Reverse-micelle-induced porous pressure-sensitive rubber for wearable human-machine interfaces. Adv. Mater. 2014, 26, 4825-4830. [CrossRef] [PubMed]S. Jung, J.H. Kim, J. Kim, S. Choi, J. Lee, I. Park, T. Hyeon, D.H. Kim, Reverse-micelle-induced porous pressure-sensitive rubber ...
1.1. Evaluation and Development of Human–Machine Interfaces Benchmarking can be conducted in a number of contexts, including the automotive industry. In the automotive context, it is of particular importance to evaluate human–machine interfaces (HMIs) since their design is critical in several aspect...
3.1. External Human—Machine Interfaces VRUs employ a variety of different communication cues to resolve ambiguities during interactions which results in a challenge to determine the ideal communication method that AVs should adopt. Road users consider many different factors when deciding to cross a roa...
In recent years, advancements in Intelligent and Connected Vehicles (ICVs) have led to a significant increase in the amount of information to the driver through Human–Machine Interfaces (HMIs). To prevent driver cognitive overload, the development of Adaptive HMIs (A-HMIs) has emerged. Indeed,...
The self-healing ability ensures that the HMI interfaces can maintain their integrity and continuous functionality after long-term use or accidental damage. Meanwhile, a good tensile performance can guarantee the HMI interfaces’ stable performance under various pressures. As shown in Figure 2c(i), ...
Furthermore, within this layer, business validations are located in “Value Objects” and “Entities”, as well as the ports of the MAMIC system (adapter interfaces and domain services). Application layer: The application layer contains the use cases needed for each “Bounded context” or unit...
The direct physical support causes interaction forces in human–machine interfaces, whereas their form determines both the effectiveness and comfort of the collaboration. However, their correct detection requires various sensor characteristics and remains challenging. Thus, this paper presents a developed ...
A“receptors unit” with different kinds of ‘receptors’ (e.g., sensors, user interfaces, etc.) and ‘effectors’ to communicate both ways between the system and its environment. Let us note that, unlike in [30], we do not seek to describe a specific implementation of this unit but on...
This review focuses on HMI systems for the collaboration between humans and machines through human–machine interfaces to accomplish tasks. Meanwhile, the involved machines specifically refer to smart machine agents, i.e., physical machines with perceptual, computational, and action capabilities [32]. ...
This work demonstrates the promising performance of this novel approach to sensing for use in human–machine interfaces. Keywords: intention detection; non-contact sensing; continuous motion; hand motion; wrist motion; sensor-based control; wearable device; joint angle regression; human–machine ...