Your search keyword '"Sanghyun Heo"' showing total 18 results

1. Transparent and flexible fingerprint sensor array with multiplexed detection of tactile pressure and skin temperature

Author

Byeong Wan An, Sanghyun Heo, Sangyoon Ji, Franklin Bien, and Jang-Ung Park

Subjects

Science

Abstract

Next-generation mobile security devices require fingerprint sensors that can be incorporated directly into the display. Here, Park et al. demonstrate a highly transparent, multifunctional capacitive fingerprint sensor array that simultaneously detects tactile pressure and finger skin temperature.

Published

2018

2. Research on flexible display at Ulsan National Institute of Science and Technology

Author

Jihun Park, Sanghyun Heo, Kibog Park, Myoung Hoon Song, Ju-Young Kim, Gyouhyung Kyung, Rodney Scott Ruoff, Jang-Ung Park, and Franklin Bien

Subjects

Electronics, TK7800-8360, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract Displays represent information visually, so they have become the fundamental building block to visualize the data of current electronics including smartphones. Recently, electronics have been advanced toward flexible and wearable electronics that can be bent, folded, or stretched while maintaining their performance under various deformations. Here, recent advances in research to demonstrate flexible and wearable displays are reviewed. We introduce these results by dividing them into several categories according to the components of the display: active-matrix backplane, touch screen panel, light sources, integrated circuit for fingerprint touch screen panel, and characterization tests; and we also present mechanical tests in nano-meter scale and visual ergonomics research.

Published

2017

3. A 1.08ms Ultrafast Scanning Capacitive Touch-Screen Sensor Interface with Charge-Interpolated Common-Mode Compensation and Host-Based Adaptive Median Filtering.

Author

Jonghang Choi, Subin Kim, Yongjun Lee, Sanghyun Heo, Keum-Dong Jung, Young-Ha Hwang, and Jun-Eun Park

Published

2023

4. 17-aFrms Resolution Noise-Immune Fingerprint Scanning Analog Front-End for Under-Glass Mutual-Capacitive Fingerprint Sensors

Author

Franklin Bien, Sangwoong Shin, Seunghun Oh, Sanghyun Heo, and Kyeongmin Park

Subjects

Physics, Noise, Analog front-end, Capacitive sensing, Acoustics, Fingerprint (computing), Resolution (electron density), Electrical and Electronic Engineering

Published

2022

5. A low-offset, low-noise, fully differential receiver with a differential signaling method for fingerprint mutual capacitive touch screen.

Author

Sanghyun Heo, Joohyeb Song, Kyoungmin Park, Eun-Ho Choi 0001, Seong-Mun Kim, and Franklin Bien

Published

2017

6. A 32-dB SNR Readout IC With 20-Vpp Tx Using On-Chip DM-TISM in HV BCD Process for Mutual-Capacitive Fingerprint Sensor

Author

Franklin Bien, Seong Mun Kim, Eunho Choi, Kyoungmin Park, Gyeongho Namgoong, Haksun Kim, Hyunggun Ma, and Sanghyun Heo

Subjects

Physics, business.industry, Capacitive sensing, 020208 electrical & electronic engineering, Transmitter, Order (ring theory), 02 engineering and technology, Type (model theory), Signal, Signal-to-noise ratio (imaging), 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, System on a chip, Electrical and Electronic Engineering, business, DC bias

Abstract

This brief presents a readout IC with a 20 V high-voltage (HV) transmitter (Tx) and On-Chip Differentially Modulated Time-Interleaved Sensing Method (DM-TISM) in a BCD process for a mutual-capacitive Transparent Fingerprint Sensor (TFPS) in order to achieve high SNR, AC & DC offset reduction, high noise immunity, and compensate for the signal loss under thick cover glass. A proposed readout IC with on-chip DM-TISM is composed of 42 identical HV Tx channels, 32 identical Rx channels, and a diamond-patterned TFPS. The performance results including those for transient noise show that the DM-TISM achieves greater SNR than conventional TISM. The measured raw data show that the proposed readout IC achieves SNR of 32 dB with current consumption of 25 mA for the Tx and 13 mA for the Rx. It can be applied to any type of mobile device that needs fingerprint recognition. The ICs for the Tx and Rx are fabricated using 0.25- $\mu \text{m}$ BCD process and 0.18- $\mu \text{m}$ CMOS process with $1.6\,\,\mathrm {mm} \times 3.5$ mm and $2.5\,\,\mathrm {mm} \times 2.5$ mm areas, respectively.

Published

2020

7. Differential Coded Multiple Signaling Method With Fully Differential Receiver for Mutual Capacitive Fingerprint TSP

Author

Kyeongmin Park, Franklin Bien, Eunho Choi, and Sanghyun Heo

Subjects

Physics, Offset (computer science), Amplifier, Capacitive sensing, 020208 electrical & electronic engineering, 02 engineering and technology, Fingerprint recognition, Frame rate, Capacitance, law.invention, Capacitor, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, Voltage

Abstract

This paper presents a fingerprint mutual capacitive touchscreen panel (TSP) readout IC, which uses a differential coded multiple signaling (DCMS) method. A readout IC with high SNR and fast frame rate is required for fingerprint recognition. However, achieving high SNR is challenging owing to the limited capacitance difference originating from the small depth variations between the ridges and valleys of the fingerprint. In addition, scanning the entire fingerprint TSP with multiple electrodes is time-consuming. A fully differential receiver with DCMS is proposed to detect the low capacitance difference in a fingerprint TSP. The internal noise is minimized by the low-noise amplifier, and external noise is eliminated by a lock-in sensing architecture. In addition, DCMS reduces the offset and enhances the SNR while achieving faster frame rate in multiple channels. The proposed architecture can detect capacitance of 50 aF, which is the capacitance difference resulting from the ridges and valleys of a finger under a 0.3-mm-thick (T) cover glass. The readout IC achieves 15.1-dB peak-to-peak SNR and 23-Hz frame rate with a transparent mutual capacitive fingerprint TSP under 0.3T glass. The power consumption is below 21 mW at 3.3-V supply voltage. The IC was fabricated using a 0.18- $ {\mu }\text{m}$ standard CMOS process.

Published

2020

8. Research on flexible display at Ulsan National Institute of Science and Technology

Author

Franklin Bien, Kibog Park, Gyouhyung Kyung, Rodney S. Ruoff, Ju-Young Kim, Jang Ung Park, Jihun Park, Myoung Hoon Song, and Sanghyun Heo

Subjects

Engineering drawing, Engineering, TK7800-8360, Wearable computer, lcsh:TK7800-8360, 02 engineering and technology, Integrated circuit, 010402 general chemistry, 01 natural sciences, law.invention, law, General Materials Science, Electronics, Electrical and Electronic Engineering, Materials of engineering and construction. Mechanics of materials, Wearable technology, Block (data storage), business.industry, Fingerprint (computing), lcsh:Electronics, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Engineering management, Backplane, Flexible display, TA401-492, 0210 nano-technology, business

Abstract

Displays represent information visually, so they have become the fundamental building block to visualize the data of current electronics including smartphones. Recently, electronics have been advanced toward flexible and wearable electronics that can be bent, folded, or stretched while maintaining their performance under various deformations. Here, recent advances in research to demonstrate flexible and wearable displays are reviewed. We introduce these results by dividing them into several categories according to the components of the display: active-matrix backplane, touch screen panel, light sources, integrated circuit for fingerprint touch screen panel, and characterization tests; and we also present mechanical tests in nano-meter scale and visual ergonomics research.

Published

2017

9. On-Display Transparent Half-Diamond Pattern Capacitive Fingerprint Sensor Compatible With AMOLED Display

Author

Kibog Park, Kyungmin Na, Franklin Bien, Sanghyun Heo, Jae Joon Kim, Hyunggun Ma, Zhenyi Liu, Sungchul Jung, Hanbyul Jin, and Jeeyoon Lee

Subjects

Engineering, business.industry, Capacitive sensing, 020208 electrical & electronic engineering, 010401 analytical chemistry, Fingerprint (computing), 02 engineering and technology, Fingerprint recognition, 01 natural sciences, Capacitance, 0104 chemical sciences, Active matrix, law.invention, Capacitor, AMOLED, law, 0202 electrical engineering, electronic engineering, information engineering, Transmittance, Optoelectronics, Electrical and Electronic Engineering, business, Instrumentation

Abstract

The need for personal security in portable devices has increased. Among several biometric sensing technologies, fingerprint sensing is the most highlighted method. However, a fingerprint sensor in electronics is stifling the demands for a larger interactive display. In this paper, the bottlenecks of placing the sensor on display is discussed, and an on-display mutual capacitive high-resolution transparent fingerprint sensor with a half-diamond pattern is proposed for adapting to the needs of personal security on a larger screen. To overcome various performance limitations on the on-display fingerprint sensor, a metal mesh is used as an electrode material, and the half-diamond pattern is applied. The proposed pattern is compatible with the diamond-patterned active matrix organic light emitter diode display. The proposed sensor has $72\times72$ channels in a 6 mm $\times6$ mm area. The sensor satisfies the criteria set by the Federal Bureau of Investigation for fingerprint sensing with 322 capacitors per inch, and the measured transmittance in the visible light region is 79.7%. The proposed sensor achieved a capacitance variation 2.3 times larger than that achieved by the conventional sensor. The five-channel fingerprint sensing circuit to examine the feasibility of fingerprint detection is fabricated with the TSMC 0.18- $\mu \text{m}$ process.

Published

2016

10. 72 dB SNR, 240 Hz Frame Rate Readout IC With Differential Continuous-Mode Parallel Architecture for Larger Touch-Screen Panel Applications

Author

Eunho Choi, Kyoungmin Park, Jae Joon Kim, Hyunggun Ma, Franklin Bien, Sanghyun Heo, and Joohyeb Song

Subjects

Engineering, business.industry, Capacitive sensing, 020208 electrical & electronic engineering, Transmitter, Electrical engineering, Skew, Spectral density, 020206 networking & telecommunications, 02 engineering and technology, Frame rate, Noise (electronics), Signal, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, business, Charge amplifier

Abstract

This paper presents a mutual capacitive touch screen panel (TSP) readout IC (ROIC) with a differential continuous-mode parallel operation architecture (DCPA). The proposed architecture achieves a high product of signal-to-noise ratio (SNR) and frame rate, which is a requirement of ROIC for large-sized TSP. DCPA is accomplished by using the proposed differential sensing method with a parallel architecture in a continuous-mode. This architecture is implemented using a continuous-type transmitter for parallel signaling and a differential-architecture receiver. A continuous-type differential charge amplifier removes the common-mode noise component, and reduces the self-noise by the band-pass filtering effect of the continuous-mode charge amplifier. In addition, the differential parallel architecture cancels the timing skew problem caused by the continuous-mode parallel operation and effectively enhances the power spectrum density of the signal. The proposed ROIC was fabricated using a 0.18- $\mu$ m CMOS process and occupied an active area of 1.25 $\text{mm}^{2}$ . The proposed system achieved a 72 dB SNR and 240 Hz frame rate with a 32 channel TX by 10 channel RX mutual capacitive TSP. Moreover, the proposed differential-parallel architecture demonstrated higher immunity to lamp noise and display noise. The proposed system consumed 42.5 mW with a 3.3-V supply.

Published

2016

11. An Excessive Current Subtraction Technique to Improve Dynamic Range for Touch Screen Panel Applications

Author

Hyunggun Ma, Franklin Bien, and Sanghyun Heo

Subjects

Engineering, business.industry, Dynamic range, Noise (signal processing), 020208 electrical & electronic engineering, 010401 analytical chemistry, Subtraction, Electrical engineering, High voltage, 02 engineering and technology, 01 natural sciences, Signal, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, law.invention, Capacitor, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, business, Charge amplifier, Voltage

Abstract

A current subtraction technique with parallel operation system is proposed to remove excessive current in touch screen application. The proposed current subtraction remove the current which go into the input node of charge amplifier. The value of subtraction current is same with current when touch screen is not touched. As a result, charge amplifier output is only proportional to variation of mutual capacitor, which make dynamic rage is increased. Also, Transmitter (Tx) driving signal and subtraction driving signal are out of phase each other. Thus, noise generated in Tx is cancelled. The proposed IC is implemented in a mixed-mode 0.18-um CMOS process. Overall system is designed for touch screen panel (TSP) with 16 driving lines and 8 sensing lines. 5-V supply voltages are used in the proposed circuits. For multiple Tx driving signal, Walsh codes are used and signal frequency is 300 khz. By using proposed technique, dynamic rage is improved 36 dB.

Published

2016

12. Wireless Energy Transfer: Touch/Proximity/Hover Sensing for Large Contoured Displays and Industrial Applications

Author

Sai Kiran Oruganti, Franklin Bien, Sanghyun Heo, and Hyunggun Ma

Subjects

Engineering, Liquid-crystal display, business.industry, Transmitter, Electrical engineering, law.invention, Sine wave, law, Proximity sensor, Maximum power transfer theorem, Wireless, Electrical and Electronic Engineering, business, Instrumentation, Multimeter, Tactile sensor

Abstract

This paper presents a new kind of touch sensor that utilizes the concept of wireless energy transfer (WET). A near-field sheet like a waveguide-based WET system was used for this purpose based on its geometric suitability. The approaching target object (human finger bioimpedance) disturbs the overall sheet reactance based on a complex power conservation equation at the resonant frequency. Thus, the drop in the efficiency of the power transfer can be utilized to carry out the task of sensing. The WET sensor was designed to operate at 29 MHZ, with a power transfer efficiency of −3.18 dB. An experimental demonstration was performed by feeding a 10 V peak-to-peak sine wave at the transmitter end and reading a dc output using a full-wave rectifier and multimeter at the receiver end. The system was designed to achieve a drop of 2.1 V when a touch was registered. The sensor was also designed to operate in the proximity mode. For operation in the proximity mode, the receiver had to be a wave trap cavity. This was achieved by designing the receiver to have a cylindrical wave cavity arrangement. The WET sensor had to be unaffected by the presence of an electric field, and this was demonstrated by carrying out sensing while the sensor was located under an LCD, which has a considerable electric field. It was experimentally demonstrated that the sensor had a linear output in proximity mode. Proposed sensor could be ideal candidate for: 1) touch screen panels; 2) human-robotics interactions; and 3) security applications.

Published

2015

13. A low-offset, low-noise, fully differential receiver with a differential signaling method for fingerprint mutual capacitive touch screen

Author

Seong Mun Kim, Franklin Bien, Eunho Choi, Joohyeb Song, Sanghyun Heo, and Kyoungmin Park

Subjects

Capacitor, law, Computer science, Capacitive sensing, Hardware_INTEGRATEDCIRCUITS, Operational amplifier, Electronic engineering, Integrated circuit, Fingerprint recognition, Frame rate, Capacitance, Differential signaling, law.invention

Abstract

This paper presents a fingerprint mutual capacitive touch-screen panel (TSP) readout IC (ROIC) with a differential signaling method for fast fingerprint recognition. A readout IC with high SNR and fast frame rate are required in the fingerprint recognition. However, the capacitance difference by the ridge and valley of the fingerprint is very small, so that the signal-to-noise ratio is very low. In addition, it takes long time to scan whole fingerprint TSP with multiple electrodes. A fully differential architecture with differential signaling is proposed to detect the low capacitance difference in fingerprint TSP. The internal noise generated is minimized by 2nd fully differential operational amplifier and external noise is eliminated by a lock-in sensing structure. In addition, DCMS reduces an AC offset and enhances a higher product of SNR and frame rate in multiple channels. Proposed IC has been fabricated using a 0.18 μm standard CMOS process.

Published

2017

14. Stretchable Dual-Capacitor Multi-Sensor for Touch-Curvature-Pressure-Strain Sensing

Author

Sungchul Jung, Hanbyul Jin, Sanghyun Heo, Jae-Ik Lim, Junhyung Kim, Franklin Bien, Won-Sang Park, Kibog Park, and Hye Yong Chu

Subjects

Materials science, Capacitive sensing, Acoustics, lcsh:Medicine, 02 engineering and technology, 010402 general chemistry, Curvature, 01 natural sciences, Capacitance, Article, law.invention, chemistry.chemical_compound, law, Hardware_INTEGRATEDCIRCUITS, lcsh:Science, Multidisciplinary, Polydimethylsiloxane, lcsh:R, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Capacitor, Tree structure, chemistry, Electrode, lcsh:Q, Photolithography, 0210 nano-technology

Abstract

We introduce a new type of multi-functional capacitive sensor that can sense several different external stimuli. It is fabricated only with polydimethylsiloxane (PDMS) films and silver nanowire electrodes by using selective oxygen plasma treatment method without photolithography and etching processes. Differently from the conventional single-capacitor multi-functional sensors, our new multi-functional sensor is composed of two vertically-stacked capacitors (dual-capacitor). The unique dual-capacitor structure can detect the type and strength of external stimuli including curvature, pressure, strain, and touch with clear distinction, and it can also detect the surface-normal directionality of curvature, pressure, and touch. Meanwhile, the conventional single-capacitor sensor has ambiguity in distinguishing curvature and pressure and it can detect only the strength of external stimulus. The type, directionality, and strength of external stimulus can be determined based on the relative capacitance changes of the two stacked capacitors. Additionally, the logical flow reflected on a tree structure with its branches reaching the direction and strength of the corresponding external stimulus unambiguously is devised. This logical flow can be readily implemented in the sensor driving circuit if the dual-capacitor sensor is commercialized actually in the future.

Published

2017

15. A 200 atto farad capacitance sensing with a differential signaling method for a mutual capacitive finger-print sensors

Author

Franklin Bien, Joohyeb Song, Hyunggun Ma, Eunho Choi, Sanghyun Heo, and Kyeongmin Park

Subjects

Capacitive coupling, Engineering, business.industry, Capacitive sensing, 020208 electrical & electronic engineering, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Integrated circuit, Differential signaling, Capacitance, law.invention, Capacitor, CMOS, Hardware_GENERAL, law, Hardware_INTEGRATEDCIRCUITS, 0202 electrical engineering, electronic engineering, information engineering, Farad, business

Abstract

This paper describes an atto farad capacitive sensing system for a finger-print sensor. The architecture of mutual capacitive finger-print sensor is obtained by investigating the capacitance change by the finger-print based on the Q3D Extractor model. An electrostatic simulation shows that the 200aF difference caused by the valley and the ridge in the sensor. In order to sense the atto farad capacitance in finger-print sensor, a continuous-type fully differential architecture with a differential transmitted signals is proposed to amplify a capacitance difference only with a reduced the parasitic effect caused by a large number of electrodes. The prototype IC with 0.18um CMOS achieves 300mV/200aF.

Published

2016

16. Algorithm for improving SNR using high voltage and differential Manchester code for capacitive touch screen panel

Author

Jae Joon Kim, Hyunggun Ma, Sanghyun Heo, and Franklin Bien

Subjects

Computer science, business.industry, Capacitive sensing, Electrical engineering, High voltage, Capacitance, Return-to-zero, Signal, Manchester code, Signal-to-noise ratio, Modulation, Electronic engineering, Electrical and Electronic Engineering, business, Algorithm, Computer Science::Information Theory

Abstract

An algorithm for a capacitive touch screen panel that can make the sum of the signal into `0' for the use of high voltage is presented. The differential Manchester code is combined with the Walsh-Hadamard code to generate an input coded signal. Owing to the property of the differential Manchester code, the Moore-Penrose pseudoinverse matrix is employed to decode-mutual capacitance from the received signal. As only the variation between the un-touch and touch condition is detected at the receiver, a high-voltage input coded signal is used. Unlike a normal touch system, the decoded sensing capacitance in the proposed algorithm does not have an absolute value. Positive decoded capacitance is the un-touch condition and negative decoded capacitance is the touch condition. The simulated signal-to-noise ratio (SNR) of the proposed algorithm is 27.9 dB, which is 8.26 dB higher than SNR in not return to zero (NRZ).

Published

2014

17. Highly improved SNR differential sensing method using parallel operation signaling for touch screen application

Author

Franklin Bien, Sanghyun Heo, Hyunggun Ma, and Jae Joon Kim

Subjects

Engineering, Signal-to-noise ratio, business.industry, Noise (signal processing), Amplifier, Capacitive sensing, Transmitter, Electrical engineering, Electronic engineering, Filter (signal processing), business, Signal, Electronic circuit

Abstract

In this paper, a continuous-time differential type multi-signal parallel driving architecture touch screen sensing circuit for projective capacitive type panel is presented. In order to further enhance the Signal-to-Noise Ratio (SNR), a new transmitter (TX) architecture is proposed with parallel signal processing algorithm. In this work, charge amplifiers with built-in band-pass filter are designed that filter out low frequency noise and common-mode noise simultaneously. Conventional approaches in continuous-time operation with band-pass filter suffer from a synchronization problem in the case of multi-signal parallel driving. In this work, a built-in delay calibration circuit is proposed that can align signal timing for TX signal and adjacent receiver (RX) sensing line. This proposed architecture enables multi-signal parallel driving in continuous-time operation for projective capacitive sensing circuits. The proposed work supports 16 × 8 mutual capacitive touch screen panel (TSP). TSP load is 12.5 kΩ and 40 pF with frame rate of 200 Hz and 58 dB SNR. Power dissipation is 46 mW.

Published

2014

18. Algorithm for improving SNR using high voltage and differential Manchester code for capacitive touch screen panel.

Author

Hyunggun Ma, Sanghyun Heo, Jae Joon Kim, and Bien, Franklin

Subjects

*ALGORITHMS, *HIGH voltages, *TOUCH screens, *CAPACITIVE sensors

Abstract

An algorithm for a capacitive touch screen panel that can make the sum of the signal into '0' for the use of high voltage is presented. The differential Manchester code is combined with the Walsh-Hadamard code to generate an input coded signal. Owing to the property of the differential Manchester code, the Moore-Penrose pseudoinverse matrix is employed to decode-mutual capacitance from the received signal. As only the variation between the un-touch and touch condition is detected at the receiver, a high-voltage input coded signal is used. Unlike a normal touch system, the decoded sensing capacitance in the proposed algorithm does not have an absolute value. Positive decoded capacitance is the un-touch condition and negative decoded capacitance is the touch condition. The simulated signal-to-noise ratio (SNR) of the proposed algorithm is 27.9 dB, which is 8.26 dB higher than SNR in not return to zero (NRZ). [ABSTRACT FROM AUTHOR]

Published

2014