Low-power MEMS pressure sensor for wireless biomedical applications

García-Alonso, Santiago; Bautista, Tomás; Sosa, Javier; Monzón-Verona, José Miguel; Santana-Martín, Francisco Jorge; Navarro-Botello, V.; Santana-Cabrera, Jorge; Montiel–Nelson, Juan A.

doi:10.1109/mwscas.2011.6026544

Cited by 6 publications

(4 citation statements)

References 10 publications

(11 reference statements)

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“…Piezoresistive and capacitive sensing technologies are the most commonly utilized technologies, which have been widely used to measure strain, pressure and acceleration [1], [2]. They both typically consume power in the μW to mW range [3]. Alternative technologies, such as tunneling current sensing, are attractive for low power applications because the typical tunneling current is in the nA range.…”

Section: Introductionmentioning

confidence: 99%

Low Power Tunneling Current Strain Sensor Using MOS Capacitors

Zhu

McNamara

2015

J. Microelectromech. Syst.

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Although microelectromechanical systems (MEMS) strain sensors have been widely researched and commercialized for decades, the increasing requirement for low power sensors is motivating research on new techniques. We present a new technology to make very low power sensors by measuring the tunneling current through a MOS capacitor. The tunneling current can be in the nanoamp range, which is a good alternative for low power sensing. We demonstrate a power consumption of a couple of nano-Watts with a minimum detectable strain of 0.00036%. The fabrication process is very simple and compatible with CMOS processes. We find that noise is lower in inversion region, and therefore, it is better to bias device to inversion region. To study the sensitivity in the inversion region, a model was developed to compute the strained tunneling current comprised of electron conduction band tunneling current and electron valence band tunneling current. The model fits our experiment very well.[2014-0127]

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Section: Introductionmentioning

confidence: 99%

Low Power Tunneling Current Strain Sensor Using MOS Capacitors

Zhu

McNamara

2015

J. Microelectromech. Syst.

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“…Piezoresistive and capacitive sensing technologies are the most common technologies, which have been widely used to measure strain, pressure and acceleration [1,2]. They both typically consume power from μW to mW [3]. Considering the piezoresistive sensors, to achieve low power consumption, we have to decrease doping concentration.…”

Section: Introductionmentioning

confidence: 99%

“…Considering the piezoresistive sensors, to achieve low power consumption, we have to decrease doping concentration. For example, to have a minimum detectable strain of 0.0005% (which is our device's resolution), the doping concentration should be around 10 16 atoms/cm 3 [4]. This doping concentration gives a resistivity of 1 ohm-cm.…”

Section: Introductionmentioning

confidence: 99%

Low Power Strain Sensing Using Tunneling Current Through Mos Capacitors

Zhu¹,

McNamara²

2012

2012 Solid-State, Actuators, and Microsystems Workshop Technical Digest

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Although MEMS pressure sensors and accelerometers have been widely researched and commercialized for decades, the recently increasing requirement for low power sensors is motivating research on new techniques. We present a new technology to make very low power sensors by measuring the tunneling current (Ig) through a MOS capacitor. The tunneling current can be in the nano-amp range, which is a good alternative for low power sensing. We demonstrate a power consumption of couple of nano-Walts (nW) with a minimum detectable strain of 0.0005%. This method can be used to create very low power sensors compared to typical piezoresistive and capacitive sensors whose power is typically in the μW to mW range. Our fabrication process is very simple and compatible with CMOS processes.

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“…García-Alonso et al, 2011;Cho et al, 2006;Chun-Hyung et al, 2008): Local sensitivity map of the diaphragm, G R (x,y)…”

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confidence: 99%

Multi-objective genetic algorithms applied to low power pressure microsensor design

Monzón-Verona

García-Alonso

Sosa

et al. 2013

Engineering Computations

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Purpose -The purpose of this paper is to explain in detail the optimization of the sensitivity versus the power consumption of a pressure microsensor using multi-objective genetic algorithms. Design/methodology/approach -The tradeoff between sensitivity and power consumption is analyzed and the Pareto frontier is identified by using NSGA-II, AMGA-II and 1-MOEA methods. Findings -Comparison results demonstrate that NSGA-II provides optimal solutions over the entire design space for spread metric analysis, and AMGA-II is better for convergence metric analysis. Originality/value -This paper provides a new multiobjective optimization tool for the designers of low power pressure microsensors.

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Low-power MEMS pressure sensor for wireless biomedical applications

Cited by 6 publications

References 10 publications

Low Power Tunneling Current Strain Sensor Using MOS Capacitors

Low Power Tunneling Current Strain Sensor Using MOS Capacitors

Low Power Strain Sensing Using Tunneling Current Through Mos Capacitors

Multi-objective genetic algorithms applied to low power pressure microsensor design

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