CLEO 2022, San Jose, USA

May 16 - May 20, 2022 (Mon. - Fri.), McEnery Convention Center

ICEIC 2025, Osaka, Japan

January 19 - January 22, 2025 (Sun. - Wen.), Osaka International House

A Novel Low-Power Level Shifter With Stacked Structure Based on a-IGZO Thin-Film Transistors

Kyeongbin Lee, Kyungmin Choi, Hyunwoo Kim and Hojin Lee

Abstract

 In this paper, we propose a novel level shifter based on amorphous indium-gallium-zinc-oxide (a-IGZO) thin-film transistors (TFTs). The proposed level shifter achieves low power consumption by employing a stacking structure and enhances connectivity with the external panel by using only a single input clock signal.

ICEIC 2025, Osaka, Japan

January 19 - January 22, 2025 (Sun. - Wen.), Osaka International House

Design of Low Power Scan Driver Based on a-InGaZnO TFTs for Frame Masking Technique with Extra Clock Signal Modulation

Chaeyeon Park, Dongseok Kim, Hyunwoo Kim, and Hojin Lee

Abstract

We proposed a novel low-power scan driver using frame masking techniques, which selectively disables scan driver outputs based on the type of content, thereby reducing unnecessary pixel updates. The proposed frame masking drive effectively reduces power consumption not only for the scan driver but also for the display panel itself.

IEEE-NEMS 2023, Jeju, Korea

May 14 - May 17, 2023 (Sun. - Wed.), Ramada Plaza Hotel

Patch-Type Electromagnetic Energy Focusing Metasurface for Wireless Power Transfer in Bio-Implantable Devices

Wonwoo Lee, Semin Jo, and Hojin Lee

Abstract

 Herein, a patch-type metasurface is proposed that improves the power transferred to the skin by reducing the reflection loss of electromagnetic waves at the air–skin interface and forming a focal point at a specific location. The subwavelength-thickness (< λ/10) metasurface is introduced that focuses electromagnetic energy to a desired depth in multilayered biological tissues to enhance the transferred power for implantable devices. The stable focusing performance is demonstrated by confirming the robust focal point and field intensity profiles for oblique incident angles and polarization directions with enhanced voltage of approximately 11.1 dBmV at a depth of 10 mm in an in-vitro environment. By applying the patch-type metasurface to an actual implemented wireless power transfer system, an improved transmission coefficient of 6.37 dB is realized at a depth of 10 mm compared with that of a system without the metasurface patch.

IMID 2019, Gyeongju, Korea

August 27 - 30, 2019 (Tue. - Fri.), HICO

Micropatterned polymer light-emitting diodes (μ-PLEDs) based on Orthogonal Polymer Semiconductors

Kyun-Yeong Choi, Han Wool Park, Do Hwan Kim, and Hojin Lee

Abstract

  In this paper, a micro-patterned 2-color OLED was fabricated through a sequential solution process based on standard photolithography. Previously, we

developed a sol-gel process to obtain the orthogonality of organic semiconductor against the solvents and chemicals so that we could apply the standard photo-lithography and dry-etch process to achieve micron-size patterns of light-emitting polymers with MEH-PPV and F8T2-based orthogonal polymer semiconductor gel (OPSG) through sequential solution processes.