ABSTRACT
This paper reports on a series of user experiments evaluating the design of a multimodal test platform capable of rendering visual, audio, vibrotactile, and directional skin-stretch stimuli. The test platform is a handheld, wirelessly controlled device that will facilitate experiments with mobile users in realistic environments. Stimuli rendered by the device are fully characterized, and have little variance in stimulus onset timing. A series of user experiments utilizing navigational cues validates the function of the device and investigates the user response to all stimulus modes. Results show users are capable of interpreting all stimuli with high accuracy and can use the direction cues for mobile navigation. Tests included both stationary (seated) and mobile (walking a simple obstacle course) tasks. Accuracy and response time patterns are similar in both seated and mobile conditions. This device provides a means of designing and evaluating multimodal communication methods for handheld devices and will facilitate experiments investigating the effects of stimulus mode on device usability and situation awareness.
ABSTRACT
Experiments were conducted using a novel tactile contact rendering device to explore important factors of the tactile contact event. The effects of contact velocity and event-based transient vibrations were explored. Our research was motivated by a need to better understand the perception of the tactile contact event and to develop a means of rendering stiff surfaces with a nonspecialized haptic device. A passive tactile display, suitable for mounting on a Phantom robot, was developed and is capable of rendering the tactile sensation of contact on a fingertip over a range of velocities commonly experienced during everyday manipulation and tactile exploration. Experiments were conducted with this device to explore how tactile contact dynamics affect the perceived stiffness of a virtual surface. It was found that contact velocity does not have a significant effect on perceived stiffness. These results can be explained by prior research that defines perceived hardness (akin to stiffness) in terms of rate-hardness. However, in agreement with prior literature with stylus-based studies, the addition of transient vibrations to the contact event can, in some cases, increase the perceived stiffness.
ABSTRACT
Tactile feedback could replace or augment visual and auditory communication in a range of important applications. This paper advances the field of tactile communication by presenting performance data on a variety of tactors and a finger restraint that is suitable for use in portable devices. Tactors, the contact elements between the device and the skin, and finger restraints were evaluated using a tangential skin displacement direction identification task. We tested tactors of three sizes and two different textures. Rough textured tactors improved communication accuracy compared to smooth tactors, but tactor size did not have a statistically significant effect. Aperture-based restraints of three sizes were evaluated on both the index finger and the thumb. The aperture-based restraint was effective when used on both the index finger and the thumb, with performances on par with our previously tested thimble-based restraint. Participants performed better with larger apertures than with smaller apertures, but there was no interaction between aperture size and finger size, meaning that the same aperture could be used with a range of finger sizes. Subjects' perceptual acuity varied with stimulus direction. We discuss the effects of contact force, finger size, and differences in perceptual acuity between the index finger and thumb.
