Designing Wearable Vibrotactile Notifications for Information Communication

Visual and auditory stimuli are frequently used for information communication on mobile devices. These feedback modalities, however, are less suitable for emerging wearable devices that are intended to support multitasking with minimum interruption. Use of vibrotactile stimuli is great alternatives due to their low disruption and high ability to attract attention.Currently, effective vibration notifications are still elusive. In the present study, we explored a vibration notification mechanism by using a singular vibration motor to generate various vibration stimuli. This solution is appropriate for existing wearable devices that have a small form factor, limited internal space, and low battery capacity. Our first experiment investigated individuals' vibration perception in order to select a set of vibration stimuli that were detectable and discriminable. In our second experiment, we mapped the 5 vibration stimuli that were identified in the first experiment to various mobile application events and evaluated user performance using a wrist mounted prototype device. Results indicate that our vibration notification design achieved an average response accuracy rate of 82.3% (SD=18.0%) and an average response time of 2.83 (SD=0.83)s. Moreover, results of the post-test questionnaire revealed that the average perceived usefulness towards the vibration notification design was rated 5.5 (SD=1.18) and the average perceived ease of use was rated 5.0 (SD=1.36) when using a 7-point rating scale. Overall, results indicated the present vibration notification design was perceived as useful and highlighted opportunities for improving perceptions of ease of use. Our findings inform the design of future vibration notifications on wearable devices and highlight the importance of increasing pair-wise dissimilarities, perceived usefulness, and perceived ease of use in designing effective vibration notifications. We investigated the critical factors of and their effects on human vibration perception.We evaluated empirical vibration designs for information communication and compared user performance across designs.We developed a vibration notification mechanism on a wrist mounted prototype for novice users.We conducted an experiment to measure pair-wise discriminability of a larger set of vibration stimuli, and based on this experiment, selected a smaller set of vibration stimuli with the highest discriminability for our design.Based on survey responses, we selected the 5 mobile applications that were ranked as having the highest priorities for receiving notification events, and then we associated specific vibration stimuli for alerting events to the selected mobile applications.We conducted another experiment to evaluate user performance when using our final vibration notification design on a wrist mounted prototype device.Most individuals discriminated 4-5 vibrations based on perceived intensity and perceived durationIncreasing vibration discriminability can increase the accuracy in recognizing vibration-coded information