comparison of clinical outcome after implantation of two toric intraocular lenses with different haptic type: a prospective randomized controlled trial.

Author

Sun J, Bai H, Cui W, and Wu X

Subjects

Humans, Haptic Technology, Prospective Studies, Cornea, Astigmatism surgery, Lenses, Intraocular, Corneal Diseases

Abstract

Objective: To study the effect of astigmatism correction, rotational stability, and related factors of two different haptic type toric intraocular lenses., Methods: A prospective, randomized, controlled trial. Cataract patients with preoperative corneal astigmatism of > 1 D were randomly implanted with C-loop haptic toric IOL (AcrySof-toric IOL) (group A) or plate-haptic toric IOL (AT TORBI 709 M IOL) (group B). The residual astigmatism, intraocular lens rotation, and visual quality were determined and compared between the two groups at 3 months after surgery., Results: Seventy-nine eyes were included in this study, including 40 eyes in the group A and 39 eyes in the group B. No significant difference in preoperative visual acuity, intraocular pressure, and ophthalmic biological parameters was found between the two groups. There was no significant difference in residual astigmatism between the two groups at 3 months after surgery (P > 0.05). The rotation degree in the group A was 3.85 ± 2.92°, the rotation degree in the group B was 2.33 ± 2.31°, and a significant difference in intraocular lens rotation was identified between the two groups (P < 0.05). Upon exploring the rotation-related factors of the two different haptic type toric intraocular lenses, the rotation after implanting C-loop haptic toric IOL was positively correlated with axial length (Pearson r = 0.522, P = 0.01) and corneal white-to-white distance (Pearson correlation analysis r = 0.356, P = 0.024)., Conclusions: The two different haptic type toric intraocular lenses effectively corrected regular corneal astigmatism and provided a good rotational stability after surgery. But the stability of plate-haptic toric IOL was better than that of C-loop haptic toric IOL. The rotational stability of C-loop haptic toric IOL was often related to axial length and corneal white-to-white distance., (© 2023. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

76. A force rendering model for virtual assembly of mechanical parts with clearance fits

Author

Wang, QingHui, Huang, Zhong-Dong, Li, JingRong, and Liu, Jia-Wu

Published

2018

77. Touching Virtual Humans: Haptic Responses Reveal the Emotional Impact of Affective Agents

Author

Ville Johannes Harjunen, Tuukka Ruotsalo, Michiel M. Spapé, Imtiaj Ahmed, Niklas Ravaja, Giulio Jacucci, Department of Computer Science, Facing Narcissism, Department of Psychology and Logopedics, Ubiquitous Interaction research group / Giulio Jacucci, and Helsinki Institute for Information Technology

Subjects

Modality (human–computer interaction), Physiology, 05 social sciences, Virtual agent, Virtual reality, 113 Computer and information sciences, Affect (psychology), Arousal, Affective interaction, Human-Computer Interaction, 0502 economics and business, Emotional expression, 050211 marketing, 0501 psychology and cognitive sciences, Haptic response, Valence (psychology), Psychology, 050107 human factors, Software, Haptic technology, Cognitive psychology

Abstract

Interpersonal touch is critical for social-emotional development and presents a powerful modality for communicating emotions. Virtual agents of the future could capitalize on touch to establish social bonds with humans and facilitate cooperation in virtual reality (VR). We studied whether the emotional expression of a virtual agent would affect the way humans touch the agent. Participants were asked to hold a pressure-sensing tube presented as the agent's arm in VR. Upon seeing the agent's emotional expression change, participants briefly squeezed the arm. The effect of emotional expressions on affective state was measured using self-reported valence and arousal as well as physiology-based indices. Onset, duration, and intensity of the squeeze were recorded to examine the haptic responses. Emotional expression of agents affected squeeze intensity and duration through changes in emotional perception and experience. Haptic responses may thus provide an implicit measure of persons' experience towards their virtual companion.

Published

2023

78. SIMPLE REFIXATION OF A DISLOCATED HAPTIC OF FLANGED INTRAOCULAR LENS USING A 25-GAUGE NEEDLE

Author

Sukhum Silpa-archa

Subjects

Ophthalmology, Optics, business.industry, Simple (abstract algebra), medicine.medical_treatment, Gauge (instrument), Refixation, medicine, Intraocular lens, General Medicine, business, Haptic technology

Published

2023

79. Toolkit for exploring ethical aspects of digital social and affective touch interactions

Author

A Dima, Laura, Jung, Merel M., Golmohammadi, Lili, Huisman, Gijs, Lancel, Karen, Keizer, Anouk, Parisi, David, van Erp, Jan, A Dima, Laura, Jung, Merel M., Golmohammadi, Lili, Huisman, Gijs, Lancel, Karen, Keizer, Anouk, Parisi, David, and van Erp, Jan

Abstract

In this hands-on demonstration, people are invited to use a newly developed toolkit to scrutinize their attitude and preferences towards digital social and affective touch interactions.

Published

2023

80. SereniSleeve - Designing Shape Memory Based Wearables for Anxiety Modulation

Author

Kim, June (author) and Kim, June (author)

Abstract

Anxiety is a natural “fight-or-flight” response that everybody experiences to perceived stress or threat. Even though it is a natural response, some individuals struggle with managing their anxiety levels in a healthy manner. Prolonged exposure to high anxiety states can lead to clinical anxiety disorders that negatively impact the quality of life, thus early interventions to reduce anxiety levels can help prevent the development of clinical level anxiety. Even nonclinical individuals can also suffer from periods of heightened anxiety state, so anyone can benefit from additional guidance with anxiety modulation. This graduation project aims to create a wearable garment that helps with daily levels of anxiety modulation in a non-clinical setting by providing warmth and pressure sensations typically associated with Deep Touch Pressure (DTP). DTP is a form of tactile sensory input that is provided by holding, stroking, hugging and squeezing, which has been proven to elicit feelings of safety, relaxation, and comfort. Although there are some commercially available DTP wearable products typically in the form of a vest, they are often heavy, uncomfortable, or indiscreet as the DTP sensations are provided by additional weights or inflatables with hand-operated pumps. Since they are difficult to conceal, wearing those commercial DTP vests can attract unwanted attention from nearby strangers and further aggravate anxiousness. Instead, DTP sensations can be applied to the body in a noiseless, lightweight, and discreet manner by utilizing shape memory alloy (SMA) actuators in wearable garments. The insights that formed the groundwork for this project was gathered through literature review in a wide variety of topics including haptic technology, affect regulation, and SMA. Deeper understanding of the intricate nuances involved with anxiety modulation were gained through self-reflection and introspection as part of the autobiographical design method. Although, Integrated Product Design

Published

2023

81. Mediated Social Touch With Mobile Devices: A Review of Designs and Evaluations

Author

Wei, Qianhui, Li, Min, Hu, Jun, Wei, Qianhui, Li, Min, and Hu, Jun

Abstract

Background: Mediated social touch has been widely studied for remote affective communication in the field of humancomputer interaction. Goal: We conducted this literature review to comprehensively understand the state of the art of the designs and evaluations of mediated social touch for mobile devices. Method: We selected 52 articles based on related keywords from four main digital libraries, i.e., ACM, IEEE, Springer, and Scopus. Results: We summarized from these articles how mediated social touch signal is designed, prototyped, and evaluated, and what the main research findings are. Based on the analysis, we identified opportunities for later work.

Published

2023

82. Accuracy of haptic robotic guidance of dental implant surgery for completely edentulous arches

Author

Scotty L. Bolding and Uday N. Reebye

Subjects

Cone beam computed tomography, medicine.medical_treatment, Crown (dentistry), 03 medical and health sciences, 0302 clinical medicine, Robotic Surgical Procedures, medicine, Humans, Prospective Studies, Dental implant, Haptic technology, Dental Implants, Orthodontics, business.industry, Dental Implantation, Endosseous, 030206 dentistry, Cone-Beam Computed Tomography, Surgery, Computer-Assisted, Haptic Technology, Maxilla, Computer-Aided Design, Dental Prosthesis, Implant-Supported, Implant, Mouth, Edentulous, Oral Surgery, Fiducial marker, Splint (medicine), business

Abstract

Statement of problem The accuracy of single implant placement is critical, as errors may cause problems with vital structures intraoperatively, as well as postoperatively with the prostheses. These issues may be exacerbated in complete-arch edentulous treatments requiring relative accuracy among multiple implants, particularly with prefabricated prosthetic structures. Purpose The purpose of this clinical study was to determine the accuracy of dental implant placement by using haptic robotic guidance in completely edentulous participants. Material and methods In a prospective single-arm clinical study, 5 qualified participants elected to receive dental implants placed by using haptic robotic guidance to restore either the maxillary or mandibular arch, or both, with complete-arch implant-supported prostheses. Three dual-arch participants and 2 single-arch participants resulted in 38 endosteal dental implants being placed. A virtual preoperative restorative and surgical plan was created before surgery. This plan was matched to the surgical workspace on the day of surgery by using a bone-mounted fiducial splint fabricated from a cone beam computed tomography (CBCT) scan. Intraoperatively, the surgeons maneuvered a handpiece attached to the robotic guidance arm, osteotomies were created with a haptically constrained handpiece, and the implants were placed with 3-dimensional haptic constraints as per the virtual plan. Postoperative CBCT scans allowed the evaluation of the deviations of the actual implant placement relative to the plan. Results Twenty-three implants were placed in the mandible and 15 in the maxilla. The mean ±standard deviation global angular deviation was 2.56 ±1.48 degrees, while the crown of the placed implant showed a deviation from the plan of 1.04 ±0.70 mm and the apex of 0.95 ±0.73 mm. The signed depth deviation was 0.42 ±0.46 mm proud. No adverse events were reported. Conclusions This clinical series for treating completely edentulous patients by using haptic robotic guidance was found to be safe and accurate. While further longer-term clinical studies are necessary to measure outcomes and to assess differences as compared with nonrobotic implementations, haptic robotic preparation appears to confer additional intraoperative advantages over other techniques for treating completely edentulous arches.

Published

2022

83. An Offline-Merge-Online Robot Teaching Method Based on Natural Human-Robot Interaction and Visual-Aid Algorithm

Author

Gengcheng Yao, Peter X. Liu, Chunquan Li, and Guanglong Du

Subjects

Operator (computer programming), Control and Systems Engineering, Computer science, Interface (computing), Teaching method, Robot, Electrical and Electronic Engineering, Algorithm, Human–robot interaction, Motion (physics), Computer Science Applications, Gesture, Haptic technology

Abstract

This article proposes an offline-merge-online robot teaching method (OMORTM). Specifically, a virtual-real fusion interactive interface (VRFII) is first developed by projecting a virtual robot into the real scene with an augmented-reality (AR) device, aiming to implement offline teaching. Second, a visual-aid algorithm (VAA) is proposed to improve offline teaching accuracy. Third, a gesture and speech teaching fusion algorithm (GSTA) with the fingertip tactile force feedback is developed to obtain the natural teaching pattern and improve the interactive accuracy of teaching the real or virtual robot. More specifically, through the VRFII, the operator can use the GSTA and the VAA to teach the virtual robot naturally and safely, and then the real robot reproduces the motion of the virtual robot. Therefore, OMORTM enables the teaching results to be quickly verified while ensuring the operator's safety and avoiding damage to the robot or workpiece. A series of experiments were conducted to validate the practicality and effectiveness of OMORTM. The results show that by effectively combining the offline and online, OMORTM provides accurate robotic teaching processes, suitable for nonprofessionals.

Published

2022

84. Hand-Held Haptic Navigation Devices for Actual Walking

Author

Myrthe Plaisier, Tessa Junggeburth, Astrid Kappers, Max Fa Si Oen, Human Technology Interaction, Control Systems Technology, Dynamics and Control, and Industrial Engineering and Innovation Sciences

Subjects

deafblind, hand-held, Location awareness, blind, Walking, Haptic interfaces, Navigation, Computer Science Applications, Human-Computer Interaction, Touch Perception, outdoors, Global Positioning System, Haptic Technology, Geographic Information Systems, Legged locomotion, Humans, Buildings, indoors, hand-worn, Visualization

Abstract

In this survey, we give an overview of hand-held haptic navigation devices specifically designed for and tested with pedestrians. We distinguish devices for indoor use and for outdoor use as the implementation is usually quite different. Outdoor devices make use of Global Positioning Systems (GPS) tracking built-in in smartphones; indoor devices use a variety of sensors, and tracking and localization systems and these are usually restricted to a small part of a building. Overall, the high success rates reported in the studies show that vibrotactile stimulation via a hand-held user interface is suitable for navigation instructions, as in all experiments (almost) all participants reached their goal. An issue for several of the indoor devices is that walking speeds were (much) lower than normal walking speeds and path efficiency was relatively low. However, these issues might be overcome with some training as in most studies there was hardly any practice time. Several of the outdoor devices seem quite close to taking the last step before commercial use. In the Discussion, we evaluate the suitability of the devices for persons with visual and/or hearing impairments. Especially devices that provide very specific instructions, such as, ‘go straight’ or ‘go right’, seem valuable for this population.

Published

2022

85. Sensorized Reconfigurable Soft Robotic Gripper System for Automated Food Handling

Author

Yee Seng Teoh, Zhuangjian Liu, Haicheng Yao, Jin Huat Low, Pablo Valdivia y Alvarado, I-Ming Chen, Si Li, Yadan Zeng, Chen-Hua Yeow, Benjamin C. K. Tee, Jun Liu, Qian Qian Han, and Phone May Khin

Subjects

Computer science, Orientation (computer vision), business.industry, SCOOP, Cognitive neuroscience of visual object recognition, Soft robotics, Computer Science Applications, Control and Systems Engineering, Control system, Benchmark (computing), Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business, computer, Tactile sensor, computer.programming_language, Haptic technology

Abstract

This article presents a versatile soft robotic gripper system whereby its fingers can be reconfigured into different poses such as scoop, pinch, and claw. This allows the gripper to efficiently and safely handle food samples of different shapes, sizes and stiffness such as uncooked tofu and broccoli floret. The 3D-printed fingers were tested to last up to 25 000 cycles without significant changes in the curvature profile and force output profile. A benchmark experiment was conducted to evaluate the performance of the gripper and state-of-the-art gripping solutions. Capability of versatile soft gripper was optimized by integrating vision and tactile sensing facilities. An object recognition system was developed to identify food samples such as potato, broccoli, and sausage. Position and orientation of food samples were identified and pick-and-place pathway was optimized to achieve the best gripping performance. Flexible tactile sensors were integrated into soft fingers and closed-loop force feedback control system was developed. This allowed the gripper to automatically explore and select the most stable grip pose for different food samples. Integration of vision and force feedback system ensure that objects detected by the system would be firmly gripped. The reconfigurable soft robotic gripper system has been demonstrated to perform high-speed pick-and-place tasks (∼3 s per item) with object recognition system, making it a potential solution to food and grocery supply chain needs.

Published

2022

86. Bias Estimation and Gravity Compensation for Wrist-Mounted Force/Torque Sensor

Author

Ran Shi, Yunjiang Lou, and Yongqiang Yu

Subjects

Gravity (chemistry), Inertial frame of reference, Computer science, Control theory, Torque, Torque sensor, Electrical and Electronic Engineering, Rotation, Instrumentation, Contact force, Haptic technology, Compensation (engineering)

Abstract

Robot force-controlled task executions require an accurate perception of the contact force/torque. When a six-axis force/torque (F/T) sensor is attached to the robot wrist, the compensation precision is affected by many non-contact features, such as the end-effector gravity, inertial, centrifugal, Coriolis forces, and the mechanical errors of the sensor. However, it is complicated to identify all parameters at the same time. Some features will be ignored in practice applications, e.g., surface finishing, human-robot interaction, and haptic applications. In this paper, a novel end-effector gravity compensation method for the F/T sensor is proposed, which identifies the end-effector gravity, its center, and the biases (the rotation between the sensor and robot, the robot installation declination, the bias of sensor). Our key is the rotation calibration while the transformation between the F/T sensor and robot is unknown. Simulation and experimental results show that the proposed method works effectively. In a wrist-mounted F/T sensor system, compared to the previous limited method, the compensation error in common force control channel Fz by our method diminishes 1.0% of the end-effector gravity (i.e., 21.7% relative improvement).

Published

2022

87. “Through the looking glass: envisioning new library technologies” an experience you can feel: haptic technology

Author

Fernandez, Peter

Published

2017

88. Intrascleral haptic fixation for haptic exposure after Yamane technique

Author

Mohamed Ibrahime Asif, Rahul Kumar Bafna, Anirudh Kapoor, and Namrata Sharma

Subjects

Lenses, Intraocular, medicine.medical_specialty, genetic structures, business.industry, medicine.medical_treatment, Suture Techniques, Intraocular lens, General Medicine, Middle Aged, behavioral disciplines and activities, eye diseases, Sutureless Surgical Procedures, body regions, Fixation (surgical), Lens Implantation, Intraocular, Ophthalmology, medicine, Humans, sense organs, business, Sclera, Haptic technology

Abstract

A 55-year-old patient presented with exposure of both the haptics beyond the conjunctiva of the scleral fixated multipiece intraocular lens (IOL). Two diagonally opposite scleral pockets were created, and the exposed haptics was redirected and repositioned aseptically into these pockets to facilitate intrascleral fixation. Herein, we report a simple rescue method for management of exposed haptic after Yamane technique of scleral fixated IOL.

Published

2023

89. Toolkit for exploring ethical aspects of digital social and affective touch interactions

Subjects

Ethics, Toolkit, Social and affective touch, Haptic technology, Digital touch

Abstract

In this hands-on demonstration, people are invited to use a newly developed toolkit to scrutinize their attitude and preferences towards digital social and affective touch interactions.

Published

2023

90. Virtual touch: Liminal forms of touch between the sacred and the symbolic register

Author

Škorjanc, Tjaša and Komel, Mirt

Subjects

dotik, haptična tehnologija, liminal sacred, touch during the pandemic, touch, humanoid robot, lacanovska psihoanaliza, liminalno sveto, dotik med pandemijo, humanoidni robot, Lacanian psychoanalysis, udc:159.964:1(043.2), haptic technology

Abstract

V pričujočem besedilu analiziramo izbrane značilnosti hipertehnološke sodobnosti in zagovarjamo premiso, da se spričo slednjih človekov odnos do dotika nahaja v liminalnem stanju, v katerem vznikajo različne liminalne oblike dotika. Pričnemo z obravnavo teorij ključnih mislecev dotika, katerih sopostavitev nas pripelje do 10-členske definicije dotika. Ta (pri čemer se še zlasti naslanjamo na člen, ki dotik zastavlja kot hipni pretres ločitve na subjekt in objekt) nam v nadaljevanju omogoča misliti dotik kot zatik znotraj lacanovske označevalske verige oziroma kot izmuzljivi “objekt a”. Če preko Lacanovih in kasneje še Kristevinih psihoanalitskih nastavkov dotik pojmujemo kot Simbolno, torej kot mehanizem vznika subjekta, pa drugo plat dotika najdemo v učinku hipnega izkoraka iz Simbolnega. Tovrsten izkorak konceptualiziramo s pomočjo Bataillove razdelave “erotizma”. Zaradi ambivalentnosti, s stališča katere se dotik kaže kot tvorna in obenem destruktivna sila za človeškega subjekta, dotik razumemo kot instanco svetega. Z zastavitvijo dotika kot svetega ga zagovarjamo kot za človeka konstitutivno silo, katere skrajne premene sprožajo splošno družbeno stanje liminalnosti. Trdimo, da liminalne oblike dotika pomenijo instant prilagoditev na občo “krizo dotika”. V nadaljevanju podrobno analiziramo (1) ASMR, (2) dotik humanoidnega robota in (3) dotik med pandemijo. Naš namen je umestiti izbrane liminalne oblike dotika znotraj polarnega razmerja med svetim in simbolnim registrom. Ugotovimo, da je za liminalne oblike dotika značilno dvoumno prehajanje med dotikom (kot svetim in kot objektom a) in reprodukcijo verige označevalcev, ki uzakonjajo delovanje lacanovskega Simbolnega in vzpostavljajo razločbo na objekt in subjekt. In the text we analyse selected traits of the hypertech contemporaneity and argue that they push the human relationship with touch into a liminal state, bearing liminal forms of touch. We commence by contrasting touch theories from key thinkers, which leads to a ten-part definition of touch. The definition enables us to conceive touch as a disruption within the Lacanian chain of signifiers or the elusive “object a”. We turn to Lacan’s and Kristeva’s psychoanalytic postulates to operationalize touch as a mechanism of emergence of the Symbolic. We show that the momentary exit from the Symbolic represents an opposite dimension of touch. Bataille’s “eroticism” helps conceptualize such a temporary exit. Due to touch’s inherent ambivalence, which makes it both a productive as well as a destructive force for the subject, we understand it as an instance of the sacred. Therefore, a radical transformation of the concept of touch brings about a general state of liminality. We claim that liminal forms of touch imply an instant adaptation to the prevalent “crisis of touch”. We examine (1) ASMR, (2) touch of the humanoid robot, and (3) touch during the pandemic. Our intention is to place the selected liminal forms of touch within the polar relation between the sacred and the Symbolic. We find that liminal forms of touch are characterized by an ambivalent crossing between touch (as sacred and as “object a”) and the reproduction of the signifying chain, which ordains the functioning of the Lacanian Symbolic and establishes the distinction between the object and the subject.

Published

2023

91. HapticSOUND: An Interactive Learning Experience with a Digital Musical Instrument

Author

Mavridis, Christina Volioti, Apostolos Tsagaris, Dimitrios Trigkas, Theodoros Iliou, Menelaos N. Katsantonis, and Ioannis

Subjects

haptic technology, digital musical instrument, gesture recognition, sensorimotor learning

Abstract

In this paper, an interactive learning experience is proposed, aiming to involve museum visitors in a personalized experience of the transmittal of cultural knowledge in an active and creative way. The proposed system, called HapticSOUND, consists of three subsystems: (a) the Information, where visitors are informed about the traditional musical instruments; (b) the Entertainment, where visitors are entertained by playing serious games to virtually assemble traditional musical instruments by a set of 3D objects; and (c) the Interaction, where visitors interact with a digital musical instrument which is an exact 3D-printed replica of a traditional musical instrument, where cameras have been placed to capture user gestures and machine learning algorithms have been implemented for gesture recognition. The museum visitor can interact with the lifelike replica to tactilely and aurally explore the instrument’s abilities, producing sounds guided by the system and receiving real-time visual and audio feedback. Emphasis is given to the Interaction Subsystem, where a pilot study was conducted to evaluate the usability of the subsystem. Preliminary results were promising since the usability was satisfactory, indicating that it is an innovative approach that utilizes sensorimotor learning and machine learning techniques in the context of playing sounds based on real-time gesture and fingering recognition.

Published

2023

92. Human perception baseline for anticipating haptic greetings in human-robot interaction

Subjects

Greeting, Haptic technology, Social robots, Human perception

Abstract

Greeting is the hallmark example of social behavior inwhich touch occurs frequently and serves an importantfunction in managing interpersonal relations by welcominga guest or acknowledging a friend [1]. Socially intelligentrobots should therefore be able to initiate and respond tohaptic greetings such as a handshake or a hug. While anticipating touch interactions from an exocentric perspective [2]is useful for some applications, social robots would requireanticipation of human actions from an egocentric perspective.To establish a baseline, a perception study was conductedto compare how accurately humans can anticipate differenttypes of haptic greetings from an egocentric and exocentricview

Published

2023

93. Artificial Tactile Sensing System with Photoelectric Output for High Accuracy Haptic Texture Recognition and Parallel Information Processing

Author

Liuting Shan, Huaan Zeng, Yaqian Liu, Xianghong Zhang, Enlong Li, Rengjian Yu, Yuanyuan Hu, Tailiang Guo, and Huipeng Chen

Subjects

Artificial Intelligence, Touch, Haptic Technology, Mechanical Engineering, Humans, General Materials Science, Bioengineering, Neural Networks, Computer, General Chemistry, Electronics, Condensed Matter Physics

Abstract

Developing multifunctional artificial sensory systems is an important task for constructing future artificial neural networks. A system with multisignal output capability is highly required by the rising demand for high-throughput data processing in the Internet of Things (IoT) society. Here, a novel dual-output artificial tactile sensing (DOATS) system with parallel output of photoelectric signals was proposed. Because of the ionic-electronic coupling mechanism in light-emitting synaptic (LES) devices in the DOATS system, modulating electric current and light emission can coexist through ion accumulation and electron-hole recombination. As a result, the DOATS system can realize the simulation of human tactile information, and the recognition of 16 kinds of fabrics was demonstrated with an accuracy rate of 94.1%. A photoelectric hybrid artificial neural network was proposed, which achieved efficient and accurate multitask operation. The DOATS system proposed in this work is promising for implementing photoelectric hybrid neural network and promoting the development of interactive artificial intelligence.

Published

2022

94. An Adaptive Force Guidance System for Computer-Guided Laparoscopy Training

Author

Minsik Hong and Jerzy W. Rozenblit

Subjects

Laparoscopic surgery, Computer science, medicine.medical_treatment, education, Sliding mode control, Feedback, User-Computer Interface, Adaptive system, ComputingMilieux_COMPUTERSANDEDUCATION, medicine, Humans, Computer Simulation, Electrical and Electronic Engineering, Laparoscopy, Simulation, Haptic technology, medicine.diagnostic_test, Computers, Fuzzy control system, Computer Science Applications, Human-Computer Interaction, Control and Systems Engineering, Surgical instrument, Clinical Competence, Guidance system, Software, Information Systems

Abstract

We present an adaptive force guidance system for laparoscopic surgery skills training. This system consists of self-adjusting fuzzy sliding-mode controllers and switching mode controllers to provide proper force feedback. Using virtual fixtures, the proposed system restricts motions or guides a trainee to navigate a surgical instrument in a 3-D space in a manner that mimics a human instructor who would teach the trainees by holding their hands. The self-adjusting controllers incorporate human factors, such as different force sensitivity and proficiency levels. The proposed system was implemented and evaluated using the computer-assisted surgical trainer (CAST). The effects of the force guidance system are presented based on the experimental test results.

Published

2022

95. A Multilayered, Lesion-Embedded Ultrasound Breast Phantom with Realistic Visual and Haptic Feedback for Needle Biopsy

Author

Si Yen Ng and Chi-Lun Lin

Subjects

Acoustics and Ultrasonics, Radiological and Ultrasound Technology, Phantoms, Imaging, Haptic Technology, Biopsy, Needle, Biophysics, Humans, Radiology, Nuclear Medicine and imaging, Feedback, Ultrasonography

Abstract

Anthropomorphic phantoms have been used to provide residents with training in ultrasound-guided breast biopsy. However, different individuals differ in terms of the acoustic properties and stiffness of their breast tissues. The individual differences should be reflected in the training breast phantoms. This study aimed to develop a breast tissue-mimicking phantom that offers realistic haptic feedback and ultrasound imaging during needle insertion. We investigated the tunability of the mechanical and acoustic properties of breast tissue-mimicking materials (TMMs) to emulate fat, glandular and tumor tissues. The Design of experiments (DOE) methods and physician's feedback were used to reveal the effect of component concentration on Young's modulus and acoustic properties of breast TMMs. Furthermore, the relative backscatter power of the TMM was studied to adjust the contrast between the simulated tumor and background glandular tissue. The results indicated that Young's moduli of TMMs could be altered by adjusting the concentrations of glycerol, agar and olive oil. Changing the concentration of silicon carbide in a TMM could enhance the contrast between the target and the background materials in an ultrasound image. Finally, a series of TMMs were suggested for fat, glandular, benign tumor and malignant tumor tissues. A breast phantom with a tunability appropriately reflecting the individual differences of breast tissues was developed.

Published

2022

96. Single-string, closed-loop fixation modification to reposit a dislocated triple-looped haptic intraocular lens

Author

Quan-Yong, Yi, Jia-Ning, Ying, Shan-Jun, Wu, Guo-Hai, Wu, Zhi-Tao, Su, Sang-Sang, Wang, and Yan, Gong

Subjects

Lenses, Intraocular, Ophthalmology, Sutures, Haptic Technology, Suture Techniques, Visual Acuity, Humans, Surgery, Sclera, Sensory Systems, Retrospective Studies

Abstract

A technique using the single-string, closed-loop fixation method to reposit dislocated triple-looped haptic intraocular lens (IOL)-capsular bag complex is described. The long needle or curved needle with a 10-0/8-0 polypropylene suture and a 27/30-gauge needle were used as the guide needle to pass through the fenestrated haptics twice. The scleral interlaminar course was used as the fixed point. Last, a fixation knot was created in the sclerotomy by the 2 ends of the thread to close the suture loop for IOL fixation. Another knot was created about 2 to 3 mm from the exit point and was intrasclerally anchored by the aid of the attached needle. 4 eyes from 4 consecutive patients were studied retrospectively; during all follow-up visits, the IOLs were well centered and stable, and no suture erosion, hypotony, scleral atrophy, chronic inflammation, retinal tears, and/or detachments were observed.

Published

2022

97. To Move or Not to Move: Development of Fine-Tuning of Object Motion in Haptic Exploration

Author

Giulio Sandini and Alessandra Sciutti

Subjects

Fine-tuning, Artificial Intelligence, Computer science, Human–computer interaction, Perception, media_common.quotation_subject, Motor commands, Strategic advantage, Object motion, Stimulus (physiology), Software, media_common, Haptic technology

Abstract

Recognizing objects through touch is a complex task based on integrating information coming from multiple senses and motor commands guiding the exploratory motions. To gain insight into the development of exploratory strategies in children, in this study we addressed the question: how does exploration change when the stimulus becomes freely movable rather than fixed? We tested whether the possibility to move the object ushers in a strategic advantage, reducing the time and the number of touches necessary. We analyzed how school-aged children explore iCube, which is a sensorized cube measuring its orientation in space and contacts location. We tasked participants with finding specific cube faces; they could only touch the static cube, move and touch it, or move, touch and look at it. Visuo-haptic performances were adult-like at 7 years of age, whereas haptic exploration was less effective until 9 years. The fine-tuning of object movements as a function of task constraints, e.g. availability of vision or blind haptic task, increased significantly with age. Shedding light on how different factors shape haptic exploration could help researchers in the pursuit of detecting the occurrence of abnormal exploratory behaviors early on during development, providing a novel approach to detecting perceptual problems.

Published

2022

98. Cross-Modal Transmission Strategy

Author

Liang Zhou, Meng Zhang, and Xin Wei

Subjects

Modalities, Modality (human–computer interaction), Transmission (telecommunications), Computer science, Reliability (computer networking), Real-time computing, Media Technology, Electrical and Electronic Engineering, Latency (engineering), Signal, Throughput (business), Haptic technology

Abstract

Multi-modal services, typically integrated by visual, audio, and haptic signals, have been considered as promising killer services in 5G and beyond 5G era. However, due to essential difference among these signals, how to guarantee quality of multi-modal services is a significant technical challenge. Existing transmission schemes, which deliver and process each modality signal separately, cannot meet such requirements as low latency, high reliability, and high throughput. To get over the dilemma, this paper proposes a general cross-modal transmission strategy by taking advantage of the potential correlation among modalities, which consists of a delivery mechanism at the sender and a signal restoration procedure at the receiver. On the one hand, a visual-aided haptic content compression method is designed for the delivery mechanism. By utilizing the category correlation among modalities, haptic signals with similar visual content can be effectively compressed, reducing transmission burden. On the other hand, a fine-grained haptic to image synthesis (FHIS) approach is proposed for realizing signal restoration. Through exploring strong matching properties among modalities, the FHIS can restore the impaired, missing, delayed visual images from the received haptic signals. Experiments on a standard visual-haptic database and a practical platform evaluate the performance of the constructed cross-modal transmission strategy.

Published

2022

99. Accuracy and Precision of Haptic Robotic-Guided Implant Surgery in a Large Consecutive Series.

Author

Neugarten JM

Subjects

Humans, Dental Implantation, Endosseous, Prospective Studies, Haptic Technology, Maxilla diagnostic imaging, Maxilla surgery, Cone-Beam Computed Tomography, Computer-Aided Design, Imaging, Three-Dimensional, Dental Implants, Robotic Surgical Procedures, Surgery, Computer-Assisted

Abstract

Purpose: To determine the accuracy of dental implant placement using haptic robotic guidance in a large clinical series., Materials and Methods: In a prospective single-arm clinical study, 108 patients received 273 individual endosteal implants. A virtual preoperative restorative and surgical plan was created from a CBCT scan and matched to the surgical workspace on the day of surgery via either a tooth-based or bone-based fiducial splint. Intraoperatively, the surgeon manipulated a handpiece attached to a haptic robotic guidance arm. A variety of drills and implants were used. Both the osteotomy and the implant placement were guided by 3D haptic constraints according to the virtual plan. Postoperative CBCT scans permitted the calculation of the actual implant placement deviations compared to the plan for accuracy. Precision was calculated by comparing SDs from published literature., Results: The implants were evenly distributed by arch, with 47% placed in the maxilla and 53% in the mandible. The mean ± SD signed depth deviation was 0.14 ± 0.87 mm proud. The global angular deviation averaged 1.42 ± 1.53 degrees, with 95% confidence limits of 1.24 and 1.60 degrees. The crown of the actual placed implant showed an average deviation from the plan of 1.10 ± 0.69 mm and the apex of the placed implant showed a deviation of 1.12 ± 0.69 mm. Haptic robotic guidance showed greater precision than freehand, static computerguided, and dynamic computer-guided implant placement., Conclusions: This large clinical series of 273 implants shows a high accuracy of implant placement compared to the published accuracy for angular deviations for any technology, as well as demonstrating statistically greater precision. Long-term clinical studies are necessary to establish the true effect of increased accuracy on clinical outcomes. Using haptic robotic guidance provides accurate implant placement while allowing additional benefits compared to computer-guided surgery, namely full visualization of the surgical field and the ability to change the plan intraoperatively.

Published

2024

100. LONG-TERM OUTCOMES OF SUTURELESS INTRASCLERAL INTRAOCULAR LENS FIXATION IN CHILDREN AND ADULTS: Single-Surgeon Case Series With and Without Haptic Flanging With Up to 11 Years of Follow-Up.

Author

Moore SM, Bullock BL, and Walsh MK

Subjects

Adult, Child, Humans, Lens Implantation, Intraocular methods, Follow-Up Studies, Retrospective Studies, Haptic Technology, Sclera surgery, Suture Techniques, Lenses, Intraocular, Surgeons

Abstract

Purpose: Report and compare long-term outcomes and complications of sutureless scleral tunnel (SST) and flanged haptic (FH) scleral-fixated intraocular lens, with spontaneous intraocular lens (IOL) dislocation as primary outcome measure., Methods: Retrospective single-surgeon case series of 95 SST and 458 FH eyes from 2011 to 2022 (553 total eyes). Demographics, surgical indications, ocular history, visual acuity, and complication rates were collected., Results: Reoperation-requiring spontaneous IOL dislocation rate was significantly different ( P = 0.0167) between FH (3.7%) and SST (10.5%). Mean follow-up was 3.31 ± 0.30 versus 1.58 ± 0.07 years for SST and FH, respectively. There was no significant difference between preoperative (20/305 vs. 20/300) or final postoperative (20/77 vs. 20/62) visual acuity. Other complications included any cystoid macular edema (20.0% vs. 25.3%), elevated intraocular pressure (16.8% vs. 9.6%), IOL tilt requiring reoperation (5.3 vs. 0%), haptic exposure (2.1% vs. 3.3%), and reverse pupillary block (4.2% vs. 1.1%)., Conclusion: Haptic flanging resulted in fewer eyes meeting the primary end point of IOL dislocation. We reported the longest-to-date follow-up of both nonflanged SST IOL fixation and our FH-modified Yamane technique. Our FH-modified Yamane technique represents a safe, durable, and potentially superior option for scleral-fixated intraocular lens.

Published

2024