A 155-dB Dynamic Range Current Measurement Front End for Electrochemical Biosensing

Dai, Shanshan; Perera, Rukshan T.; Yang, Zi; Rosenstein, Jacob K.

doi:10.1109/tbcas.2016.2612581

Cited by 37 publications

(20 citation statements)

References 25 publications

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“…2(b), or the integrate-and-fire (IAF) modulator of Fig. 2(c) combined with an external ADC for extending its overall dynamic range [8]. The use of current conveyors for later current-to-frequency conversion is also attractive especially for directly encoding into an output RF signal [10], [11].…”

Section: B State-of-the-art Potentiostatic Integrated Circuitsmentioning

confidence: 99%

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A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

et al. 2020

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Wearable electrochemical sensors represent a point of convergence between lab-on-a-chip technologies, advanced microelectronics and connected intelligence. These three pillars establish data flow from analytes present in body fluids, to the Cloud infrastructures towards next-generation personal healthcare and wellness. The design of electrode-embedded interfacing instrumentation in advanced CMOS technology nodes offer a number of challenges spanning from ultra-low power operation, small footprint, sufficient general purpose operability, and compatibility with advanced CMOS technology nodes. This paper presents a low-power frontend with extended amperometric dynamic range and wide potentiostatic range for electrochemical transducers with Delta-Sigma () digital output. The second-order single-bit continuoustime modulator architecture reuses the electrochemical cell dynamic characteristics for quantization noise shaping, while the differential potentiostat enables 1.8 V pp of control range under single 1.2-V supply. The proposed frontend has been integrated in TSMC 65-nm CMOS technology occupying 0.07 mm 2. From electrical and electrochemical tests, the micro potentiostat achieves a Signal-to-Distortion-and-Noise of 80 dB with 15-µW power consumption and a combined multi-scale dynamic range of 105 dB.

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Section: B State-of-the-art Potentiostatic Integrated Circuitsmentioning

confidence: 99%

“…State of the art potentiostats: differential amplifier based[5] (a), dual-slope ADC[6],[7] (b), extended-DR IAF ADC[8] (c), first-order single-bit SC[13] (d) and SI[15] (e) CT M ADCs.…”

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confidence: 99%

A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

et al. 2020

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“…Most of the quasi-digital converters proposed in the literature focus on achieving a wide dynamic range (e.g., [12][13][14][15][16]), whereas other issues such as robustness and simplicity have not been fully addressed, as required for low-cost, low-power readout circuits for practical implementations. Accuracy and robustness of most quasi-digital converters strongly depend on a bandgap voltage reference or on high performance building blocks, such as low-offset and high-speed comparators, resulting in higher complexity and/or power consumption [17,18].…”

Section: Introductionmentioning

confidence: 99%

A Highly Robust Interface Circuit for Resistive Sensors

et al. 2019

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The signal from a resistive sensor must be converted into a digital signal to be compatible with a computer through an interface circuit. Resistance-to-Period converter, used as interface, is preferred if the resistance variations are very large. This paper presents the structure of an interface circuit for resistive sensors that is highly robust to component and power supply variations. Robustness is achieved by using the ratiometric approach, thus complex circuits or highly accurate voltage references are not necessary. To validate the proposed approach, a prototype was implemented using discrete components. Measurements were carried out considering a variation of ±35% in the single supply voltage and a range from 1 k Ω to 1 M Ω .

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“…I-to-PDM (pulse density modulation) potentiostats: the readout current modulates the density of a pulse repetition in time [128,[152][153][154]; 4.…”

mentioning

confidence: 99%

“…The circuit of Figure 17b avoids the problem related to a non-zero T pulse by alternating the integration and reset phase on two nominally identical capacitors C 1 and C 2 [153]. The modulator also features a double comparator to detect separately positive and negative I W .…”

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confidence: 99%

CMOS Interfaces for Internet-of-Wearables Electrochemical Sensors: Trends and Challenges

et al. 2019

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Smart wearables, among immediate future IoT devices, are creating a huge and fast growing market that will encompass all of the next decade by merging the user with the Cloud in a easy and natural way. Biological fluids, such as sweat, tears, saliva and urine offer the possibility to access molecular-level dynamics of the body in a non-invasive way and in real time, disclosing a wide range of applications: from sports tracking to military enhancement, from healthcare to safety at work, from body hacking to augmented social interactions. The term Internet of Wearables (IoW) is coined here to describe IoT devices composed by flexible smart transducers conformed around the human body and able to communicate wirelessly. In addition the biochemical transducer, an IoW-ready sensor must include a paired electronic interface, which should implement specific stimulation/acquisition cycles while being extremely compact and drain power in the microwatts range. Development of an effective readout interface is a key element for the success of an IoW device and application. This review focuses on the latest efforts in the field of Complementary Metal–Oxide–Semiconductor (CMOS) interfaces for electrochemical sensors, and analyses them under the light of the challenges of the IoW: cost, portability, integrability and connectivity.

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A 155-dB Dynamic Range Current Measurement Front End for Electrochemical Biosensing

Cited by 37 publications

References 25 publications

A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

A Highly Robust Interface Circuit for Resistive Sensors

CMOS Interfaces for Internet-of-Wearables Electrochemical Sensors: Trends and Challenges

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A 155-dB Dynamic Range Current Measurement Front End for Electrochemical Biosensing

Cited by 37 publications

References 25 publications

A 15-μW 105-dB 1.8-Vpp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

A 15-μW 105-dB 1.8-Vpp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

A Highly Robust Interface Circuit for Resistive Sensors

CMOS Interfaces for Internet-of-Wearables Electrochemical Sensors: Trends and Challenges

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About

A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology

A 15-μW 105-dB 1.8-V_pp Potentiostatic Delta-Sigma Modulator for Wearable Electrochemical Transducers in 65-nm CMOS Technology