Frequency hopping spread spectrum multiplexing for interferometric optical fibre sensor networks

Radi, Haidar M.

January 1997

No description available.

621.381045

Sensor sensitivity; Phase noise

CHARACTERIZATION OF CARBON NANOTUBES BASED RESISTIVE AND CAPACITIVE GAS SENSORS

Ma, Ning

01 January 2007

A preliminary gas detection study was conducted on as-grown multi-walled carbon nanotubes and anodized aluminum oxide (MWNTs/AAO) template. The material demonstrated room temperature gas sensitivity and p-type semiconductor characteristics. Plasma-etched MWNTs/AAO templates were employed to construct capacitive gas sensors. The capacitances of the sensors were sensitive to both reducing and oxidizing gases at room temperature. Single-walled carbon nanotubes (SWNTs) dispersed in binder andamp;aacute;-terpineol were applied on sensor platforms to form resistive gas sensors. The sensors demonstrated excellent sensitivity to low concentrations of reducing and oxidizing gases at room temperature, which suggests the p-type semiconducting behavior of SWNTs. The sensor recovery was found to be incomplete at room temperature in flow of nitrogen and air, thus possible solutions were investigated to enhance sensor performance. The sensor operating principles and suggestions for possible future work are discussed. The room temperature and air background functionality of the sensor suggest that SWNT is a promising gas sensing material for application in ambient conditions.

Methodology to Analyze the Sensitivity of Building Energy Consumption to HVAC System Sensor Error

Ma, Liang

2011 December 1900

This thesis proposes a methodology for determining sensitivity of building energy consumption of HVAC systems to sensor error. It is based on a series of simulations of a generic building, the model for which is based on several typical input parameters. There are a total of eight scenarios considered in this simulation. The simulation tool was developed based on Excel. The control parameters examined include room temperature, cold deck temperature, hot deck temperature, pump pressure, and fan pressure. All of the parameters considered are varied in order to analyze the sensitivity of building energy consumption to their variation. In this tool, different operation schedules for equipment, occupancy, and lighting are considered. By changing each control parameter, the sensitivity of energy use to sensor error is simulated, a regression model is generated, and the energy consumption change is expressed as a function of sensor error and outside air percentage. Two applications of this methodology are presented in this thesis. One is a SDVAV system and the other is a DDVAV system. The outside air percentage changes the trend of the sensor error curve. After the sensitivity study is discussed, some recommendations regarding the calibration intervals of the sensors are given.

HVAC sensor

energy consumption

sensor sensitivity

Optimization of microelectrode sensor sensitivity for real-time monitoring important physiological parameters of human renal epithelial cell

Yuan, Fan

07 May 2020

In order to calculate specific impedance of cell-covered electrodes in a Equation of morphological parameters of cell per se, an ECIS model of Human Renal Epithelial Cell are created by analysis partial differential equations describing three intrinsic pathways of electrical currents in the system. Based on this cell model, this research explores how some adjustable dimensional parameters of electrode-configuration impact sensor sensitivity by changing the overall impedance contribution of electrical double layer. Namely, it includes electrode planner area, spacing between working and counter electrode and geometry of electrode, scanning frequency. Qualitative studies on how sensor sensitivity rely on configurational parameters are conducted with these parameters involved. Moreover, theoretical analysis of sensitivity by using equivalent circuit model is also carried out. As results of COMSOL simulations, special double layer electrode configurations and selectively planted cell monolayer arrangement are proposed regardless of fabrication difficulties. Accordingly, some possible strategies to make these arrangements come true are also illustrated. Finally, superior possible COMSOL simulation model is suggested and discussed for future optimization works. / 2021-05-07T00:00:00Z

Bioengineering

COMSOL simulation

Finite element analysis

Human renal epithelial cell

Microelectrode sensor

Real-time monitoring

Sensor sensitivity

An Evaluation of Optical Fiber Strain Sensing for Engineering Applications

Harold, Douglas A.

16 March 2012

A fatigue test has been performed on 7075-T651 aluminum specimens which were bonded with polyimide coated optical fibers with discrete Bragg gratings. These fibers were bonded with AE-10 strain gage adhesive. The results indicate that lower strain amplitudes do not produce cause for concern, but that larger strain amplitudes (on the order of 3500 μ) may cause some sensors to become unreliable. The strain response of acrylate coated optical fiber strain sensors bonded to aluminum specimens with AE-10 and M-Bond 200 strain gage adhesives was investigated with both axial and cantilever beam tests. These results were compared to both the strain response of conventional strain gages and to model predictions. The results indicate that only about 82.6% of the strain in the specimen was transferred through the glue line and fiber coating into the fiber. Thus, multiplying by a strain transfer factor of approximately 1.21 was sufficient to correct the optical fiber strain output. This effect was found to be independent of the adhesive used and independent of the three-dimensional profile of the glue line used to attach the fiber. Finally, this effect did not depend on whether the fiber had a polyimide or an acrylate coating. Further investigation was conducted on the feasibility of using optical fiber strain sensors for monitoring subcritical damage (such as matrix cracks) in fiber reinforced composite materials. These results indicate that an array of optical fibers which monitor the strain profile on both sides of a composite panel may be sufficient for these purposes / Master of Science

Fiber Bragg grating

Optical fiber sensor

Distributed strain sensing

Strain monitoring

Strain transfer

Surface-mounted fiber-optic sensor

Sensor sensitivity

Optical fiber strain sensor

Reliability

Durability

Damage detection

Adressing Integration Obstacles for Carbon Nanotube based Miniaturized Electro-mechanical Transducers

Böttger, Simon

18 February 2025

Emerging electronic system architectures follow increasingly 3D integration concepts driven by further miniaturization, increase of performance, decrease of energy consumption, and implementation of further functionality. Following this More than Moore path, trendsetting on-top-of-complementary metal-oxide semiconductor (CMOS) technologies for nanodevices find increasing attention in semiconductor development roadmaps. Nanodevices implemented through nanomaterials such as semiconducting single-walled carbon nanotubes (CNTs) with their proceeded technology readiness level, give additional degree of freedom to upgrade such systems as substrate-independent and post-CMOS compatible technologies are already available. Although, they inherently feature extraordinary properties several technological obstacles are not yet addressed. Pronounced obstacles like inadequate CNT assembly structure, interfering parasitic effects related to CNT/substrate interfaces, as well as insufficient pre-stress state of the CNTs are tackled within this thesis aiming on CNT-based piezoresistive sensors. Following a holistic approach, the activities range from the implementation of chromatography-based length separation of CNTs over wafer-level micro- and nanotechnological process-, module-, and equipment developments towards comprehensive and statistical data analysis. It could be shown, that short CNTs adversely affect integrability and reproducibility, underlined by a 25% decline of the fabrication yield of CNT based field-effect transistors (CNT-FETs) with respect to long CNTs. It furthermore turns out, that performance of CNT-FETs built from long CNTs show significant benefits in terms of subthreshold swing (up to 163%) and hole mobility (up to 300%), which could be explained by suppressed CNT chain formation within the transistor channel. Furthermore, short-channel piezoresistive CNT sensors in FET configuration show a significant drain-induced barrier thinning characterized by a degradation of the subthreshold swing and a threshold voltage roll-off of (−1370± 130) mV · V−1 upon applied drain-source voltage. This device-specific effect enhances the intrinsic strain-sensitivity of the sensor of up to 150% with a maximum measured gauge factor of 800. In this regard, supporting transport simulations underline the importance of the Schottky barrier at the source/CNT junction as the dominating junction for tunneling currents responsible for the gained enhancement. Finally, a technology module was developed, which further reduce parasitic effects such as stick-slip and slack behavior of device-integrated CNTs upon mechanical load by incorporation of layout-determined pre-strain. Utilizing a post-CMOS compatible sacrificial layer approach combined with residual stressed membranes, the integrated CNTs were strained by almost 1% in axial direction. This consequences in an reduced sensor offset determined by a reduction of the detection limit to 30 MPa. In addition this modul was successfully implemented by heterogeneous on-top-of application-specific integrated circuit technologies where CNT-FETs were characterized over an embedded complementary metal-oxide semiconductor multiplexer circuit. Hence, this work displays novelty and provides significant contributions on heterointegrated system-on-chip applications of upcoming nanomaterial-based devices for environmental sensing, condition monitoring, photonic integrated circuits, up to promising architectures for neuromorphic computing and the quantum technology science and application.

ddc:621.30284

Einwandige Kohlenstoff-Nanoröhre

Feldeffekttransistor

Nanotechnologie

Dehnungssensor

Wafer-Integration