Development of a Microelectromechanical System (MEMS)-Based Multisensor Platform for Environmental Monitoring

Hautefeuille, Mathieu; O’Flynn, Brendan; Peters, Frank H.; O’Mahony, Conor

doi:10.3390/mi2040410

Cited by 15 publications

(18 citation statements)

References 31 publications

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“…Thanks to the technological developments in electronics and MEMS-based sensors [29][30][31][32], nowadays, most mobile devices (e.g., smartphones and tablets) are provided with several embedded sensors. Hence, differently from other works, which considered the use of external sensors (e.g., [8,9,17]), here, an indoor navigation system based on the use of the sensors embedded in standard mobile devices is considered.…”

Section: System Description and Relation To Previous Workmentioning

confidence: 99%

A Particle Filter for Smartphone-Based Indoor Pedestrian Navigation

et al. 2014

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This paper considers the problem of indoor navigation by means of low-cost mobile devices. The required accuracy, the low reliability of low-cost sensor measurements and the typical unavailability of the GPS signal make indoor navigation a challenging problem. In this paper, a particle filtering approach is presented in order to obtain good navigation performance in an indoor environment: the proposed method is based on the integration of information provided by the inertial navigation system measurements, the radio signal strength of a standard wireless network and of the geometrical information of the building. In order to make the system as simple as possible from the user's point of view, sensors are assumed to be uncalibrated at the beginning of the navigation, and an auto-calibration procedure of the magnetic sensor is performed to improve the system performance: the proposed calibration procedure is performed during regular user's motion (no specific work is required). The navigation accuracy achievable with the proposed method and the results of the auto-calibration procedure are evaluated by means of a set of tests carried out in a university building.

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Section: System Description and Relation To Previous Workmentioning

confidence: 99%

A Particle Filter for Smartphone-Based Indoor Pedestrian Navigation

et al. 2014

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“…In the general pedestrian dead reckoning (PDR) technique, accelerometers are used for step detection, and step length estimation, gyroscope and magnetometer sensors are combined to resolve the movement heading [21,32]. The movement heading is fused with the step length to calculate the accumulated position change relative to a previous position [21,43,51]. The PDR technique has high precision within a short period, although suffering from accumulated absolute positioning errors over time [2,32,43,51].…”

Section: Radio Signals and Mems Sensors Integration For Smartphone Pomentioning

confidence: 99%

“…The movement heading is fused with the step length to calculate the accumulated position change relative to a previous position [21,43,51]. The PDR technique has high precision within a short period, although suffering from accumulated absolute positioning errors over time [2,32,43,51]. Contrarily, fingerprinting positioning does not suffer from error accumulation, whereas due to multipath and non-line-of-sight propagation of WLAN signals, non-stationary RSSI observables might generate noisy and jumpy positioning results [22][23][24][25].…”

Section: Radio Signals and Mems Sensors Integration For Smartphone Pomentioning

confidence: 99%

Reciprocal Estimation of Pedestrian Location and Motion State toward a Smartphone Geo-Context Computing Solution

et al. 2015

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Abstract:The rapid advance in mobile communications has made information and services ubiquitously accessible. Location and context information have become essential for the effectiveness of services in the era of mobility. This paper proposes the concept of geo-context that is defined as an integral synthesis of geographical location, human motion state and mobility context. A geo-context computing solution consists of a positioning engine, a motion state recognition engine, and a context inference component. In the geo-context concept, the human motion states and mobility context are associated with the geographical location where they occur. A hybrid geo-context computing solution is implemented that runs on a smartphone, and it utilizes measurements of multiple sensors and signals of opportunity that are available within a smartphone. Pedestrian location and motion states are estimated jointly under the framework of hidden Markov models, and they are used in a reciprocal manner to improve their estimation performance of one another. It is demonstrated that pedestrian location estimation has better accuracy when its motion state is known, and in turn, the performance of motion state recognition can be improved with increasing reliability when the location is given. The geo-context inference is implemented simply with the expert system principle, and more sophisticated approaches will be developed. OPEN ACCESSMicromachines 2015, 6 700

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“…The noise level of the sensor would be decreased by integrating the sensor and the signal processing circuit in one chip [6]. With the fast development of various kinds of sensors, the idea of multifunctional platforms for the different sensors is generated [7]. With these multifunctional platforms, different kinds of sensors can be implemented, which would save a lot of development time and cost.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Platform with CMOS-Compatible Tungsten Microhotplate for Pirani, Temperature, and Gas Sensor

Wang¹,

Yu²

2015

Micromachines

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Abstract:A multifunctional platform based on the microhotplate was developed for applications including a Pirani vacuum gauge, temperature, and gas sensor. It consisted of a tungsten microhotplate and an on-chip operational amplifier. The platform was fabricated in a standard complementary metal oxide semiconductor (CMOS) process. A tungsten plug in standard CMOS process was specially designed as the serpentine resistor for the microhotplate, acting as both heater and thermister. With the sacrificial layer technology, the microhotplate was suspended over the silicon substrate with a 340 nm gap. The on-chip operational amplifier provided a bias current for the microhotplate. This platform has been used to develop different kinds of sensors. The first one was a Pirani vacuum gauge ranging from 10´1 to 10 5 Pa. The second one was a temperature sensor ranging from´20 to 70˝C. The third one was a thermal-conductivity gas sensor, which could distinguish gases with different thermal conductivities in constant gas pressure and environment temperature. In the fourth application, with extra fabrication processes including the deposition of gas-sensitive film, the platform was used as a metal-oxide gas sensor for the detection of gas concentration.

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Development of a Microelectromechanical System (MEMS)-Based Multisensor Platform for Environmental Monitoring

Cited by 15 publications

References 31 publications

A Particle Filter for Smartphone-Based Indoor Pedestrian Navigation

A Particle Filter for Smartphone-Based Indoor Pedestrian Navigation

Reciprocal Estimation of Pedestrian Location and Motion State toward a Smartphone Geo-Context Computing Solution

Multifunctional Platform with CMOS-Compatible Tungsten Microhotplate for Pirani, Temperature, and Gas Sensor

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