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Utilizing of MEMS sensors in rehabilitation process


Utilizing of MEMS sensors in rehabilitation process

The potential for utilizing of MEMS sensors, especially of accelerometers and gyroscopes is significant. They are used not only in consumer’s electronics, but also in so called wearable sensors that can be worn on body or in part of garment without interrupting comfort of person who is wearing these sensors. In the same time, we are able to collect data about person carrying the device. This paper focuses on analysis of current state of utilizing of MEMS sensors in rehabilitation process or in motion analysis.

Keywords:
MEMS, wearable sensors, motion analysis


Autoři: Ján Karchňák;  Dušan Šimšík;  Daniel Siman;  Marcel More
Působiště autorů: Department of Automation, control and human-machine interaction, Faculty of Mechanical Engineering, Technical University of Košice
Vyšlo v časopise: Lékař a technika - Clinician and Technology No. 4, 2013, 43, 28-31
Kategorie: Původní práce

Souhrn

The potential for utilizing of MEMS sensors, especially of accelerometers and gyroscopes is significant. They are used not only in consumer’s electronics, but also in so called wearable sensors that can be worn on body or in part of garment without interrupting comfort of person who is wearing these sensors. In the same time, we are able to collect data about person carrying the device. This paper focuses on analysis of current state of utilizing of MEMS sensors in rehabilitation process or in motion analysis.

Keywords:
MEMS, wearable sensors, motion analysis

Introduction

The abbreviation MEMS is intended for micro-electro-mechanical systems. Devices that belong into this group of sensors (e.g. accelerometers, gyroscopes, etc.) can be found in various applications, such as airbag sensors in cars, miniature gyroscopes for flying applications, wireless devices, etc. [1]. Dimensions of MEMS devices vary in general from one micrometer to few millimetres [2]. Into the so called “family” of MEMS devices belongs besides of the most known "members" - the accelerometers, gyroscopes and magnetometers, also the microphones, clocks, temperature sensors, pressure sensors and many others. Accelerometers and gyroscopes are commonly used in smartphones, 3D controls, pedometers, wearable sensors, inertial navigation, even in targetable ammunition [1], [4-6]. Typical structure of capacitive MEMS accelerometer is shown on Fig.1.

Fig. 1: Typical structure of capacitive MEMS accelerometer [7].
Fig. 1: Typical structure of capacitive MEMS accelerometer [7].

It is trend to integrate as much as possible devices on one chip, so usually most of the MEMS sensors has its own A/D converter and it is no rarity if user can set internal high pass or low pass filters for better reliability and accuracy of measurements. Such sensors (accelerometers, gyros, etc.), as mentioned above, can be found in customers’ electronics or in more scientific applications such as motion analysis using wearable sensors [8-9].

Current state

European Union assumes that in year 2015 will be mortality rate higher than natality and this trend will continue in the future while the population ageing will appear [10]. Similar course is expected also in USA [11].

According to current possibilities and knowledge about MEMS sensors and of course according to the expected demographical course, many research tasks are aimed on development of intelligent households environments and their elements [12-16] intended for specific groups of population (e.g. elderly or physically disabled persons) for which is necessary to monitor various parameters (e.g. blood pressure, motion, blood sugar). Such monitoring should be conducted in order to improve healthcare. It should be executed remotely without compromising the comfort of the monitored person. Another aspect of such environments is executing preventive actions that will prevent unwanted events, e.g. falls and in case of appearance of such events intelligent environment will contact the caregivers [11]. Essential elements of such environments are obviously wearable sensors. These sensors can be used for monitoring upper rehabilitation or telemedicine activities, respectively [9,17].

Fig. 2 shows general structure of wearable sensors according to review of wearable sensors and systems with application in rehabilitation [11]. Sensing and data collection hardware provides raw data, e.g. data about motion activities and events (gait, fall). The essential elements of this section are sensors (e.g. accelerometers) and other necessary hardware such as microcontroller; Communication hardware and software conducts data transfer into evaluation unit. According to the effort of remote monitoring such data are mainly transmitted by wireless technologies. Data analysis techniques are summary denotation for techniques of filtration, processing and evaluation of incoming data.

Fig. 2: General structure of wearable sensors [11]
Fig. 2: General structure of wearable sensors [11]

As mentioned above, development in MEMS area is fairly significant. From the view of improving technical parameters the integration of several sensors into one chip is widely used, along with using advanced data processing algorithms and filtration of measured data [9]. Market contains various commercial solutions for motion analysis using wearable MEMS sensors, e.g. PAMSysTM from BioSensics (Fig. 3). It is intended for long-term evaluation of physical activity during every day’s life, while it is possible to obtain information about position and posture, gait, falls, etc.[19]. Another commercial solution and available tools for similar motion analysis is from Xsens with their MTw Development Kit [20].

Fig. 3: Structure of PAMSys<sup>TM</sup> platform [19]
Fig. 3: Structure of PAMSys&lt;sup&gt;TM&lt;/sup&gt; platform [19]

There are also many academic projects in this area, e.g. Mercury platform that is intended for long-term data collection [21] or research work from Bruneti et. al [13] that uses wireless communication based on standard IEEE 802.15.4. Very interesting results are from To & Mahfouz [22] who made a comparison of experimental results from motion analysis of the lower limb performed by optical method and MEMS sensors in the same time.

Our previous work has been aimed on development and implementation of wearable devices based on MEMS sensors intended for rehabilitation process. The idea of development was that these devices could be used in case of dangerous states monitoring (e.g. measuring tilt of the shoulder or its acceleration) and in the same time it would be suitable for evaluation of motion parameters of the patient during rehabilitation process. Used rehabilitation device is based on pneumatic artificial muscles. For mentioned purposes, a prototype of wearable device has been developed.

Design of device

In the designing of the device, we had several requirements for it, such as control system of the rehabilitation device must be able to act very quickly and in the way of no harming of the patient if dangerous states are sensed. Of course, rehabilitation device will be mounted with incremental encoders, but it seems to be appropriate to complement its data with data from accelerometer. The reason for this is that accelerometers can provide information about vibrations in the construction of the rehabilitation device. So for the task of quick proper behaving of the device are accelerometers suitable solution. Another requirement to the wearable sensor is the possibility of connecting the sensor into PC and data transfer via USB. In the same time, USB works as a power supply to the sensor board. We decided to use 3 axis accelerometer MMA7431 from FreeScale and gyroscope ITG3200 from Invensense. As a control unit, ATMEGA32L was employed. There is also possibility to send data via UART. The prototype of wearable sensor is shown on Fig. 5. More about this prototype can be found in [25].

Fig. 4: MTw Development Kit [20]
Fig. 4: MTw Development Kit [20]

Conclusion

Wearable sensors are subject to the research and development of many interdisciplinary teams. Those teams are working on creating of suitable elements for intelligent environments that will improve quality of life of the specific group of the population (e.g elderly persons or disabled persons) and thus decrease their dependence from caregivers. The proposed paper is aimed on evaluation of current state-of-the art in the area of wearable sensors and shortly introduces work of authors in the given area.

Fig. 5: Prototype of wearable sensor
Fig. 5: Prototype of wearable sensor

Acknowledgement

This work has been supported also by the Slovak Grant Agency VEGA contract Nb. 1/1162/11 Theoretical principles, methods and tools in diagnostics and rehabilitation of seniors mobility.

The research leading to these results has received funding from the European Community’s Structural Funds, project „Research and development of inteligent nonconventional actuators on basis of artificial muscles“, ITMS 26220220103.

Prof. Ing. Dušan Šimšík, Ph.D.

E-mail: dusan.simsik@tuke.sk

Ing. Daniel Siman, Ph.D.

E-mail: daniel.siman@tuke.sk

Ing. Marcel More

E-mail: marcel.more@tuke.sk

Ján Karchňák

E-mail: jan.karchnak@tuke.sk

Department of Automation, control and human-machine interaction

Faculty of Mechanical Engineering

Technical University of Košice

Letná 9, 040 00 Košice

Slovak Republic


Zdroje

[1] Rai-Choudhury P.: MEMS and MOEMS Technology and Applications. SPIE Press Monograph, vol. 85, 2000. ISBN 0-8194-3716-6.

[2] MEMS & Nanotechnology Exchange: What is MEMS Technology? [online]. Available on http://www.memsexchange.org/MEMS/what-is.html

[3] Mahalik N. P.: MEMS. Tata McGraw-Hill, 2007, second edition. 501 pp. ISBN 978-0-07-063445-9.

[4] de Rooij, N. F. et al.: MEMS for space. In: Solid-State Sensors, Actuators and Microsystems Conference, 2009. TRANSDUCERS. pp.17-24. 2009.

[5] Ying Kun Peng - Golnaraghi, M. F.: A vector-based gyro-free inertial navigation system by integrating existing accelerometer network in a passenger vehicle. In: Position Location and Navigation Symposium, 2004. pp. 234- 242.

[6] Stewart, R. - Thede, R. - Couch, P. - Tarrant, D.: High G MEMS accelerometer for Compact Kinetic Energy Missile (CKEM). In: Position Location and Navigation Symposium, 2004.

[7] Saxena, G. D. - Thamarai, V.: Modeling and Simulation of High Performance Sixth Order Sigma-Delta MEMS Accelerometer. In: Computational Intelligence and Communication Networks (CICN), 2011. pp. 527-531.

[8] Frank Randy, Nine-Axis MEMS Motion Sensing, SensorTips, 2012.

[9] Šimšík, Dušan - Karchňák, Ján - Olejník, Matej - Petrik, Stanislav: Trendy vo využívaní MEMS snímačov. In: Automatizácia a riadenie v teórii a praxi ARTEP 2013 : workshop odborníkov z univerzít, vysokých škôl a praxe v oblasti automatizácie a riadenia : zborník príspevkov : 20.2.-22. 2. 2013, Stará Lesná, SR. - Košice : TU, 2013 S. 13-1-13-7. - ISBN 978-80-553-1330-6.

[10] EUROPA.EU. 2008. Press Releases: Population projections 2008-2060. 2008. [online]. 2008-08-26, [cit. 2013-04-04]. Available on: europa.eu/rapid/pressReleasesAction.do?reference=STAT/08/119&format=HTML&aged=0&language=EN&guiLanguage=en.

[11] Patel et al.: A review of wearable sensors and systems with application in rehabilitation. Journal of NeuroEngineering and Rehabilitation 2012 9:21.

[12] Bamberg et al.: Gait analysis using a shoe-integrated wireless sensor system. In: IEEE Transactions on information technology in biomedicine, vol. 12, no. 4, 2008.

[13] Bruneti F. et al.: A new platform based on IEEE802.15.4 wireless inertial sensors for motion caption and assessment. In: Proceedings of the 28th IEEE EMBS Annual International Conference, USA, 2006. pp. 6497 – 6500.

[14] Self Mobility Improvement in the eLderly by counteractING falls (SMILING), part of the European Commission's 7th RTD Framework Programme – Specific Programme Cooperation, contract number 215493. Internal documentation.

[15] Zhang Z. et al.: Wearable sensors for 3D upper limb motion modeling and ubiquitous estimation. In: Journal of Control Theory and Applications. Vol. 9, No. 1, pp. 10-17.

[16] Šimšík, D. et al.: MonAMI Platform in Elderly Household Environment Architecture, Installation, Implementation, Trials and Results. In: Lecture Notes in Computer Science : Computer Helping People with Special Needs. - Berlin Heidelberg : Springer-Verlag, 2012 No. 7383, pp. 419-422. - ISBN 978-3-642-31533-6 - ISSN 0302-9743.

[17] Do, Tri Nhut – Suh, Young Soo: Gait Analysis Using Floor Markers and Inertial Sensors. In: Sensors. 12/2012. Pp. 1594-1611. ISSN 1424-8220.

[18] Timmermans, A. et al: Home Stroke Rehabilitation for the Upper Limbs. In: Engineering in Medicine and Biology Society, 2007. EMBS 2007. 29th Annual International Conference of the IEEE, pp.4015-4018.

[19] BioSensics: PAMSysTM. Available on: http://www.biosensics.com/pamsys-overview/

[20] Xsens: products. Available on: http://www.xsens.com/en/general/products-all

[21] Lorincz K. et al., Mercury: A Wearable Sensor Network Platform for High-Fidelity Motion Analysis, Berkeley: School of Engineering and Applied Sciences. 2009.

[22] To, G. – Mahfouz, M. R.: Design of Wireless Inertial Trackers for Human Joint Motion Analysis. In: BioWireleSS, 2012. ISBN 978-1-4577-1135-0.

[23] Židek, Kamil – Dovica, Miroslav – Líška, Ondrej: Angle Measuring by MEMS Accelerometers. In: Journal of Automation, Mobile Robotics & Intelligent Systems. Vol. 6, no. 4 (2012), p. 3-6. ISSN 1897-8649.

[24] Kamil Židek, Alexander Hošovský, Vladislav Maxim: Real-time safety circuit based on combined MEMS sensor data for rehabilitation device. In: ICCC 2012 : proceedings of the 13th International Carpathian Control Conference : Podbanské, Slovak Republic, May 28-31, 2012. - Košice : TU, 2012 S. 786-790. - ISBN 978-1-4577-1866-3.

[25] Šimšík, D., Karchnák, J., Jobbágy, B., Galajdová, A. (2013). Design of inertial module for rehabilitation device. SAMI 2013 : IEEE 11th International Symposium on Applied Machine Intelligence and Informatics : proceedings : January 31 - February 2, 2013, Herlany, Slovakia. - Budapest : IEEE, 2013 S. 33-36. ISBN 978-1-4673-5926-9.

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