open access
메뉴Background: Blood pressure monitors are medical devices that accurately measure blood pressure, enabling individuals to monitor their blood pressure levels. As hypertension has become more prevalent and awareness of blood pressure management has increased, the demand for these monitors has grown significantly high, making them essential tools for household health management. In this context, designing efficient and comfortable user experiences for blood pressure measurement has become a critical focus for deisgners, who aim to support users in effectively managing their blood pressure levels . Purpose:This paper aims to enhance the design of user interface (UI) for innovative blood pressure monitors. Methods: An integrated approach combining literature review and case comparison was used to examine UI designs of home-use blood pressure monitors, with a focus on the characteristics of tangible user interfaces (TUIs) and graphical user interfaces (GUIs). Results: For physical interfaces, function buttons using letters or graphic symbols were more difficult to recognize than those with plain text, resulting in underutilization of certain functions. For graphical interfaces, a comparative analysis of five brands’ measurement displays revealed variations in information layout, data volume, and graphic design. Among these Omron J735 and Yuwell S67XR exhibited relatively better performance. Conclusion: Blood pressure monitor display must be optimized to better address users’ specific needs. Enhancing information layout, data quantity, and graphic clarity will ensure easy access and accurate interpretation of health information for users of all ages and abilities.
Background: The advancement of smart vehicle technologies has made human-computer interaction (HCI) interfaces more critical in enhancing user experience and safety. Compared with traditional cars, smart cars provide more sophisticated and intelligent HCI interfaces by integrating advanced technologies. Purpose: This study aims to analyze the differences in HCI interfaces between smart cars and traditional cars, as well as their impact on driving experience and safety. Additionally, it is intended to promote the design and innovation of HCI in smart cars. It helps manufacturers to integrate cutting-edge technologies and enhance competitiveness. It also serves as a reference for automobile manufacturers and designers to balance technological advancement and user needs, and to promote the development of the automobile industry towards intelligentization. Methods: Through literature review, the study analyzes the development, design concepts, and technical applications of human-computer interaction interfaces between intelligent and traditional automobiles providing theoretical support for future research. The case study examines typical intelligent cars and traditional automobile central control interfaces, comparing the two in terms of information presentation, interaction mode, and personalized settings. Comparative research selects sample cases of traditional cars and smart cars, analyzes the differences in interaction interfaces, and identifies the needs and challenges of users. Conclusion: In comparison of human-computer interaction interfaces between smart cars and traditional cars, smart cars significantly provide a more convenient user experience, which is difficult to achieve in traditional cars. Traditional cars, on the other hand, focus more on the usability and interaction efficiency. Therefore, when designing the interaction system for smart cars, it is necessary to take into account humanization and user habits, simplify functionality, and ensure that drivers can smoothly transition into the smart driving environment so as to enhance the fun of interaction.
