From virtual reality to rehabilitation and communication, haptic technology has revolutionized the way humans interact with the digital world. (Credit: Rice University)

While early haptic devices focused on single-sensory cues like vibration-based notifications, modern advancements have paved the way for multisensory haptic devices that integrate various forms of touch-based feedback, including vibration, skin stretch, pressure and temperature. Recently, a team of experts has analyzed the current state of wearable multisensory haptic technology, outlining its challenges, advancements, and real-world applications.

Designing effective, wearable multisensory haptic devices requires a deep understanding of human touch perception, and the research team identified several key challenges in the field today. One of the most significant hurdles is the variability in skin contact mechanics as differences in skin elasticity, receptor distribution and external factors like humidity can alter how haptic stimuli are perceived. Another issue is tactile masking, where multiple haptic sensations such as vibration and skin stretch can interfere with one another, reducing perceptual clarity.

In addition, wearability and comfort continue to be major considerations in every product. Haptic devices must be designed to fit different body locations without causing discomfort, restricting movement or disrupting daily activities. Factors such as weight, size and attachment methods all play a crucial role in ensuring long-term usability.

In addition to highlighting challenges, the authors identified several emerging actuation methods that could redefine wearable haptic technology.

Electromechanical actuation, commonly used in vibrational feedback systems, remains the most widely adopted method due to its reliability and affordability. However, it often struggles to provide a diverse range of haptic cues. Polymeric actuation, which relies on smart polymers that change shape or texture when exposed to stimuli, offers a lightweight and flexible alternative for delivering haptic feedback. Fluidic actuation, which utilizes pressurized air or liquid to generate dynamic tactile sensations, is gaining traction in soft robotics and textile-based haptic wearables, offering new possibilities for comfort and adaptability. Additionally, thermal actuation is emerging as a way to enhance immersion in virtual environments or simulate real-world interactions through warming or cooling sensations.

Source 

Topics:
Medical Robotics Wearables Wearables

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