Your search keyword '"Lee, Keon Jae"' showing total 4 results

1. Theoretical Basis of Biomimetic Flexible Piezoelectric Acoustic Sensors for Future Customized Auditory Systems.

Author

Jung, Young Hoon, An, Jaehun, Hyeon, Dong Yeol, Wang, Hee Seung, Kim, Ingon, Jeong, Chang Kyu, Park, Kwi‐Il, Lee, Pooi See, and Lee, Keon Jae

Subjects

PIEZOELECTRIC detectors, AUDITORY pathways, BIOMIMETIC materials, SOUND pressure, PIEZOELECTRICITY, PHASES of matter, EAR, ACOUSTIC transducers

Abstract

Flexible piezoelectric sensors have been spotlighted as an essential human–machine interface (HMI) by obtaining high‐quality data from omnipresent biomechanical inputs. Because human voice is the most intuitive bio‐signal among them, flexible piezoelectric acoustic sensors (f‐PAS) have a potential to shift the paradigm of HMI technologies. Despite the reported outstanding performance such as high sensitivity and speaker recognition accuracy, the theoretical investigation of f‐PAS has been insufficient to realize future customized development, because sensing principles are fundamentally different from commercialized microphones. Here, a theoretical framework of self‐powered f‐PAS by using mechanical and electrical physics is introduced. First of all, the basic theory of f‐PAS is compared with the auditory system of human cochlear. Based on the biomimetic trapezoidal shape, the resonant frequencies are analyzed with various structural and material conditions. In addition, the piezoelectricity of f‐PAS is derived to predict the sensitivity and SNR prior to experiments. To investigate sensor properties under the medium condition that is similar to human ear, the acoustic responses depending on the states of matter are theoretically compared. Finally, the distance limit of f‐PAS is studied with the correlations between piezoelectricity and sound pressure, which would provide novel strategies of functional material design for future applications of f‐PAS. [ABSTRACT FROM AUTHOR]

Published

2024

2. Self-Powered Wireless Sensor Node Enabled by an Aerosol-Deposited PZT Flexible Energy Harvester.

Author

Hwang, Geon‐Tae, Annapureddy, Venkateswarlu, Han, Jae Hyun, Joe, Daniel J., Baek, Changyeon, Park, Dae Yong, Kim, Dong Hyun, Park, Jung Hwan, Jeong, Chang Kyu, Park, Kwi‐Il, Choi, Jong‐Jin, Kim, Do Kyung, Ryu, Jungho, and Lee, Keon Jae

Subjects

PIEZOELECTRICITY, AEROSOLS, LEAD zirconate titanate, MECHANICAL energy, VIBRATIONAL redistribution (Molecular physics), ENERGY harvesting

Abstract

A flexible piezoelectric energy harvester was demonstrated by an aerosol‐deposited PZT film to realize a self‐powered wireless sensor node system. The flexible harvesting device can generate a voltage of 200 V and a current of 35 μA. A self‐powered wireless sensor node was constructed by integrating the PZT harvester, a rectifying/storage circuit, and a wireless temperature‐sensor node to measure ambient temperature and wirelessly transmit the data to a monitor. [ABSTRACT FROM AUTHOR]

Published

2016

3. Flexible Inorganic Piezoelectric Acoustic Nanosensors for Biomimetic Artificial Hair Cells.

Author

Lee, Hyun Soo, Chung, Juyong, Hwang, Geon‐Tae, Jeong, Chang Kyu, Jung, Youngdo, Kwak, Jun‐Hyuk, Kang, Hanmi, Byun, Myunghwan, Kim, Wan Doo, Hur, Shin, Oh, Seung‐Ha, and Lee, Keon Jae

Subjects

PIEZOELECTRIC detectors, NANOSENSORS, BIOMIMETIC materials, HAIR cells, ARTIFICIAL membranes

Abstract

For patients who suffer from sensorineural hearing loss by damaged or loss of hair cells in the cochlea, biomimetic artificial cochleas to remedy the dis­advantages of existing implant systems have been intensively studied. Here, a new concept of an inorganic-based piezoelectric acoustic nanosensor (iPANS) for the purpose of a biomimetic artificial hair cell to mimic the functions of the original human hair cells is introduced. A trapezoidal silicone-based membrane (SM) mimics the function of the natural basilar membrane for frequency selectivity, and a flexible iPANS is fabricated on the SM utilizing a laser lift-off technology to overcome the brittle characteristics of inorganic piezoelectric materials. The vibration amplitude vs piezoelectric sensing signals are theoretically examined based on the experimental conditions by finite element analysis. The SM is successful at separating the audible frequency range of incoming sound, vibrating distinctively according to varying locations of different sound frequencies, thus allowing iPANS to convert tiny vibration displacement of ≈15 nm into an electrical sensing output of ≈55 μV, which is close to the simulation results presented. This conceptual iPANS of flexible inorganic piezoelectric materials sheds light on the new fields of nature-inspired biomimetic systems using inherently high piezoelectric charge constants. [ABSTRACT FROM AUTHOR]

Published

2014

4. Sensors: Flexible Inorganic Piezoelectric Acoustic Nanosensors for Biomimetic Artificial Hair Cells (Adv. Funct. Mater. 44/2014).

Author

Lee, Hyun Soo, Chung, Juyong, Hwang, Geon‐Tae, Jeong, Chang Kyu, Jung, Youngdo, Kwak, Jun‐Hyuk, Kang, Hanmi, Byun, Myunghwan, Kim, Wan Doo, Hur, Shin, Oh, Seung‐Ha, and Lee, Keon Jae

Subjects

NANOSENSORS

Abstract

A flexible inorganic piezoelectric acoustic nanosensor is demonstrated using high performance PZT thin films. As reported by S. Hur, S.‐H. Oh, K. J. Lee, and colleagues on page 6914, the acoustic nanosensor can utilize artificial hair cell with transducing electric signals to the sensory nerves. [ABSTRACT FROM AUTHOR]

Published

2014