A high performance, ultra-low power, fully differentia 2nd-order continuous-time Σ∆ analogue-to-digital modulator for cardiac pacemakers is presented in this paper. The entire design procedure is described in detail from the high-level system synthesis in both discrete and continuous-time domain, to the low-level circuit implementation of key functional blocks of the modulator. The power consumption of the designed modulator is rated at 182nA from a 1.2V power supply, meeting the ultra-low power requirement of the cardiac pacemaker applications. A 65nm CMOS technology is employed to implement the Σ∆ modulator. The modulator achieves a simulated SNR of 53.8dB over a 400 Hz signal bandwidth, with 32KHz sampling frequency and an oversampling r...
A low-power mixed-signal IC for implantable pacemakers is presented. The proposed system features th...
The manuscript describes the design and implementation of a low-power, fully differential switched-c...
The biomedical devices often operate only with a battery, e.g., blood glucose monitor, pacemaker. Th...
Abstract—A high performance, ultra-low power, fully differen-tial 2nd-order continuous-time Σ ∆ anal...
A high performance, ultra-low power, fully differential 2 nd-order continuous-time ∑Δ analogue-to-di...
A high performance, ultra-low power, fully differential 2nd-order continuous-time Sigma Delta analog...
Power reduction is a central priority in battery-powered medical implantable devices, particularly p...
Implantable biomedical devices can highly benefit from submicrometer CMOS technologies both in terms...
Biomedical electronics has gained significant attention in healthcare. A general biomedical device c...
This paper proposes an architecture design approach for a wideband continuous-time (CT) ΣΔ modulator...
An ultra-low-voltage low-power switched-capacitor (SC) delta-sigma (ΔΣ) modulator running at a suppl...
This work presents an input stage for a cardiac pacemaker fully integrated in 0.35-\u3bcm CMOS techn...
When the heart does not function properly, an artificial pacemaker is needed to correct the heart be...
Achieving an accurate sub-Hz high-pass (HP) cutoff frequency and simultaneously a high accuracy of t...
An ultra low power cardiac sensing channel for pacemaker applications, designed in 0.6um HV CMOS tec...
A low-power mixed-signal IC for implantable pacemakers is presented. The proposed system features th...
The manuscript describes the design and implementation of a low-power, fully differential switched-c...
The biomedical devices often operate only with a battery, e.g., blood glucose monitor, pacemaker. Th...
Abstract—A high performance, ultra-low power, fully differen-tial 2nd-order continuous-time Σ ∆ anal...
A high performance, ultra-low power, fully differential 2 nd-order continuous-time ∑Δ analogue-to-di...
A high performance, ultra-low power, fully differential 2nd-order continuous-time Sigma Delta analog...
Power reduction is a central priority in battery-powered medical implantable devices, particularly p...
Implantable biomedical devices can highly benefit from submicrometer CMOS technologies both in terms...
Biomedical electronics has gained significant attention in healthcare. A general biomedical device c...
This paper proposes an architecture design approach for a wideband continuous-time (CT) ΣΔ modulator...
An ultra-low-voltage low-power switched-capacitor (SC) delta-sigma (ΔΣ) modulator running at a suppl...
This work presents an input stage for a cardiac pacemaker fully integrated in 0.35-\u3bcm CMOS techn...
When the heart does not function properly, an artificial pacemaker is needed to correct the heart be...
Achieving an accurate sub-Hz high-pass (HP) cutoff frequency and simultaneously a high accuracy of t...
An ultra low power cardiac sensing channel for pacemaker applications, designed in 0.6um HV CMOS tec...
A low-power mixed-signal IC for implantable pacemakers is presented. The proposed system features th...
The manuscript describes the design and implementation of a low-power, fully differential switched-c...
The biomedical devices often operate only with a battery, e.g., blood glucose monitor, pacemaker. Th...