Technical Features and Functionalities of Myo Armband: An Overview on Related Literature and Advanced Applications of Myoelectric Armbands Mainly Focused on Arm Prostheses
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
ADORA-MED d.o.o.. For Surgeons – ADORA Assistant. Website: https://adora-med.com/#section_video.ADORA-MED d.o.o.Website:https://adora-med.com/#section_videoSearch in Google Scholar
Baker, J., Scheme, E., Englehart, K., Hutchinson, D., and Greger, B.. Aug. 2010. Continuous detection and decoding of dexterous finger flexions with implantable myoelectric sensors. IEEE Transactions on Neural Systems and Rehabilitation Engineering 18 No. 4: 424-432.BakerJ.SchemeE.EnglehartK.HutchinsonD., and GregerB.Aug. 2010Continuous detection and decoding of dexterous finger flexions with implantable myoelectric sensors18442443210.1109/TNSRE.2010.204759020378481Search in Google Scholar
Benalcázar, M.E., Jaramillo, A.G., Zea, J.A., Páez, A., and Andaluz, V.H.. 2017. Hand gesture recognition using machine learning and the Myo Armband. 25th European Signal Processing Conf. (EUSIPCO), Kos, Greece, 28 Aug–2 Sept, 2017: 1040-1044, DOI: 10.23919/EUSIPCO.2017.8081366.BenalcázarM.E.JaramilloA.G.ZeaJ.A.PáezA., and AndaluzV.H.201725th European Signal Processing Conf. (EUSIPCO)Kos, Greece28 Aug–2 Sept, 201710401044DOI: 10.23919/EUSIPCO.2017.808136610.23919/EUSIPCO.2017.8081366Search in Google Scholar
Carlo, J.D.L.. 1997. The use of surface electromyography in biomechanics. Journal of applied biomechanics 13: 135-163.CarloJ.D.L.1997The use of surface electromyography in biomechanics1313516310.1123/jab.13.2.135Search in Google Scholar
Cipriani, C., Controzzi, M., and Carrozza, M.C.. May 2011. The SmartHand transradial prosthesis. Journal of NeuroEngineering and Rehabilitation 8 No. 29: 2-13.CiprianiC.ControzziM.CarrozzaM.C.May 2011The SmartHand transradial prosthesis82921310.1186/1743-0003-8-29312075521600048Search in Google Scholar
Donovan, I., Valenzuela, K., Ortiz, A., Dusheyko, S., Jiang, H., Okada, K., and Zhang, X.. 2016. MyoHMI: a low-cost and flexible platform for developing real-time human machine interface for myoelectric controlled applications. IEEE Int. Conference on Systems, Man and Cybernetics SMC 2016, Budapest, Hungary, Oct. 9–12, 2016: 4495-4500, DOI: 10.1109/SMC.2016.7844940.DonovanI.ValenzuelaK.OrtizA.DusheykoS.JiangH.OkadaK., and ZhangX.2016IEEE Int. Conference on Systems, Man and Cybernetics SMC 2016BudapestHungaryOct. 9–12, 201644954500DOI: 10.1109/SMC.2016.784494010.1109/SMC.2016.7844940Search in Google Scholar
Fang, Y., Hettiarachchi, N., Zhou, D., and Liu, H.. 2015. Multi-modal sensing techniques for interfacing hand prostheses: a review. IEEE Sensors Journal 15 No. 11: 6065-6076.FangY.HettiarachchiN.ZhouD., and LiuH.2015Multi-modal sensing techniques for interfacing hand prostheses: a review15116065607610.1109/JSEN.2015.2450211Search in Google Scholar
Fillauer LLC. 2018. http://fillauer.com/Upper-Extremity-Prosthetics/body-powered-systems/hands-and-gloves/child-hands/child-CAPP-hand.html.2018http://fillauer.com/Upper-Extremity-Prosthetics/body-powered-systems/hands-and-gloves/child-hands/child-CAPP-hand.htmlSearch in Google Scholar
Ganiev, A., Shin, H.S., and Lee, K.H.. 2016. Study on virtual control of a robotic arm via a Myo Armband for the self- manipulation of a hand amputee. International Journal of Applied Engineering Research 11 No. 2: 775-782.GanievA.ShinH.S., and LeeK.H.2016Study on virtual control of a robotic arm via a Myo Armband for the self- manipulation of a hand amputee112775782Search in Google Scholar
Georgia Institute of Technology. 2017. www.news.gatech.edu/2017/12/11/force-strong-amputee-controls-individual-prosthetic-fingers.2017www.news.gatech.edu/2017/12/11/force-strong-amputee-controls-individual-prosthetic-fingersSearch in Google Scholar
Guo, W., Sheng, X., Liu, H., and Zhu, X.. 2017. Toward an enhanced human–machine interface for upper-limb prosthesis control with combined EMG and NIRS signals. IEEE Transactions on Human–Machine Systems 47 No. 4: 564-575.GuoW.ShengX.LiuH., and ZhuX.2017Toward an enhanced human–machine interface for upper-limb prosthesis control with combined EMG and NIRS signals47456457510.1109/THMS.2016.2641389Search in Google Scholar
Guo, W., Sheng, X., Liu, H., and Zhu, X.. 2017. Mechanomyography assisted myoeletric sensing for upper-extremity prostheses: a hybrid approach. IEEE Sensors Journal 17 No. 10: 3100-3108.GuoW.ShengX.LiuH., and ZhuX.2017Mechanomyography assisted myoeletric sensing for upper-extremity prostheses: a hybrid approach17103100310810.1109/JSEN.2017.2679806Search in Google Scholar
Hettig, J., Saalfeld, P., Luz, M., Becker, M., Skalej, M., and Hansen, C.. 2017. Comparison of gesture and conventional interaction techniques for interventional neuroradiology. International Journal of Computer Assisted Radiology and Surgery 12 No. 9: 1643-1653.HettigJ.SaalfeldP.LuzM.BeckerM.SkalejM., and HansenC.2017Comparison of gesture and conventional interaction techniques for interventional neuroradiology1291643165310.1007/s11548-017-1523-728120179Search in Google Scholar
InMoov open source 3D printed life-size robot. available at: http://inmoov.fr.InMoov open source 3D printed life-size robothttp://inmoov.frSearch in Google Scholar
Khushaba, R.N., Al-Timemy, A.H., Al-Ani, A., and Al-Jumaily, A.. 2017. A framework of temporal-spatial descriptors- based feature extraction for improved myoelectric pattern recognition. IEEE Transactions on Neural Systems and Rehabilitation Engineering 25 No. 10: 1821-1831.KhushabaR.N.Al-TimemyA.H.Al-AniA., and Al-JumailyA.2017A framework of temporal-spatial descriptors- based feature extraction for improved myoelectric pattern recognition25101821183110.1109/TNSRE.2017.268752028358690Search in Google Scholar
Lenzi, T., Lipsey, J., and Sensinger, J.W.. 2016. The RIC arm—a small, anthropomorphic transhumeral prosthesis. IEEE/ASME Transactions on Mechatronics 21 No. 6: 2660-2671.LenziT.LipseyJ., and SensingerJ.W.2016The RIC arm—a small, anthropomorphic transhumeral prosthesis2162660267110.1109/TMECH.2016.2596104Search in Google Scholar
Liu, J., Sheng, X., Zhang, D., He, J., and Zhu, X.. 2016. Reduced daily recalibration of myoelectric prosthesis classifiers based on domain adaptation. IEEE Journal of Biomedical and Health Informatics 20 No. 1: 166-175.LiuJ.ShengX.ZhangD.HeJ., and ZhuX.2016Reduced daily recalibration of myoelectric prosthesis classifiers based on domain adaptation20116617510.1109/JBHI.2014.238045425532196Search in Google Scholar
Mendez, I., Hansen, B.W., Grabow, C.M., Smedegaard, E.J.L., Skogberg, N.B., Uth, X.J., Bruhn, A., Geng, B., and Kamavuako, E.N.. 2017. Evaluation of the Myo Armband for the classification of hand motions. International Conference on Rehabilitation Robotics (ICORR), QEII Centre, London, UK, July 17–20, 2017: 1211-1214, DOI: 10.1109/ICORR.2017.8009414.MendezI.HansenB.W.GrabowC.M.SmedegaardE.J.L.SkogbergN.B.UthX.J.BruhnA.GengB., and KamavuakoE.N.2017International Conference on Rehabilitation Robotics (ICORR), QEII CentreLondon, UKJuly 17–20, 201712111214DOI: 10.1109/ICORR.2017.800941410.1109/ICORR.2017.800941428813986Search in Google Scholar
Menon, R., Di Caterina, G., Lakany, H., Petropoulakis, L., Conway, B.A., and Soraghan, J.J.. 2017. Study on interaction between temporal and spatial information in classification of EMG signals for myoelectric prostheses. IEEE Transactions on Neural Systems and Rehabilitation Engineering 25 No. 10: 1832-1842.MenonR.Di CaterinaG.LakanyH.PetropoulakisL.ConwayB.A., and SoraghanJ.J.2017Study on interaction between temporal and spatial information in classification of EMG signals for myoelectric prostheses25101832184210.1109/TNSRE.2017.268776128436879Search in Google Scholar
Merrill, D.R., Lockhart, J., Troyk, P.R., Weir, R.F., and Hankin, D.L.. 2011. Development of an implantable myoelectric sensor for advanced prosthesis control. Artificial Organs 35 No. 3: 249-252.MerrillD.R.LockhartJ.TroykP.R.WeirR.F., and HankinD.L.2011Development of an implantable myoelectric sensor for advanced prosthesis control35324925210.1111/j.1525-1594.2011.01219.x376825521371058Search in Google Scholar
Morais, G.D., Neves, L.C., Masiero, A., and Castro, M.C.F.. 2016. Application of Myo armband system to control a robot Interface. Proc. of 9th Int. Conf. on Biomedical Engineering Systems and Technologies, (BIOSTEC 2016) 4: 227-231, DOI:10.5220/0005706302270231.MoraisG.D.NevesL.C.MasieroA., and CastroM.C.F.2016Application of Myo armband system to control a robot Interface4227231DOI:10.5220/000570630227023110.5220/0005706302270231Search in Google Scholar
Myo Armband web site. Thalmic Labs. Website: www.myo.com/.Myo Armband web sitewww.myo.com/Search in Google Scholar
Myo Market. 2013 – 2016, Wthalmic Labs Inc. Website: https://market.myo.com/.Myo Market2013 – 2016https://market.myo.com/Search in Google Scholar
Open bionics web site. available at: www.openbionics.com.Open bionics web sitewww.openbionics.comSearch in Google Scholar
Ottobock HealthCare GmbH (a). available at: http://bebionic.com/the_hand/features/.Ottobock HealthCare GmbH (a)http://bebionic.com/the_hand/features/Search in Google Scholar
Ottobock HealthCare GmbH (b). Technical document: http://bebionic.com/distributor/documents/RSLLIT373-_bebionic_Tech_Manual_Small_web1.pdf.Ottobock HealthCare GmbH (b)http://bebionic.com/distributor/documents/RSLLIT373-_bebionic_Tech_Manual_Small_web1.pdfSearch in Google Scholar
Patrono, L., Primiceri, P., Rametta, P., Sergi, I., and Visconti, P.. 2017. An innovative approach for monitoring elderly behavior by detecting home appliance’s usage. IEEE Proc. of 25th Int. Conference on Software, Telecommunications and Computer Networks SoftCOM, Split – Croatia, Sept. 21–23, 2017: 1-7, DOI: 10.23919/SOFTCOM.2017.8115547.PatronoL.PrimiceriP.RamettaP.SergiI., and ViscontiP.2017IEEE Proc. of 25th Int. Conference on Software, Telecommunications and Computer Networks SoftCOM, Split – CroatiaSept. 21–23, 201717DOI: 10.23919/SOFTCOM.2017.811554710.23919/SOFTCOM.2017.8115547Search in Google Scholar
Primiceri, P., Visconti, P., Melpignano, A., Vilei, A., and Colleoni, G.M.. 2016. Hardware and software solution developed in ARM mbed environment for driving and controlling DC brushless motors based on ST X-NUCLEO development boards. International Journal on Smart Sensing and Intelligent Systems 9 3: 1534-1562.PrimiceriP.ViscontiP.MelpignanoA.VileiA., and ColleoniG.M.2016Hardware and software solution developed in ARM mbed environment for driving and controlling DC brushless motors based on ST X-NUCLEO development boards931534156210.21307/ijssis-2017-929Search in Google Scholar
Raspopovic, S., Capogross, M., Petrini, F.M., Bonizzato, M., Rigosa, J., Di Pino, G., Carpaneto, J., Controzzi, M., Boretius, T., Fernandez, E., Granata, G., Oddo, C.M., Citi, L., Ciancio, A.L., Cipriani, C., Carrozza, M.C., Jensen, W., Guglielmelli, E., Stieglitz, T., Rossini, P.M., and Micera, S.. 2015. Restoring natural sensory feedback in real-time bidirectional hand prostheses. Science Translational Medicine 6 No. 222: 222ra19, doi: 10.1126/scitranslmed.3006820.RaspopovicS.CapogrossM.PetriniF.M.BonizzatoM.RigosaJ.Di PinoG.CarpanetoJ.ControzziM.BoretiusT.FernandezE.GranataG.OddoC.M.CitiL.CiancioA.L.CiprianiC.CarrozzaM.C.JensenW.GuglielmelliE.StieglitzT.RossiniP.M., and MiceraS.2015Restoring natural sensory feedback in real-time bidirectional hand prostheses6222222ra1910.1126/scitranslmed.300682024500407Open DOISearch in Google Scholar
Sathiyanarayanan, M., Mulling, T., and Nazir, B.. 2015. Controlling a robot using a wearable device (MYO). International Journal of Engineering Development and Research IJEDR1503035 3 No. 3: 1-6.SathiyanarayananM.MullingT., and NazirB.2015Controlling a robot using a wearable device (MYO)3316Search in Google Scholar
Shin, H.S., Ganiev, A., and Lee, K.H.. 2015. Design of a virtual robotic arm based on the EMG variation. Advanced Science and Technology Letters 113: 38-43, http://dx.doi.org/10.14257/astl.2015.113.09.ShinH.S.GanievA., and LeeK.H.2015Design of a virtual robotic arm based on the EMG variation1133843http://dx.doi.org/10.14257/astl.2015.113.0910.14257/astl.2015.113.09Search in Google Scholar
Tan, D.W., Schiefer, M.A., Keith, M.W., Anderson, J.R., Tyler, J., and Tyler, D.J.. 2014. A neural interface provides long-term stable natural touch perception. Science Translational Medicine 6 No. 257: 1-25, doi: 10.1126/scitranslmed.3008669.TanD.W.SchieferM.A.KeithM.W.AndersonJ.R.TylerJ., and TylerD.J.2014A neural interface provides long-term stable natural touch perception6257125doi:10.1126/scitranslmed.3008669551730525298320Open DOISearch in Google Scholar
Tarantino, S., Clemente, F., Barone, D., Controzzi, M., and Cipriani, C.. 2017. The myokinetic control interface: tracking implanted magnets as a means for prosthetic control. Scientific Reports 7 No. 17149: 1-11, doi: 10.1038/s41598-017-17464-1.TarantinoS.ClementeF.BaroneD.ControzziM., and CiprianiC.2017The myokinetic control interface: tracking implanted magnets as a means for prosthetic control717149111doi:10.1038/s41598-017-17464-1571944829215082Open DOISearch in Google Scholar
Thalmic Labs Inc.. 2013 – 2017. www.youtube.com/watch?v=LSuzMxQDmzg.2013 – 2017www.youtube.com/watch?v=LSuzMxQDmzgSearch in Google Scholar
Thalmic Labs Inc.. 2013-2018. www.thalmic.com/.2013-2018www.thalmic.com/Search in Google Scholar
Touch Bionics Inc. 2018. www.touchbionics.com/.2018www.touchbionics.com/Search in Google Scholar
Troyk, P., Michele, G., Kerns, D., and Weir, R.. 2007. IMES: an implantable myoelectric sensor. 29th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 2007 (EMBS 2007), Lyon, France, Aug. 22–26, 2007: 1730-1703.TroykP.MicheleG.KernsD., and WeirR.200729th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 2007 (EMBS 2007)Lyon, FranceAug. 22–26, 200717301703Search in Google Scholar
Victoria Hand project. available at: www.victoriahandproject.com.Victoria Hand projectwww.victoriahandproject.comSearch in Google Scholar
Vidovic, M., Hwang, H.J., Amsuss, S., Hahne, J., Farina, D., and Müller, K.-R.. 2016. Improving the robustness of myoelectric pattern recognition for upper limb prostheses by covariate shift adaptation. IEEE Transactions Neural Systems and Rehabilitation Engineering 24 No. 9: 961-970, doi: 10.1109/TNSRE.2015.2492619.VidovicM.HwangH.J.AmsussS.HahneJ.FarinaD., and MüllerK.-R.2016Improving the robustness of myoelectric pattern recognition for upper limb prostheses by covariate shift adaptation249961970doi:10.1109/TNSRE.2015.249261926513794Open DOISearch in Google Scholar
Visconti, P., Ekuakille, A.L., Primiceri, P., Ciccarese, G., and de Fazio, R.. 2017b. Hardware design and software development for a white led-based experimental spectrophotometer managed by a PIC-based control system. IEEE Sensors Journal 17 No. 8: 2507-2515, doi: 10.1109/JSEN.2017.2669529.ViscontiP.EkuakilleA.L.PrimiceriP.CiccareseG., and de FazioR.2017bHardware design and software development for a white led-based experimental spectrophotometer managed by a PIC-based control system17825072515doi:10.1109/JSEN.2017.2669529Open DOISearch in Google Scholar
Visconti, P., Sbarro, B., and Primiceri, P.. 2017a. A ST X-Nucleo-Based telemetry unit for detection and wifi transmission of competition car sensors data: firmware development, sensors testing and real-time data analysis. International Journal on Smart Sensing and Intelligent Systems 10 No. 4: 793-828.ViscontiP.SbarroB., and PrimiceriP.2017aA ST X-Nucleo-Based telemetry unit for detection and wifi transmission of competition car sensors data: firmware development, sensors testing and real-time data analysis10479382810.21307/ijssis-2018-019Search in Google Scholar
Visconti, P., Orlando, C., and Primiceri, P.. 2016. Solar Powered WSN for monitoring environment and soil parameters by specific app for mobile devices usable for early flood prediction or water savings. IEEE 16th Int. Conference on Environment and Electrical Engineering, Florence, Italy: 1-6, DOI:10.1109/EEEIC.2016.7555638.ViscontiP.OrlandoC., and PrimiceriP.2016Solar Powered WSN for monitoring environment and soil parameters by specific app for mobile devices usable for early flood prediction or water savingsFlorence, Italy16DOI:10.1109/EEEIC.2016.755563810.1109/EEEIC.2016.7555638Search in Google Scholar
Visconti, P., Giannotta, G., Primiceri, P., de Fazio, R., Brama, R., and Malvasi, A.. 2017d. Operation principle, advanced procedures and validation of a new Flex-SPI communication Protocol for smart IoT devices. International Journal on Smart Sensing and Intelligent Systems 10 No. 3: 506-550.ViscontiP.GiannottaG.PrimiceriP.de FazioR.BramaR., and MalvasiA.2017dOperation principle, advanced procedures and validation of a new Flex-SPI communication Protocol for smart IoT devices10350655010.21307/ijssis-2017-222Search in Google Scholar
Visconti, P., Giannotta, G., Primiceri, P., de Fazio, R., Brama, R., and Malvasi, A.. 2017c. Framework implementation, firmware development and characterization of FlexSPI communication protocol: energy consumption analysis and comparison with I2C standard. International Journal on Smart Sensing and Intelligent Systems 10 No. 4: 754-792.ViscontiP.GiannottaG.PrimiceriP.de FazioR.BramaR., and MalvasiA.2017cFramework implementation, firmware development and characterization of FlexSPI communication protocol: energy consumption analysis and comparison with I2C standard10475479210.21307/ijssis-2018-018Search in Google Scholar
Yang, D., Yang, W., Huang, Q., and Liu, H.. 2017. Classification of multiple finger motions during dynamic upper limb movements. IEEE Journal of Biomedical and Health Informatics 21 No. 1: 134-141.YangD.YangW.HuangQ., and LiuH.2017Classification of multiple finger motions during dynamic upper limb movements21113414110.1109/JBHI.2015.249071826469791Search in Google Scholar
Zappatore, G.A., Reina, G., and Messina, A.. 2017. Analysis of a highly underactuated robotic hand. International Journal of Mechanics and Control 18 No. 4: 17-23.ZappatoreG.A.ReinaG., and MessinaA.2017Analysis of a highly underactuated robotic hand1841723Search in Google Scholar
Zappatore, G.A., Reina, G., and Messina, A.. 2016. Adam’s hand: an underactuated robotic end-effector. in Boschetti, G., and Gasparetto, A. (eds), Advances in Italian Mechanism Science. Mechanisms and Machine Science 47, Springer, Cham: 239-246.ZappatoreG.A.ReinaG., and MessinaA.2016BoschettiG., and GasparettoA.47SpringerCham239246Search in Google Scholar