Your search keyword '"Tang, Kea-Tiong"' showing total 6 results

1. An Inductive Power and Data Telemetry Subsystem With Fast Transient Low Dropout Regulator for Biomedical Implants.

Author

Lin, Yu-Po and Tang, Kea-Tiong

Abstract

This paper presents a capacitorless low-dropout (LDO) regulator with fast transient response and data reverse telemetry circuit for fully implantable wireless transmission applications. We propose a novel hybrid feedback structure using high-frequency compensation technology to achieve a rapid transient response for the LDO regulator. To reduce the size of the implant and transmit neural recordings through the same coil without interfering with power transmission, the load-shift-key (LSK) modulation technique is adopted for back data telemetry. The proposed implantable chip, fabricated using commercial 0.18~\mum complementary metal oxide semiconductor technology, yielded an output power of 15 mW. Under 1.15 V operation voltage, the maximum overshoot and undershoot voltages were less than 45 mV and 55 mV, respectively, for a 15 mA full-load current whose rising and falling time were less than 100 ns. The proposed LSK transceiver uses a digitized demodulator to improve bandwidth efficiency for low carrier frequency operation. [ABSTRACT FROM PUBLISHER]

Published

2016

2. A Battery-Less, Implantable Neuro-Electronic Interface for Studying the Mechanisms of Deep Brain Stimulation in Rat Models.

Author

Lin, Yu-Po, Yeh, Chun-Yi, Huang, Pin-Yang, Wang, Zong-Ye, Cheng, Hsiang-Hui, Li, Yi-Ting, Chuang, Chi-Fen, Huang, Po-Chiun, Tang, Kea-Tiong, Ma, Hsi-Pin, Chang, Yen-Chung, Yeh, Shih-Rung, and Chen, Hsin

Abstract

Although deep brain stimulation (DBS) has been a promising alternative for treating several neural disorders, the mechanisms underlying the DBS remain not fully understood. As rat models provide the advantage of recording and stimulating different disease-related regions simultaneously, this paper proposes a battery-less, implantable neuro-electronic interface suitable for studying DBS mechanisms with a freely-moving rat. The neuro-electronic interface mainly consists of a microsystem able to interact with eight different brain regions bi-directionally and simultaneously. To minimize the size of the implant, the microsystem receives power and transmits data through a single coil. In addition, particular attention is paid to the capability of recording neural activities right after each stimulation, so as to acquire information on how stimulations modulate neural activities. The microsystem has been fabricated with the standard 0.18 \mum CMOS technology. The chip area is 7.74 mm^2, and the microsystem is able to operate with a single supply voltage of 1 V. The wireless interface allows a maximum power of 10 mW to be transmitted together with either uplink or downlink data at a rate of 2 Mbps or 100 kbps, respectively. The input referred noise of recording amplifiers is 1.16 \muVrms, and the stimulation voltage is tunable from 1.5 V to 4.5 V with 5-bit resolution. After the electrical functionality of the microsystem is tested, the capability of the microsystem to interface with rat brain is further examined and compared with conventional instruments. All experimental results are presented and discussed in this paper. [ABSTRACT FROM PUBLISHER]

Published

2016

3. A Fully Integrated Nose-on-a-Chip for Rapid Diagnosis of Ventilator-Associated Pneumonia.

Author

Chiu, Shih-Wen, Wang, Jen-Huo, Chang, Kwuang-Han, Chang, Ting-Hau, Wang, Chia-Min, Chang, Chia-Lin, Tang, Chen-Ting, Chen, Chien-Fu, Shih, Chung-Hung, Kuo, Han-Wen, Wang, Li-Chun, Chen, Hsin, Hsieh, Chih-Cheng, Chang, Meng-Fan, Liu, Yi-Wen, Chen, Tsan-Jieh, Yang, Chia-Hsiang, Chiueh, Herming, Shyu, Juyo-Min, and Tang, Kea-Tiong

Abstract

Ventilator-associated pneumonia (VAP) still lacks a rapid diagnostic strategy. This study proposes installing a nose-on-a-chip at the proximal end of an expiratory circuit of a ventilator to monitor and to detect metabolite of pneumonia in the early stage. The nose-on-a-chip was designed and fabricated in a 90-nm 1P9M CMOS technology in order to downsize the gas detection system. The chip has eight on-chip sensors, an adaptive interface, a successive approximation analog-to-digital converter (SAR ADC), a learning kernel of continuous restricted Boltzmann machine (CRBM), and a RISC-core with low-voltage SRAM. The functionality of VAP identification was verified using clinical data. In total, 76 samples infected with pneumonia (19 Klebsiella, 25 Pseudomonas aeruginosa, 16 Staphylococcus aureus, and 16 Candida) and 41 uninfected samples were collected as the experimental group and the control group, respectively. The results revealed a very high VAP identification rate at 94.06% for identifying healthy and infected patients. A 100% accuracy to identify the microorganisms of Klebsiella, Pseudomonas aeruginosa, Staphylococcus aureus, and Candida from VAP infected patients was achieved. This chip only consumes 1.27 mW at a 0.5 V supply voltage. This work provides a promising solution for the long-term unresolved rapid VAP diagnostic problem. [ABSTRACT FROM PUBLISHER]

Published

2014

4. A Low-Power Electronic Nose Signal-Processing Chip for a Portable Artificial Olfaction System.

Author

Tang, Kea-Tiong, Chiu, Shih-Wen, Chang, Meng-Fan, Hsieh, Chih-Cheng, and Shyu, Jyuo-Min

Abstract

The bulkiness of current electronic nose (E-Nose) systems severely limits their portability. This study designed and fabricated an E-Nose signal-processing chip by using TSMC 0.18-\mum 1P6M complementary metal–oxide semiconductor technology to overcome the need to connect the device to a personal computer, which has traditionally been a major stumbling block in reducing the size of E-Nose systems. The proposed chip is based on a conductive polymer sensor array chip composed of multiwalled carbon nanotubes. The signal-processing chip comprises an interface circuit, an analog-to-digital converter, a memory module, and a microprocessor embedded with a pattern-recognition algorithm. Experimental results have verified the functionality of the proposed system, in which the E-Nose signal-processing chip successfully classified three odors, carbon tetrachloride (CCl4), chloroform (CHCl3), and 2-Butanone (MEK), demonstrating its potential for portable applications. The power consumption of this signal-processing chip was maintained at a very low 2.81 mW using a 1.8-V power supply, making it highly suitable for integration as an electronic nose system-on-chip. [ABSTRACT FROM PUBLISHER]

Published

2011

5. Editorial.

Author

Wang, Guoxing, Constandinou, Timothy G., and Tang, Kea-Tiong

Published

2020

6. Guest Editorial—ISCAS 2013 Special Issue.

Author

Tang, Kea-Tiong and Wisland, Dag T.

Abstract

The eight articles in this special section have been selected from papers presented at the Biomedical and Life-Science Circuits and Systems,Biomedical Information Processing, Implantable and Wearable Technology, and Biomedical Algorithm sessions of the 2013 International Symposium on Circuits and Systems (ISCAS 2013) that was held in Beijing, China, May 19-23, 2013. [ABSTRACT FROM PUBLISHER]

Published

2014