Abstract
To effectively organize design elements in virtual reality (VR) scene design and provide evaluation methods for the design process, we built a user image space cognitive model. This involved perceptual engineering methods and optimization of the VR interface. First, we studied the coupling of user cognition and design features in the VR system via the Kansei Engineering (KE) method. The quantitative theory I and KE model regression analysis were used to analyze the design elements of the VR system’s human–computer interaction interface. Combined with the complex network method, we summarized the relationship between design features and analyzed the important design features that affect users’ perceptual imagery. Then, based on the characteristics of machine learning, we used a convolutional neural network (CNN) to predict and analyze the user’s perceptual imagery in the VR system, to provide assistance for the design optimization of the VR system design. Finally, we verified the validity and feasibility of the solution by combining it with the human–machine interface design of the VR system. We conducted a feasibility analysis of the KE model, in which the similarity between the multivariate regression analysis of the VR intention space and the experimental test was approximately 97% and the error was very small; thus, the VR intention space model was well correlated. The Mean Square Error (MSE) of the convolutional neural network (CNN) prediction model was calculated with a measured value of 0.0074, and the MSE value was less than 0.01. The results show that this method can improve the effectiveness and feasibility of the design scheme. Designers use important design feature elements to assist in VR system optimization design and use CNN machine learning methods to predict user image values in VR systems and improve the design efficiency. Facing the same design task requirements in VR system interfaces, the traditional design scheme was compared with the scheme optimized by this method. The results showed that the design scheme optimized by this method better fits the user’s perceptual imagery index, and thus the user’s task operation experience was better.
Highlights
The application of virtual reality (VR) has developed substantially in the field of information visualization with the potential advantages of immersive experience
The optimization design of a VR system based on user information mining is realized, promoting the optimization design of a VR system to develop in a direction more in line with user cognition
The analysis results of multiple linear regression were combined with the complex network, which demonstrated that the interface layout (X1) and interface browsing sequence (X2) of the functional operation area worked as important factor indexes in the system design
Summary
The application of virtual reality (VR) has developed substantially in the field of information visualization with the potential advantages of immersive experience. As seen in previous studies, when optimizing a VR system, it is necessary to analyze the physiological and psychological needs of users, which can assist designers to build VR system interfaces and scenes with better experiences. The Kansei Engineering (KE) method plays an important role in mining users’ perceptual needs in the field of digital interface and user emotional interaction. Using the KE method, scholars combine perceptual cognition with rational analysis, which plays a positive role in the optimal design of product systems and assisting designers to make design decisions. Based on the correlation analysis of design elements under the implicit requirements of users, the complex network method can provide a better research direction. The key design elements were analyzed, and the user perceptual imagery value was predicted using a CNN, to optimize the design of the VR system interface
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
