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1. Haptic Technology Interaction Framework in Engineering Learning: A Taxonomical Conceptualization

   https://doi.org/10.1002/cae.70009  

   Mutis, Ivan; Oberemok, Marina (March 2025, Computer Applications in Engineering Education)

   Iskander, Magdy F (Ed.)

   ABSTRACT Innovative technology helps students foster creative thinking and problem‐solving abilities by augmenting human sensing and enriching input and output information. New technology can incorporate haptic sensing features—a sensing modality for user operations. Learning with haptic sensing features promises new ways to master cognitive and motor skills and higher‐order cognitive reasoning tasks (e.g., decision‐making and problem‐solving). This study conceptualizes haptic technology within the human‐technology interaction (HTI) framework. It aims to investigate the components of haptic systems to define their impact on learning and facilitate understanding of haptic technology, including application development to ease entry barriers for educators. The research builds a haptic HTI framework based on a systematic literature review on haptic applications in engineering learning over the last two decades. The review utilizes the SALSA methodology to analyze relevant studies comprehensively. The framework outcome is a haptic HTI taxonomy to build visual representations of the explicit connection between the taxonomy components and practical educational applications (by means of heatmaps). The approach led to a robust conceptualization of HTI into a taxonomy—a structured framework encompassing categories for interaction modalities, immersive technologies, and learning methodologies in engineering education. The model assists in understanding how haptic feedback can be utilized in learning with technology experiences. Applying haptic technology in engineering education includes mastering fundamental science concepts and creating customized haptic prototypes for engineering processes. A growing trend focuses on wearable haptics, such as gloves and vests, which involve kinesthetic movement, fine motor skills, and spatial awareness—all fostering spatial and temporal cognitive abilities (the ability to effectively manage and comprehend significant amounts ofspatial(how design components or resources are related to one another in the 3D space) andtemporal(the logic in a process, such as the order, sequences, and hierarchies of the resources information). The haptic human‐technology interaction (H‐HTI) framework guides future research in developing cognitive reasoning through H‐HTI, unlocking new frontiers in engineering education. 

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2. Haptic Experiences Shape Student-Generated Gestures While Learning with Computational Environments

   https://doi.org/10.22318/icls2024.404372  

   Tang, Xiaoyu; Lindgren, Robb; Lira, Matthew (June 2024, ISLS)

   Abstract: In science education, gestures have emerged as a valuable tool for both students to represent their reasoning and educators to assess learners’ developing knowledge. One reason is that gestures afford representing dynamic causal reasoning, a fundamental aspect of understanding various natural phenomena. However, gestures inherently lack feedback mechanisms and are possibly epiphenomenal to learning. We address these limitations by pairing haptic physical models with a computational NetLogo simulation designed to support students in comprehending dynamic interactions within complex systems. In this study, we investigated the impact of haptic learning experiences and computational environments on student-generated gestures. Our findings revealed that haptic learning experiences augment the computational environments by providing students with sensory feedback. This, in turn, leads to a shift in students' gestures, as they transition from representing aggregate patterns, such as quantity and motion, to individual interactions between physical entities and forces. 

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3. Gait Sensing and Haptic Feedback Using an Inflatable Soft Haptic Sensor

   https://doi.org/10.1115/1.4064377  

   Quinones_Yumbla, Emiliano; Rokalaboina, Jahnav; Kanechika, Amber; Poddar, Souvik; Nibi, Tolemy M; Zhang, Wenlong (January 2024, ASME Letters in Dynamic Systems and Control)

   Abstract Collecting gait data and providing haptic feedback are essential for the safety and efficiency of robot-based rehabilitation. However, readily available devices that can perform both are scarce. This work presents a novel method for mutual sensing and haptic feedback, through the development of an inflatable soft haptic sensor (ISHASE). The design, modeling, and characterization of ISHASE are discussed. Four ISHASEs are embedded in the insole of a shoe to measure ground reaction forces and provide haptic feedback. Four participants were recruited to evaluate the performance of ISHASE as a sensor and haptic device. Experimental results indicate that ISHASE can accurately estimate user’s ground reaction forces while walking, with a maximum and a minimum accuracy of 91% and 85%, respectively. Haptic feedback was delivered to four different locations under the foot, and users could identify the location with an average 92% accuracy. A case study that exemplifies a rehabilitation scenario is presented to demonstrate ISHASE’s usefulness for mutual sensing and haptic feedback. 

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4. Haptic paradigms for multimodal interactive simulations

   Tennison, J. L.; Greenberg, J.; Moore, E. B.; & Gorlewicz, J. L. (January 2021, Journal on technology and persons with disabilities)

   Touch is often omitted or viewed as unnecessary in digital learning. Lack of touch feedback limits the accessibility and multimodal capacity of digital educational content. Touchscreens with vibratory, haptic feedback are prevalent, yet this kind of feedback is often under-utilized. This work provides initial investigations into the design, development, and use of vibratory feedback within multimodal, interactive, educational simulations on touchscreen devices by learners with and without visual impairments. The objective of this work is to design and evaluate different haptic paradigms that could support interaction and learning in educational simulations. We investigated the implementation of four haptic paradigms in two physics simulations. Interviews were conducted with eight learners (five sighted learners; three learners with visual impairments) on one simulation and initial results are shared. We discuss the learner outcomes of each paradigm and how they impact design and development moving forward. 

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5. Towards a ROS-based Modular Multi-Modality Haptic Feedback System for Robotic Minimally Invasive Surgery Training Assessments

   https://doi.org/10.1109/ISMR48347.2022.9807479  

   Machaca, Sergio; Karachiwalla, Zulekha; Riaziat, Naveed D; Brown, Jeremy D (January 2022, International Symposium on Medical Robotics)

   Current commercially available robotic minimally invasive surgery (RMIS) platforms provide no haptic feedback of tool interactions with the surgical environment. As a consequence, novice robotic surgeons must rely exclusively on visual feedback to sense their physical interactions with the surgical environment. This technical limitation can make it challenging and time-consuming to train novice surgeons to proficiency in RMIS. Extensive prior research has demonstrated that incorporating haptic feedback is effective at improving surgical training task performance. However, few studies have investigated the utility of providing feedback of multiple modalities of haptic feedback simultaneously (multi-modality haptic feedback) in this context, and these studies have presented mixed results regarding its efficacy. Furthermore, the inability to generalize and compare these mixed results has limited our ability to understand why they can vary significantly between studies. Therefore, we have developed a generalized, modular multi-modality haptic feedback and data acquisition framework leveraging the real-time data acquisition and streaming capabilities of the Robot Operating System (ROS). In our preliminary study using this system, participants complete a peg transfer task using a da Vinci robot while receiving haptic feedback of applied forces, contact accelerations, or both via custom wrist-worn haptic devices. Results highlight the capability of our system in running systematic comparisons between various single and dual-modality haptic feedback approaches. 

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