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11 results on '"Shyam Sivaramakrishnan"'

3. A Novel Real-Time Capacitance Estimation Methodology for Battery-Less Wireless Sensor Systems

Author

Hwa Soo Kim, A. Serdar Sezen, Shyam Sivaramakrishnan, and Rajesh Rajamani

Subjects
Engineering, business.industry, Capacitive sensing, Capacitance, Sweep frequency response analysis, Inductance, Electronic engineering, Calibration, Radio frequency, Electrical and Electronic Engineering, business, Instrumentation, Electrical impedance, Wireless sensor network
Abstract

This paper presents a novel method to read a passive capacitive sensor in telemetry by using inductive coupling. While classical inductive coupling approaches measure sensor capacitance by identifying the resonant frequency of the sensor with a sweep of radio frequency (RF) signals, the proposed method estimates the capacitance change in real-time by algebraically manipulating two measurements (the magnitude and the phase of the reflected sensor impedance). Only one RF signal is used in the proposed method instead of a frequency sweep. Analysis is provided to show that some physical parameter errors can deteriorate the capability of the proposed method in accurately measuring sensor capacitance. However, the use of a first order calibration procedure based on error analysis overcomes this shortcoming. Extensive experimental results with the proposed method combined with a first order calibration show that multifrequency and rapid changes in sensor capacitance can be estimated reliably under varying locations and orientations of the interrogator. The battery-less wireless sensors enabled by the developed technology in this paper can be widely used for measurement of fluid pressure, force, acceleration and other capacitance-change based sensor measurements.

Published
2010

4. Evaluation of sensing properties of stiffness-sensitive electret microphones

Author

Rajesh Rajamani and Shyam Sivaramakrishnan

Subjects
Electret microphone, Microphone, Computer science, Sensing applications, Acoustics, Metals and Alloys, Stiffness, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, Carbon dioxide sensor, law, ComputerSystemsOrganization_MISCELLANEOUS, Electric field, Materials Chemistry, medicine, Electret, Electrical and Electronic Engineering, medicine.symptom, Instrumentation, Sensitivity (electronics), ComputingMethodologies_COMPUTERGRAPHICS
Abstract

This paper presents an evaluation of the sensing properties of a new thin-film stiffness sensing technology that utilizes commercial electret microphones. The analysis is intended to provide researchers with both quantitative and qualitative information on microphone selection for stiffness sensing applications. The sensing properties examined include sensitivity, selectivity and the effect of microphone's electric field. Specifically, a mathematical method to estimate the stiffness sensitivity of a commercial microphone from its acoustic sensitivity is presented. This method utilizes direct measurements of the microphone's parameters to compute sensitivity to thin-film stiffness changes. The discussion on selectivity focuses on undesired cross-stiffness changes in the microphone membrane in the presence of changes in unrelated environmental analytes. Finally, the influence of the microphone's electric field on its stiffness sensing ability is presented.

Published
2009

5. Electrically stretched capacitive membranes for stiffness sensing and analyte concentration measurement

Author

Rajesh Rajamani, Shyam Sivaramakrishnan, and T. M. Pappenfus

Subjects
Materials science, Capacitive sensing, Metals and Alloys, Analytical chemistry, Stiffness, Carbon nanotube, engineering.material, Condensed Matter Physics, Capacitance, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, Membrane, Coating, law, Deflection (engineering), Materials Chemistry, engineering, medicine, Electret, Electrical and Electronic Engineering, medicine.symptom, Composite material, Instrumentation
Abstract

A novel method for stiffness sensing is developed using an electret capacitive sensor. The electret membrane is coated with a recognition layer that responds with a change in its stiffness/elasticity in the presence of a target analyte. Since the electret membrane is stretched by electrostatic pulling towards a metallic base plate, a change in stiffness of the composite membrane results in deflection of the membrane. This deflection is measured as a change in capacitance of the sensor. The sensitivity of the sensor to stiffness changes depends on the strength of the preset electric field. The developed sensor operates in a quasi-static mode and eliminates the need for resonant monitoring. The sealed capacitive sensor is ideal for monitoring analytes in both gas and liquid environments. The final sensor package with the capacitance measurement circuitry has a low power consumption (

Published
2008

6. Carbon nanotube-coated surface acoustic wave sensor for carbon dioxide sensing

Author

Shyam Sivaramakrishnan, N. Yamashita, Rajesh Rajamani, Conor S. Smith, Kent R. Mann, and Kari A. McGee

Subjects
Nanotube, Materials science, business.industry, Surface acoustic wave, Metals and Alloys, Carbon nanotube, Conductivity, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, Carbon dioxide sensor, chemistry, Potential applications of carbon nanotubes, law, Carbon dioxide, Materials Chemistry, Optoelectronics, Surface acoustic wave sensor, Electrical and Electronic Engineering, business, Instrumentation
Abstract

Carbon dioxide gas sensors have been fabricated by self-assembling single-wall nanotube films on a surface acoustic wave delay line operating at 286 MHz. Polymer functionalization was used to enhance the sensitivity of the carbon nanotubes to carbon dioxide. A pulse radar-type interrogation system was used to monitor the conductivity of the nanotube film by measuring the attenuation of the surface acoustic wave due to film-conductivity changes. The conductivity of the film was found to decrease with carbon dioxide concentration. The effect of varying the sheet conductivity of the nanotube film was examined. Both analytical and experimental results show that controlling the conductivity of the CNT film within a specific range highly enhances the sensitivity to carbon dioxide. Experimental results show that the sensor tracks carbon dioxide concentration changes between 0% and 10%. The final sensor is sensitive, small and wirelessly interrogable, thus making it potentially useful for respiratory monitoring.

Published
2008

7. Passive Wireless MEMS Microphones for Biomedical Applications

Author

A.S. Sezen, William P. Robbins, S. Hur, Bradley J. Nelson, Shyam Sivaramakrishnan, and Rajesh Rajamani

Subjects
Microelectromechanical systems, Engineering, Miniaturization, Sound Spectrography, business.industry, Interdigital transducer, Acoustics, Transducers, Surface acoustic wave, Biomedical Engineering, Electrical engineering, Monitoring, Ambulatory, Equipment Design, Signal, Equipment Failure Analysis, Transducer, Physiology (medical), Variable capacitor, Telemetry, ComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMS, Diagnosis, Computer-Assisted, Antenna (radio), business, Audio frequency
Abstract

This paper introduces passive wireless telemetry based operation for high frequency acoustic sensors. The focus is on the development, fabrication, and evaluation of wireless, batteryless SAW-IDT MEMS microphones for biomedical applications. Due to the absence of batteries, the developed sensors are small and as a result of the batch manufacturing strategy are inexpensive which enables their utilization as disposable sensors. A pulse modulated surface acoustic wave interdigital transducer (SAW-IDT) based sensing strategy has been formulated. The sensing strategy relies on detecting the ac component of the acoustic pressure signal only and does not require calibration. The proposed sensing strategy has been successfully implemented on an in-house fabricated SAW-IDT sensor and a variable capacitor which mimics the impedance change of a capacitive microphone. Wireless telemetry distances of up to 5 centimeters have been achieved. A silicon MEMS microphone which will be used with the SAW-IDT device is being microfabricated and tested. The complete passive wireless sensor package will include the MEMS microphone wire-bonded on the SAW substrate and interrogated through an on-board antenna. This work on acoustic sensors breaks new ground by introducing high frequency (i.e., audio frequencies) sensor measurement utilizing SAW-IDT sensors. The developed sensors can be used for wireless monitoring of body sounds in a number of different applications, including monitoring breathing sounds in apnea patients, monitoring chest sounds after cardiac surgery, and for feedback sensing in compression (HFCC) vests used for respiratory ventilation. Another promising application is monitoring chest sounds in neonatal care units where the miniature sensors will minimize discomfort for the newborns.

Published
2005

8. Dynamic model inversion techniques for breath-by-breath measurement of carbon dioxide from low bandwidth sensors

Author

Bruce D. Johnson, Rajesh Rajamani, and Shyam Sivaramakrishnan

Subjects
Spectrum analyzer, Time Factors, Computer science, Remote patient monitoring, Acoustics, Real-time computing, Diagnosis tool, Wearable computer, chemistry.chemical_compound, Capnography, Electrochemistry, medicine, Electronic engineering, Humans, Electrical and Electronic Engineering, Respiratory system, Instrumentation, Monitoring, Physiologic, Signal processing, Models, Statistical, medicine.diagnostic_test, Bandwidth (signal processing), Reproducibility of Results, Signal Processing, Computer-Assisted, Equipment Design, Carbon Dioxide, Models, Theoretical, Carbon dioxide sensor, Breath Tests, chemistry, Carbon dioxide, Environmental science, InformationSystems_MISCELLANEOUS, Casing, Algorithms
Abstract

Respiratory CO2 measurement (capnography) is an important diagnosis tool that lacks inexpensive and wearable sensors. This paper develops techniques to enable use of inexpensive but slow CO2 sensors for breath-by-breath tracking of CO2 concentration. This is achieved by mathematically modeling the dynamic response and using model-inversion techniques to predict input CO2 concentration from the slowly varying output. Experiments are designed to identify model-dynamics and extract relevant model-parameters for a solid-state room monitoring CO2 sensor. A second-order model that accounts for flow through the sensor's filter and casing is found to be accurate in describing the sensor's slow response. The corresponding model-inversion algorithm is however found to be susceptible to noise sources. Techniques to remove spurious noise, while retaining quality of estimate are developed. The resulting estimate is compared with a standard-of-care respiratory CO2 analyzer and shown to effectively track variation in breath-by-breath CO2 concentration. This methodology is potentially useful for measuring fast-varying inputs to any slow sensor.

Published
2009

9. Evaluation of sensitivity of stiffness-sensitive electret microphones

Author

Shyam Sivaramakrishnan and Rajesh Rajamani

Subjects
Materials science, Microphone, Acoustics, Transducers, Carbon nanotube, Sensitivity and Specificity, law.invention, law, Nanosensor, Materials Testing, medicine, Nanotechnology, ComputingMethodologies_COMPUTERGRAPHICS, Electret microphone, Models, Statistical, Amplifiers, Electronic, Nanotubes, Carbon, Stiffness, Equipment Design, Carbon Dioxide, Models, Theoretical, Transducer, Acoustic Stimulation, ComputerSystemsOrganization_MISCELLANEOUS, Adsorption, Electret, medicine.symptom, Material properties, Algorithms
Abstract

This paper presents an evaluation of the sensitivity of a new thin-film stiffness sensing technology that utilizes commercial electret microphones. The analysis allows comparison of commercial microphones for stiffness sensing applications. A mathematical method to estimate the stiffness sensitivity of a commercial microphone from its acoustic sensitivity is developed. Experimental results are presented on the use of the developed method in a sensor that estimates carbon dioxide concentration by utilizing a carbon nanotube thin film on an electret microphone.

Published
2009

10. Simultaneous identification of tire cornering stiffnesses and vehicle center of gravity

Author

Shyam Sivaramakrishnan

Subjects
Engineering, business.industry, Yaw, Kinematics, Moment of inertia, Accelerometer, Computer Science::Robotics, Vehicle dynamics, Center of gravity, Acceleration, Control theory, Relaxation length, business, Simulation
Abstract

INS, GPS measurements are used to simultaneously estimate the location of the center of gravity of a vehicle and the tire cornering stiffnesses. The developed method uses kinematic as well as dynamic equations of a lateral vehicle model to eliminate the bias in the yaw rate and lateral acceleration measurements. An approximation of the moment of inertia is used to combine the dynamic equations of a bicycle model and thereby estimate the tire cornering stiffnesses. The chief advantage of this method is its determinate formulation which eliminates the constraint on persistency of excitation during vehicle testing. It is shown using simulations that the accuracy of the proposed method is affected by measurement noise.

Published
2008

11. Development of a wireless angle sensor based on the directional radiation pattern of antennas

Author

Gridsada Phanomchoeng, Anand Gopinath, Rajesh Rajamani, and Shyam Sivaramakrishnan

Subjects
Offset (computer science), Directional antenna, business.industry, Computer science, Applied Mathematics, Acoustics, Estimator, Gyroscope, Radiation pattern, law.invention, Printed circuit board, Optics, law, Miniaturization, Wireless, business, Instrumentation, Engineering (miscellaneous)
Abstract

The directional radiation pattern of antennas is exploited to develop a high-speed wireless absolute angle measurement device. The system involves deployment of one antenna on a rotating body as the angle measurement sensor. This sensor antenna receives signals from two interrogation antennas positioned with an angular offset on a static frame of reference. The directional radiation pattern of the antennas is used to analyze the received signal strength and estimate the angle between the static and rotating frames. The signals received by the sensor antenna are analyzed using standard inexpensive hardware capable of miniaturization on a printed circuit board/chip. The key advantages of this sensor are absolute angle detection, wireless operation, high sampling rate and inexpensive fabrication. Detailed experimental results are presented that evaluate the feasibility of this new sensing concept. Experiments show that the sensor achieves better than 0.5° accuracy for static angle measurements and an accuracy of the order of 1.6° for dynamic motion measurements. An estimator that combines a gyroscope together with the developed angle sensor is then presented. The estimator is able to achieve drift-free estimates with accuracy better than 0.2° for static and 0.8° for dynamic measurements.

Published
2009

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