iNEMO : a multi-sensor real-time human activity monitoring system

The iNEMO module family of ST Microelectronics integrates series of sensors with rapid and accurate computation core: offer more comprehensive, succinct and simple packaging solution compare to discrete sensors or components. In this project, a combination of iNEMO module includes LSM330D integrates...

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Main Author: Qian, Siyuan
Other Authors: School of Electrical and Electronic Engineering
Format: Final Year Project
Language:English
Published: 2013
Subjects:
Online Access:http://hdl.handle.net/10356/53407
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-534072023-07-07T16:15:34Z iNEMO : a multi-sensor real-time human activity monitoring system Qian, Siyuan School of Electrical and Electronic Engineering STMicroelectronics Microelectronics Centre Chen Shoushun DRNTU::Engineering The iNEMO module family of ST Microelectronics integrates series of sensors with rapid and accurate computation core: offer more comprehensive, succinct and simple packaging solution compare to discrete sensors or components. In this project, a combination of iNEMO module includes LSM330D integrates accelerometer and gyroscope, embedded on the motherboard which bridge the communication between the sensor and end platform. The control motherboard mainly consists of a STM32F103RET6 high-performance ARM Cortex™-M3 microcontroller, a DIL24 socket to mount different allowable sensor devices, and wireless adapter pins for compatible Bluetooth modules. The designed user application intends to develop the real-time human activity monitoring system by acquiring, analyzing the wireless transmitted acceleration and angular detection from the iNEMO inertial module as well as providing the instantaneous momentum information to match with data generated by computer vision image processing. The accomplished system contributes the safety assurance to the elderly, solitary personnel in Singapore. The project has been divided into two branches. One is applying computer vision methodology to process images of indoor human behavior instance. The other branch, which assigned for my final year project, was to implement the serial communication to acquire raw data through Bluetooth transmission, eliminate of preliminary noise and covert acceleration to velocity of movement. The emphases of the project are on the spontaneous serial port data transmissions, and real-time momentum data collections. The accuracy of processed momentum data with noise elimination by using kalman filter will affect the functionally of the application and matching with the other part of project. Furthermore, the conversion of data is required as the matching data from computer vision is in pixel unit. The project can work independently to provide supporting data for any other relevant projects. Bachelor of Engineering 2013-06-03T04:15:09Z 2013-06-03T04:15:09Z 2013 2013 Final Year Project (FYP) http://hdl.handle.net/10356/53407 en Nanyang Technological University 57 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering
spellingShingle DRNTU::Engineering
Qian, Siyuan
iNEMO : a multi-sensor real-time human activity monitoring system
description The iNEMO module family of ST Microelectronics integrates series of sensors with rapid and accurate computation core: offer more comprehensive, succinct and simple packaging solution compare to discrete sensors or components. In this project, a combination of iNEMO module includes LSM330D integrates accelerometer and gyroscope, embedded on the motherboard which bridge the communication between the sensor and end platform. The control motherboard mainly consists of a STM32F103RET6 high-performance ARM Cortex™-M3 microcontroller, a DIL24 socket to mount different allowable sensor devices, and wireless adapter pins for compatible Bluetooth modules. The designed user application intends to develop the real-time human activity monitoring system by acquiring, analyzing the wireless transmitted acceleration and angular detection from the iNEMO inertial module as well as providing the instantaneous momentum information to match with data generated by computer vision image processing. The accomplished system contributes the safety assurance to the elderly, solitary personnel in Singapore. The project has been divided into two branches. One is applying computer vision methodology to process images of indoor human behavior instance. The other branch, which assigned for my final year project, was to implement the serial communication to acquire raw data through Bluetooth transmission, eliminate of preliminary noise and covert acceleration to velocity of movement. The emphases of the project are on the spontaneous serial port data transmissions, and real-time momentum data collections. The accuracy of processed momentum data with noise elimination by using kalman filter will affect the functionally of the application and matching with the other part of project. Furthermore, the conversion of data is required as the matching data from computer vision is in pixel unit. The project can work independently to provide supporting data for any other relevant projects.
author2 School of Electrical and Electronic Engineering
author_facet School of Electrical and Electronic Engineering
Qian, Siyuan
format Final Year Project
author Qian, Siyuan
author_sort Qian, Siyuan
title iNEMO : a multi-sensor real-time human activity monitoring system
title_short iNEMO : a multi-sensor real-time human activity monitoring system
title_full iNEMO : a multi-sensor real-time human activity monitoring system
title_fullStr iNEMO : a multi-sensor real-time human activity monitoring system
title_full_unstemmed iNEMO : a multi-sensor real-time human activity monitoring system
title_sort inemo : a multi-sensor real-time human activity monitoring system
publishDate 2013
url http://hdl.handle.net/10356/53407
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