High-Performance Flexible Transparent Force Touch Sensor for Wearable Devices
October 15, 2018 | KAISTEstimated reading time: 2 minutes
Researchers reported a high-performance and transparent nanoforce touch sensor by developing a thin, flexible, and transparent hierarchical nanocomposite (HNC) film. The research team says their sensor simultaneously features all the necessary characters for industrial-grade application: high sensitivity, transparency, bending insensitivity, and manufacturability.
Force touch sensors that recognize the location and pressure of external stimuli have received considerable attention for various applications, such as wearable devices, flexible displays, and humanoid robots. For decades, huge amounts of research and development have been devoted to improving pressure sensitivity to realize industrial-grade sensing devices. However, it remains a challenge to apply force touch sensors in flexible applications because sensing performance is subject to change and degraded by induced mechanical stress and deformation when the device is bent.
To overcome these issues, the research team focused on the development of non-air gap sensors to break away from the conventional technology where force touch sensors need to have air-gaps between electrodes for high sensitivity and flexibility.
The proposed non air-gap force touch sensor is based on a transparent nanocomposite insulator containing metal nanoparticles which can maximize the capacitance change in dielectrics according to the pressure, and a nanograting substrate which can increase transparency as well as sensitivity by concentrating pressure. As a result, the team succeeded in fabricating a highly sensitive, transparent, flexible force touch sensor that is mechanically stable against repetitive pressure.
Furthermore, by placing the sensing electrodes on the same plane as the neutral plane, the force touch sensor can operate, even when bending to the radius of the ballpoint pen, without changes in performance levels.
The proposed force touch has also satisfied commercial considerations in mass production such as large-area uniformity, production reproducibility, and reliability according to temperature and long-term use.
Finally, the research team applied the developed sensor to a pulse-monitoring capable healthcare wearable device and detected a real-time human pulse. In addition, the research team confirmed with HiDeep, Inc. that a seven-inch large-area sensor can be integrated into a commercial smartphone.
The team of Professor Jun-Bo Yoon, PhD student Jae-Young Yoo, and Dr. Min-Ho Seo from the School of Electrical Engineering carried out this study that was featured as a back cover in Advanced Functional Materials Journal.
PhD student Jae-Young Yoo who led this research said, "We successfully developed an industrial-grade force touch sensor by using a simple structure and fabrication process. We expect it to be widely used in user touch interfaces and wearable devices."
This research was supported by the Basic Research Program through the National Research Foundation of Korea funded by the Ministry of Science and ICT, and also supported by the Open Innovation Lab Cooperation Project funded by the National Nano Fab Center.
Figure 1. Schematic illustration of a transparent, flexible force touch sensor (upper image) and sensitivity enhancement by using stress concentration (lower image).
Suggested Items
OE-A at LOPEC: Printed Electronics Powers Sustainability
02/06/2024 | OE-AThe “OE-A Competition 2024” shows the many possibilities of flexible, organic, and printed electronics with inspiring products, prototypes, and fresh designs live at LOPEC 2024, the leading international exhibition and conference for flexible, organic, and printed electronics in Munich.
All Flex Solutions Invests in New Flexible Circuit Facility
02/05/2024 | All Flex SolutionsAll Flex Solutions has started the equipment build-out of a completely new flexible circuit manufacturing facility in Minneapolis. The building was purchased in 2020, and was completely renovated to accommodate the company’s plans for a brand new state-of-the-art flexible circuit fabrication plant.
Flexible Printed Circuits: A Design Primer
12/19/2023 | Chris Keirstead, PFC Flexible CircuitsFlexible circuits consist of conductive strips in a sandwich of insulating or dielectric material. They resist moisture and contamination and are insulated from external shorts, with holes or contact surfaces for interconnection. Understanding a package’s electrical requirements and not over-designing permits means taking full advantage of a flexible circuit’s potential compared to conventional wiring.
Intel Technology Helps Power Solution for a More Resilient Grid
11/29/2023 | IntelAhead of Enlit Europe, Intel announced that its technology is helping power the Edge for Smart Secondary Substations (E4S) Alliance’s new solution to modernize the energy grid.
Würth Elektronik Launches Research Project HyPerStripes
11/27/2023 | Wurth ElektronikHyPerStripes project partners will create a technology platform including manufacturing techniques for roll-to-roll (R2R) processing as well as the integration of electronic components onto very long ("endless"), flexible and stretchable printed circuit boards.