Your search keyword '"biomedical signal acquisition"' showing total 11 results

1. Wireless Device for Biomedical Signal Acquisition with Dry Electrodes on an e-Bike

Author

Klaić, L., Čuljak, I., Stanešić, A., Vrhoci, I., Šajinović, P., Cifrek, M., Džapo, H., Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Bonačić Bartolin, Petra, editor, Allen, Matthew, editor, and Sutcliffe, Michael, editor

Published

2024

2. A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator With OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition.

Author

Lee, Shuenn-Yuh, Lee, Hao-Yun, Kung, Chia-Ho, Su, Po-Han, and Chen, Ju-Yi

Abstract

This work presents a third-order high-pass sigma-delta modulator (HPSDM) for biomedical signal acquisition. The operational amplifier (op-amp) sharing and noise-coupling techniques are adopted to reduce the required quantity of op-amps and add a noise-shaping order, which can achieve low power consumption and high resolution. A novel switched-capacitor architecture is proposed to suppress the increasing in-band noise and alleviate the circuit sensitivity to capacitor mismatch in the high-pass integrator. The proposed HPSDM was fabricated in a 0.18-μm standard CMOS process. Measurement results reveal that the proposed HPSDM has a signal-to-noise and distortion ratio (SNDR) of 75.26/74 dB in 200 Hz bandwidth and consumes 1.52/0.8 μW under 1.2/1 V supply voltage, which can achieve a peak Schreier Figure-of-Merit of 156.45/157.98 dB and a peak Walden FoM of 0.802/0.488 pJ/conv. [ABSTRACT FROM AUTHOR]

Published

2022

3. Towards a Singing Voice Multi-Sensor Analysis Tool: System Design, and Assessment Based on Vocal Breathiness

Author

Evangelos Angelakis, Natalia Kotsani, and Anastasia Georgaki

Subjects

biomedical signal acquisition, singing voice, data processing, breathiness, electroglottography, vocal mechanism, Chemical technology, TP1-1185

Abstract

Singing voice is a human quality that requires the precise coordination of numerous kinetic functions and results in a perceptually variable auditory outcome. The use of multi-sensor systems can facilitate the study of correlations between the vocal mechanism kinetic functions and the voice output. This is directly relevant to vocal education, rehabilitation, and prevention of vocal health issues in educators; professionals; and students of singing, music, and acting. In this work, we present the initial design of a modular multi-sensor system for singing voice analysis, and describe its first assessment experiment on the ‘vocal breathiness’ qualitative characteristic. A system case study with two professional singers was conducted, utilizing signals from four sensors. Participants sung a protocol of vocal trials in various degrees of intended vocal breathiness. Their (i) vocal output, (ii) phonatory function, and (iii) respiratory behavior-per-condition were recorded through a condenser microphone (CM), an Electroglottograph (EGG), and thoracic and abdominal respiratory effort transducers (RET), respectively. Participants’ individual respiratory management strategies were studied through qualitative analysis of RET data. Microphone audio samples breathiness degree was rated perceptually, and correlation analysis was performed between sample ratings and parameters extracted from CM and EGG data. Smoothed Cepstral Peak Prominence (CPPS) and vocal folds’ Open Quotient (OQ), as computed with the Howard method (HOQ), demonstrated the higher correlation coefficients, when analyzed individually. DECOM method-computed OQ (DOQ) was also examined. Interestingly, the correlation coefficient of pitch difference between estimates from CM and EGG signals appeared to be (based on the Pearson correlation coefficient) statistically insignificant (a result that warrants investigation in larger populations). The study of multi-variate models revealed even higher correlation coefficients. Models studied were the Acoustic Breathiness Index (ABI) and the proposed multiple regression model CDH (CPPS, DOQ, and HOQ), which was attempted in order to combine analysis results from microphone and EGG signals. The model combination of ABI and the proposed CDH appeared to yield the highest correlation with perceptual breathiness ratings. Study results suggest potential for the use of a completed system version in vocal pedagogy and research, as the case study indicated system practicality, a number of pertinent correlations, and introduced topics with further research possibilities.

Published

2021

4. Analog front-end design for biomedical signal acquisition systems

Author

Ansari, Mohd. Samar

Published

2019

5. Development of Software for Continuous Biomedical Signal Acquisition Using ADS1292R Integrated Circuit

Author

Kisegi, Ana Marija and Cifrek, Mario

Subjects

ADS1292R, Keil µVision, srce, FreeRTOS, ECG, biomedical systems, TEHNIČKE ZNANOSTI. Računarstvo, TEHNIČKE ZNANOSTI. Elektrotehnika, elektrode, heart, impedance pneumography, impedancijska pneumografija, PyQt, biomedical signal acquisition, electrodes, TECHNICAL SCIENCES. Electrical Engineering, TECHNICAL SCIENCES. Computing, akvizicija biomedicinskih signala, respiracija, biomedicinski sustavi, STM32F4 Discovery Board, EKG, respiration, Python

Abstract

Kontinuirano mjerenje biomedicinskih signala dobiva sve više na značaju razvojem novih uređaja, čija je uloga korištenje izvan zdravstvenih ustanova. Prijenosni i nosivi uređaji postaju i medicinski važni zbog jednostavnosti korištenja i točnosti detekcije. Korišteni razvojni sustav se sastoji od dvije tiskane pločice i elektroda. Jedna od tiskanih pločica sadrži integrirani krug ADS1292R i potrebne pasivne komponente, a druga pločica je STM32F4 Discovery Board s mikrokontrolerom, koji upravlja radom integriranog kruga. Programska okruženje Keil µVision je korišteno za razvoj programske potpora za mikrokontroler, te se koristio FreeRTOS. Koristeći FreeRTOS se programski kod dijeli na manje cjeline, zadatke. Jedan od zadatka radi inicijalizaciju ADS1292R, te ga ispravno priprema za mjerenje, dok drugi zadatak, koji je višeg prioriteta, obavlja mjerenje i šalje rezultate mjerenja na računalo. Napravljena je aplikacija u Pythonu za akviziciju, prikaz, spremanje i obradu biomedicinskih signala u stvarnom vremenu. Continuous biomedical signal measurement is becoming increasingly important with the development of new devices which can be used outside of the healthcare facilities. Portable and wearable devices are becoming more medically important due to their ease of use and accuracy of detection. The development system consists of two printed circuit boards and electrodes. The first board contains ADS1292R and all necessary passive components, while the second board is STM32F4Discovery Board with a microcontroller. Microcontroller controls the operation of ADS1292R. Keil µVision was used to develop software for microcontroller and FreeRTOS was also used. While using FreeRTOS, programming code can be divided into smaller parts, tasks. One of the tasks is initializing ADS1292R and prepares it for measurement, while the other task, which has higher priority, was used to obtain measurement data and to send acquired data to a computer. An application in Python was created for real – time acquisition, display, saving and processing of biomedical signals.

Published

2020

6. Recent developments and trends in biomedical sensors

Author

Engin, Mehmet, Demirel, Alparslan, Engin, Erkan Zeki, and Fedakar, Musa

Subjects

*BIOSENSORS, *DETECTORS, *TEXTILE industry, *ENGINEERING instruments

Abstract

Abstract: The aim of this paper is to give brief information on recent developments and trends in biomedical sensors. We also tried to reveal the close correlation between biomedical sensors and smart (intelligent) textiles. We emphasized on the concept of wearable, as we have considered this notion the transition zone between the contemporary biomedical sensors and smart (intelligent) textiles. [Copyright &y& Elsevier]

Published

2005

7. A Microcontroller-Based Portable Electrocardiograph Recorder.

Author

Segura-Juárez, José J., Cuesta-Frau, David, Samblas-Pena, Luis, and Aboy, Mateo

Subjects

*ELECTRONIC controllers, *SEMICONDUCTOR industry, *ELECTRIC controllers, *PROCESS control systems, *PROGRAMMABLE controllers, *ELECTROCARDIOGRAPHS

Abstract

We describe a low cost portable Holter design that can be implemented with off-the-shelf components. The recorder is battery powered and includes a graphical display and keyboard. The recorder is capable of acquiring up to 48 hours of continuous electrocardiogram data at a sample rate of up to 250 Hz. [ABSTRACT FROM AUTHOR]

Published

2004

8. Towards a Singing Voice Multi-Sensor Analysis Tool: System Design, and Assessment Based on Vocal Breathiness.

Author

Angelakis, Evangelos, Kotsani, Natalia, and Georgaki, Anastasia

Subjects

VOICE analysis, SYSTEMS design, PEARSON correlation (Statistics), VOCAL cords, SINGING, MODULAR design

Abstract

Singing voice is a human quality that requires the precise coordination of numerous kinetic functions and results in a perceptually variable auditory outcome. The use of multi-sensor systems can facilitate the study of correlations between the vocal mechanism kinetic functions and the voice output. This is directly relevant to vocal education, rehabilitation, and prevention of vocal health issues in educators; professionals; and students of singing, music, and acting. In this work, we present the initial design of a modular multi-sensor system for singing voice analysis, and describe its first assessment experiment on the 'vocal breathiness' qualitative characteristic. A system case study with two professional singers was conducted, utilizing signals from four sensors. Participants sung a protocol of vocal trials in various degrees of intended vocal breathiness. Their (i) vocal output, (ii) phonatory function, and (iii) respiratory behavior-per-condition were recorded through a condenser microphone (CM), an Electroglottograph (EGG), and thoracic and abdominal respiratory effort transducers (RET), respectively. Participants' individual respiratory management strategies were studied through qualitative analysis of RET data. Microphone audio samples breathiness degree was rated perceptually, and correlation analysis was performed between sample ratings and parameters extracted from CM and EGG data. Smoothed Cepstral Peak Prominence (CPPS) and vocal folds' Open Quotient (OQ), as computed with the Howard method (HOQ), demonstrated the higher correlation coefficients, when analyzed individually. DECOM method-computed OQ (DOQ) was also examined. Interestingly, the correlation coefficient of pitch difference between estimates from CM and EGG signals appeared to be (based on the Pearson correlation coefficient) statistically insignificant (a result that warrants investigation in larger populations). The study of multi-variate models revealed even higher correlation coefficients. Models studied were the Acoustic Breathiness Index (ABI) and the proposed multiple regression model CDH (CPPS, DOQ, and HOQ), which was attempted in order to combine analysis results from microphone and EGG signals. The model combination of ABI and the proposed CDH appeared to yield the highest correlation with perceptual breathiness ratings. Study results suggest potential for the use of a completed system version in vocal pedagogy and research, as the case study indicated system practicality, a number of pertinent correlations, and introduced topics with further research possibilities. [ABSTRACT FROM AUTHOR]

Published

2021

9. A Near-Infrared Heart Rate Measurement IC With Very Low Cutoff Frequency Using Current Steering Technique.

Author

Alex Wong, Kong-Pang Pun, Yuan-Ting Zhang, and Kevin Hung

Subjects

*HEART rate monitoring, *COMPLEMENTARY metal oxide semiconductors, *LIGHT emitting diodes, *SEMICONDUCTOR diodes, *ELECTROLUMINESCENT devices, *SEMICONDUCTORS

Abstract

A near-infrared heart-rate measurement IC that processes the photoplethysmographic signal was designed using a 0.35-μm CMOS technology. The IC consists of a current-to-voltage (I-V) converter, a buffer, a sample-and-hold circuit, a second-order continuous-time low-pass filter (CT-LPF), a comparator, and a timing circuit that is used to pulse the external light-emitting diode with a very low duty cycle to reduce its power consumption. The current steering technique is employed in the design of the CT-LPF to meet the requirement for very low cutoff frequency. The circuit operates from a 3-V lithium battery, occupies a core area of 0.46 mm² and has a power consumption of 4.5 mW The measurement results corroborate with simulation results and show that the CT-LPF can achieve a cutoff frequency of as low as 0.25 Hz. This demonstrates the feasibility of current steering technique in the design of filter for low-frequency application. [ABSTRACT FROM AUTHOR]

Published

2005

10. Integrated 16-Channel Neural Recording Circuit with SPI Interface and Error Correction Code in 130 nm CMOS Technology

Author

Bahr, Andreas, Abu Saleh, Lait, Schröder, Dietmar, Krautschneider, Wolfgang, Bahr, Andreas, Abu Saleh, Lait, Schröder, Dietmar, and Krautschneider, Wolfgang

Abstract

In the research of neural diseases like epilepsy and schizophrenia genetic mouse models play a very important role. Dysfunctions during early brain development might cause these diseases. The analysis of the brain signals is the key to understand this process and develop treatments. To enable the acquisition of brain signals from neonatal mice, an integrated circuit for neural recording is presented. It is minimized for low area consumption and can be placed in a miniaturized system on the head of the mouse. It is intended to acquire the local field and action potentials from the brain. 16 analog input channels are implemented. The biomedical signals are amplified with analog re-amplifiers. Two parallel structures of 8:1 multiplexer, post-amplifier and ADC are implemented to digitize the signals. The post-amplifier has programmable gain and high driving capability. The ADC is implemented as a 10 bit SAR ADC. Digital SPI interfacing is used to reduce the number of transmission lines. Reed Solomon Error Correction Coding has been implemented to enable error correction. The mixed-signal integrated circuit has been successfully implemented in a 130 nm CMOS technology. It is optimized for low area consumption; the channel density is approximately 10 channels/mm².

Published

2017

11. Integrated 16-Channel Neural Recording Circuit with SPI Interface and Error Correction Code in 130Nm CMOS Technology

Author

Bahr, Andreas, Abu Saleh, Lait, Schröder, Dietmar, and Krautschneider, Wolfgang

Subjects

Computer science, Integrated circuit, Multiplexer, law.invention, law, Reed–Solomon error correction, SPI Interface, Integrated Circuit, Biomedical Signal Acquisition, Technik [600], 130nm CMOS technology, business.industry, Mixed-signal Integrated Circuit, Error Correction Code, Mixed-signal integrated circuit, Successive approximation ADC, Technik, CMOS, Interfacing, Neural recording, ddc:004, business, Error detection and correction, ddc:600, Computer hardware

Abstract

In the research of neural diseases like epilepsy and schizophrenia genetic mouse models play a very important role. Dysfunctions during early brain development might cause these diseases. The analysis of the brain signals is the key to understand this process and develop treatments. To enable the acquisition of brain signals from neonatal mice, an integrated circuit for neural recording is presented. It is minimized for low area consumption and can be placed in a miniaturized system on the head of the mouse. It is intended to acquire the local field and action potentials from the brain. 16 analog input channels are implemented. The biomedical signals are amplified with analog pre-amplifiers. Two parallel structures of 8:1 multiplexer, post-amplifier and ADC are implemented to digitize the signals. The post-amplifier has programmable gain and high driving capability. The ADC is implemented as a 10 bit SAR ADC. Digital SPI interfacing is used to reduce the number of transmission lines. Reed Solomon Error Correction Coding has been implemented to enable error correction. The mixed-signal integrated circuit has been successfully implemented in a 130 nm CMOS technology. It is optimized for low area consumption; the channel density is approximately 10 channels/mm².

Published

2016