ABSTRACT This paper shows the implementation of a fully integrated G m -C 0.5-7Hz bandpass filter-amplifier with gain G=400, for a piezoelectric accelerometer which is part of a rate adaptive pacemaker. The fabricated circuit operates up to 2V power supply, consumes only 230nA current, and achives 2.1µV rms input noise. Detailed circuit specifications, measurements, and a comparative analysis of the system performance are presented
This paper presents a 52 μW heart-rate measurement interface for wearable applications, fabricated o...
In the emerging field of wearable systems for remote monitoring of physiological parameters, the mea...
Pacemakers that augment heart rate (HR) by sensing body motion have been the most frequently prescri...
This paper shows the implementation of a fully integrated Gm-C 0.5-7Hz bandpass filter-amplifier wit...
PostprintThis paper shows the implementation of a fully integrated Gm-C 0.5-7Hz bandpass filter-ampl...
PostprintThe design and test of a micropower signal conditioning circuit for a piezoresistive accele...
In this paper, the design methodology of a fully integrated gm-C, 0.5-7Hz band-pass amplifier is pre...
This paper presents a comparative study of activity sensors: piezoelectric and accelerometer sensor,...
When the heart does not function properly, an artificial pacemaker is needed to correct the heart be...
In this paper, the design methodology of a fully integrated gm-C, 0.5-7Hz band-pass amplifier is pre...
The advancement in sensing materials has led to the growth of the sensing technologies in flexible a...
Nowadays, the technology advancements of signal processing, low-voltage low-power circuits and minia...
A low-power front-end for a pacemaker atrial sensing channel based on peak detection is presented. T...
peer reviewedTogether with a charge or voltage amplifier, piezoelectric sensors are commonly used to...
Abstract — A low-power fully integrated bioamplifier is presented that can amplify signals in the ra...
This paper presents a 52 μW heart-rate measurement interface for wearable applications, fabricated o...
In the emerging field of wearable systems for remote monitoring of physiological parameters, the mea...
Pacemakers that augment heart rate (HR) by sensing body motion have been the most frequently prescri...
This paper shows the implementation of a fully integrated Gm-C 0.5-7Hz bandpass filter-amplifier wit...
PostprintThis paper shows the implementation of a fully integrated Gm-C 0.5-7Hz bandpass filter-ampl...
PostprintThe design and test of a micropower signal conditioning circuit for a piezoresistive accele...
In this paper, the design methodology of a fully integrated gm-C, 0.5-7Hz band-pass amplifier is pre...
This paper presents a comparative study of activity sensors: piezoelectric and accelerometer sensor,...
When the heart does not function properly, an artificial pacemaker is needed to correct the heart be...
In this paper, the design methodology of a fully integrated gm-C, 0.5-7Hz band-pass amplifier is pre...
The advancement in sensing materials has led to the growth of the sensing technologies in flexible a...
Nowadays, the technology advancements of signal processing, low-voltage low-power circuits and minia...
A low-power front-end for a pacemaker atrial sensing channel based on peak detection is presented. T...
peer reviewedTogether with a charge or voltage amplifier, piezoelectric sensors are commonly used to...
Abstract — A low-power fully integrated bioamplifier is presented that can amplify signals in the ra...
This paper presents a 52 μW heart-rate measurement interface for wearable applications, fabricated o...
In the emerging field of wearable systems for remote monitoring of physiological parameters, the mea...
Pacemakers that augment heart rate (HR) by sensing body motion have been the most frequently prescri...