Archive

Abstract:

In cooperative transmission selection of relay is considered to be the crucial factor for reliable transmission where multiple parameters are there for decision making. Again, many existing research works highlighted the problem, but none of them considered the vagueness & uncertainty of the decision makers. Currently, Fuzzy analytic hierarchy process (FAHP) proves to be an advantageous scheme for multiple criteria decision-making (MCDM) in fuzzy conditions. This paper provides FAHP-based relay node selection scheme that prioritizes the fuzziness of the decision makers during the relay node selection procedure. Numerical examples and simulation study, both are carried out to find out the best relay. The simulation study reveals the fact that the proposed scheme outperforms the existing systems.

Keywords:

Best Relay selection,Relay node,Cognitive radio Networks,Decision making,analytical hierarchy process,Fuzzy analytical hierarchy process,

Refference:

I.Akyildiz, I. F.; Wang, X. and Wang, W. “Wireless mesh networks: a survey”. Computer networks, 47(4), pp 445-487 (2005).

II.Akyildiz, I. F.; et. al. “CRAHNs: Cognitive radio ad hoc networks”. Ad Hoc Networks, 7(5), pp 810-836 (2009).

III.Buckley J. J. “Fuzzy hierarchical analysis. Fuzzy sets and systems”, 17(3), pp 233-247, (1985)

IV.Banerjee J.S.; Chakraborty A. and Chattopadhyay A. “Fuzzy Based RelaySelection for Secondary Transmission in Cooperative Cognitive RadioNetworks”. In: Proc. OPTRONIX, Springer, pp 279-287 (2017).

V.Banerjee J.S.; Chakraborty A and Chattopadhyay A. “Relay node selection using analytical hierarchy process (AHP) for secondary transmission in multi-user cooperative cognitive radio systems”. In: Proc. ETAEERE, Springer, pp 745-754 (2018).

VI.Banerjee, J. S. and Chakraborty, A. “Fundamentals of Software DefinedRadio and Cooperative Spectrum Sensing: A Step Ahead of CognitiveRadio Networks”. In Handbook of Research on Software-Defined andCognitive Radio Technologies for Dynamic Spectrum Management, IGIGlobal, pp 499-543 (2015).

VII.Banerjee, J.S.; Chakraborty, A. and Karmakar, K. “Architecture ofCognitive Radio Networks”. In N. Meghanathan & Y.B.Reddy (Ed.),Cognitive Radio Technology Applications for Wireless and Mobile AdHoc Networks, IGI Global, pp 125-152 (2013).

VIII.Banerjee, J.S. and Chakraborty, A. “Modeling of Software Defined RadioArchitecture & Cognitive Radio, the Next Generation Dynamic and SmartSpectrum Access Technology”. In M.H. Rehmani & Y. Faheem (Ed.),

Cognitive Radio Sensor Networks: Applications, Architectures, and Challenges, IGI Global, pp. 127-158 (2014).

IX. Banerjee, J.S. and Karmakar, K. “A Comparative Study on Cognitive Radio Implementation Issues”. International Journal of ComputerApplications, 45(15), No.15, pp 44-51 (2012).

X.Chakraborty, A. and Banerjee, J. S. “An Advance Q Learning (AQL) Approach for Path Planning and Obstacle Avoidance of a Mobile Robot”. International Journal of Intelligent Mechatronics and Robotics, 3(1), pp 53-73 (2013).

XI.Chakraborty, A.; Banerjee, J. S. and Chattopadhyay, A. “Non-UniformQuantized Data Fusion Rule Alleviating Control Channel Overhead forCooperative Spectrum Sensing in Cognitive Radio Networks”. In: Proc.IACC, pp 210-215 (2017).

XII.FCC (2003). ET Docket No 03-222 Notice of proposed rule making andorder.

XIII.Gao, X.; Wu, G. and Miki, T. “End-to-end QoS provisioning in mobileheterogeneous networks”.Wireless Communications, IEEE, 11(3), pp 24-34 (2004).

XIV.Jing, T.; Zhu, S.; Li, H.; Xing, X.; Cheng, X.; Huo, Y.; … and Znati, T.“Cooperative relay selection in cognitive radio networks”. IEEETransactions on Vehicular Technology, 64(5), pp 1872-1881(2015).

XV.Kandukuri, S. and Boyd, S. “Optimal power control in interference-limited fading wireless channels with outage-probability specifications”.IEEE transactions on wireless communications, 1(1), pp 46-55 (2002).

XVI.Laneman, J. N.; Tse, D. N. and Wornell, G. W. “Cooperative diversity inwireless networks: Efficient protocols and outage behavior”. IEEETransactions on Information theory, 50(12), pp 3062-3080 (2004).

XVII.Mitola, J. and Maguire Jr, G. Q. “Cognitive radio: making software radiosmore personal”. IEEE Personal Communications, 6(4), pp 13-18 (1999).

XVIII.Mitola,J. III.”Cognitive Radio— An Integrated Agent Architecture forSoftware Defined Radio”. Sweden: Royal Institute of Technology, (2000).

XIX.Paul S.; et. al. “A Fuzzy AHP-Based Relay Node Selection Protocol forWireless Body Area Networks (WBAN)”. In: Proc. OPTRONIX 2017(Press), IEEE, Nov. (2017).

XX.Paul S.; et. al.“The Extent Analysis Based Fuzzy AHP Approach for Relay Selection in WBAN”. In: Proc. CISC (Press), AISC-Springer, (2018).

XXI.Saha O.; Chakraborty A. and Banerjee J. S. “A Decision Framework ofIT-Based Stream Selection Using Analytical Hierarchy Process (AHP) for

Admission in Technical Institutions”. In: Proc. OPTRONIX 2017 (Press),IEEE, Nov. (2017).

XXII.Saha O.; Chakraborty A. and Banerjee J.S.: A Fuzzy AHP Approach toIT-Based Stream Selection for Admission in Technical Institutions inIndia. In: Proc. IEMIS (Press), AISC-Springer, (2018).

XXIII.Simeone, O.; Gambini, J.; Bar-Ness, Y. and Spagnolini, U. “Cooperationand cognitive radio”. In ICC, IEEE, pp 6511-6515 (2007)

XXIV.Zou, Y.; Zhu, J.; Zheng, B.; Tang, S. and Yao, Y. D. “A cognitivetransmission scheme with the best relay selection in cognitive radionetworks”. In GLOBECOM, IEEE, pp 1-5 (2010).

XXV.Zhang, Q.; Jia, J. and Zhang, J. “Cooperative relay to improve diversity in cognitive radio networks”. IEEE Communications Magazine, 47(2), pp111-117 (2009).

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Abstract:

This paper deals withsteady two dimensional laminar convection flow of nano fluid over aconvective heated inclined plate.Boungiorno model [VI] is employed that treats the nanofluid as a two-component mixture (base fluid plus nanoparticles), incorporating the effects of Brownian motion and thermophoresis.Byappropriate similarvariables, the governing nonlinear partial differential equations of flow are transformed to a set of nonlinear ordinary differential equations. Subsequently they are reduced to a first order system and integrated using Newton Raphson and adaptive Runge-Kutta methods. The computer codes are developed for this numerical analysis in Matlab environment. Dimensionless stream function (s), longitudinal velocity (s′), temperature (θ) and nano particle volume fraction (f) are computed and illustrated graphically for various values of thedimensionless parameters relevant to the present problem. The effects of the angle of inclination on longitudinal velocity (s′), temperature (θ) and nano particle volume fraction (f) are discussed. The results of the present simulation are in with good agreement with the previous reports available in literature.

Keywords:

Brownian Motion,Boundary Layer,Convective Boundary Condition,Inclined Plate, Nano fluid,Thermophoresis,

Refference:

I. Alam,M., Rahman,M., Sattar,M.: On the effectiveness of viscous dissipation and joule heating on steady magnetohydrodynamic heat and mass transfer flow over an inclined radiate isothermal permeable surfacein the presence of thermophoresis. Commun.Nonlinear Sci. Numer.Simul.14, 2132–2143 (2009)

II. Anghel, M., Hossain, M.A., Zeb, S., Pop, I., Combined heat and mass transfer by free convection past aninclined flat plate. Int. J. Appl. Mech. Eng. 2, 473–497 (2001).

III. Ishak A., Similarity solutions for flow and heat transfer over a permeable surface with convective boundary condition, Appl. Math. Computation, 217(2010), 837-842. (periodical)

IV. Aziz A., A similarity Solution for Laminar Thermal Boundary Layer over a Flat Plate with a Convective Surface Boundary Condition, Commun. Nonlinear Sci. Numer.Simulat., 14 (2009), 1064-1068.

V.Bianchi M. V. A. and ViskantaR., Momentum and heat transfer on a continuous flat surface movingin a parallel counterflow free stream, W/irme-und Stoff/ibertragung 29, 89-94 (1993)

VI. Buongiorno J., Convective transport in nanofluids, ASME J. Heat Transf. 128 (2006) 240–250.

VII. Choi S., Enhancing thermal conductivity of fluids with nanoparticle in: D.A. Siginer, H.P. Wang (Eds.), Developments and Applications of Non-Newtonian Flows, ASME MD vol. 231 and FED vol. 66, 1995, pp. 99–105.

VIII. Chen, C.H., Heat andmass transfer inMHDflowby natural convection from a permeable, inclined surfacewith variable wall temperature and concentration. Acta Mech. 172, 219–235 (2004)

IX. Khan W. A. and Aziz A., Natural convection flow of a nanofluid over a vertical plate with uniform surface heat flux, International Journal of Thermal Sciences, 50 (2011) 1207-1214.

X. KuznetsovA.V. and NieldD.A., Natural convective boundary-layer flow of a nanofluid past a vertical plate, Int. J. Thermal Sciences, 49, (2010) 243–247.

XI. Makinde O. D. and Aziz A., Boundary Layer Flow of a Nanofluid Past a Stretching Sheet with Convective Boundary Condition, Int. J. Therm. Sci., 50 (2011), 1326-1332. (periodical)

XII. Mitra A., Computational Modeling of Boundary-Layer Flow of a Nanofluid Past a Nonlinearly Stretching Sheet ,J. Mech.Cont. & Math. Sci., Vol.-13, No.-1, March –April (2018) Pages 101-114.

XIII. NieldD.A. andKuznetsovA.V., Thermal instability in a porous medium layer saturated by a nanofluid, Int.J.Heat Mass Transf, 52 (2009) 5796–5801.

XIV. SuneethaS. and Gangadhar K., Thermal Radiation Effect on MHD Stagnation Point Flow of a Carreau Fluid with Convective Boundary Condition, Open Science Journal of Mathematics and Application, 3(5): 121-127, 2015.

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Abstract:

In the recent time,the research and development have been blooming in the field of the prosthetic system,especially on the prosthetic arm.Thispaper emphasizesa precise study of continues advancement of the prosthetic arm. The latest expansions of the prosthetic arm are renovated with implementations of biomedical innovations. Different novel approaches are reflected in a sort of research works with technical progress considering the diverse aspect of complexity, cost, size, material, dexterity, the degree of freedom. A Systematic research and development work on the prosthetic arm and Electromyography(EMG) controlled prosthetic arm devices, Electroneurographysignal (ENG) driven prosthetic arm and devices are deeply specified in this paper. The innate efforts of the scientists and researchers of this field as well as accumulated erudition from various research papers, books and patents areenlightened and assisted in this attempt of drawing a complete overview of arm prosthesis.

Keywords:

Prosthetic Arm,Bio-signal,Electromyography (EMG),Electroneurography (ENG), Electro-Mechanical Arm,

Refference:

I. Aishwarya, R., Prabhu, M., Sumithra, G.& Anusiya, M. (2013), ‘Featureextraction for emg based prostheses control’, ICTACT journal on soft computing 3(2),472–7.

II. Ajiboye, A. B. & Weir, R. F. (2005), ‘A heuristic fuzzy logic approach to emgpattern recognition for multifunctional prosthesis control’, IEEE transactions on neural systems and rehabilitation engineering 13(3),280–291.

III.Arieta,A.H.,Yokoi,H.,Arai,T.&Wenwei,Y.(2005),Fesasbiofeedbackforanemg controlledprosthetichand,in‘TENCON20052005IEEERegion10’,IEEE,pp.1–6.

IV. Battye, C., Nightingale, A. & Whillis, J. (1955), ‘The use of myo-electriccurrentsin theoperationofprostheses’,Bone&JointJournal37(3),506–510.

V.Berger, N. & Huppert, C. R. (1952), ‘The useof electrical and mechanicalmuscular forces for the control of an electrical prosthesis.’, The American journal of occupational therapy: official publication of the American OccupationalTherapy Association 6(3),110.

VI. Bifulco,P.,Esposito,D.,Gargiulo,G.,Savino,S.,Niola,V.,Iuppariello,L.&Cesarelli, M. (2017), A stretchable, conductive rubber sensor to detect muscle contraction for prosthetic hand control, in ‘E-Health and Bioengineering Conference (EHB), 2017’, IEEE, pp. 173–176.

VII. Bigg, H. H. (1855), On artificial limbs, their construction and application, John Churchill.

VIII. Bundhoo,V.&Park,E.J.(2005),Designofanartificialmuscleactuatedfingertowards biomimetic prosthetic hands, in ‘Advanced Robotics, 2005. ICAR’05. Proceedings., 12th International Conference on’, IEEE, pp.368–375.

IX. Carozza, M., Cappiello, G., Stellin, G., Zaccone, F., Vecchi, F., Micera, S. & Dario,P. (2005), On the developmentof a novel adaptive prosthetic hand with compliant joints: experimental platform and emg control, in ‘Intelligent Robots and Systems, 2005.(IROS 2005). 2005 IEEE/RSJ International Conference on’, IEEE, pp. 1271–1276.

X. Carpaneto, J., Cutrone, A., Bossi, S., Sergi, P., Citi, L., Rigosa, J., Rossini, P. M. & Micera,S.(2011),Activitiesonpnsneuralinterfacesforthecontrolofhandprostheses, in‘EngineeringinMedicineandBiologySociety,EMBC,2011AnnualInternational Conference of the IEEE’, IEEE, pp.4637–4640.

XI. Carrozza,M.C.,Dario,P.,Vecchi,F.,Roccella,S.,Zecca,M.&Sebastiani,F.(2003), Thecyberhand:onthedesignofacyberneticprosthetichandintendedtobeinterfaced to the peripheral nervous system, in ‘Intelligent Robots and Systems, 2003.(IROS 2003). Proceedings. 2003 IEEE/RSJ International Conference on’, Vol. 3, IEEE, pp.2642–2647.

XII. Carrozza, M. C., Massa, B., Micera, S., Lazzarini, R., Zecca, M. & Dario, P. (2002), ‘The development of a novel prosthetic hand-ongoing research and preliminary results’,IEEE/AsmeTransactionsonMechatronics7(2),108–114.

XIII. Cavallaro, E., Micera, S., Dario, P., Jensen, W. & Sinkjaer, T. (2003), ‘On the intersubject generalization ability in extracting kinematic information from afferent nervoussignals’,IEEEtransactionsonbiomedicalengineering50(9),1063–1073.

XIV Childress,D.S.(1985),‘Historicalaspectsofpoweredlimbprostheses’,ClinProsthet Orthot 9(1),2–13.

XV Ciancio, A. L., Cordella, F., Barone, R., Romeo, R. A., Bellingegni, A. D.,Sacchetti, R., Davalli, A., Di Pino, G., Ranieri, F., Di Lazzaro, V. et al. (2016), ‘Control of prosthetichandsviatheperipheralnervoussystem’,Frontiersinneuroscience.

XVI Cloutier, A. & Yang, J. (2013), Control of hand prostheses: A literature review, in ‘ASME2013InternationalDesignEngineeringTechnicalConferencesandComputers andInformationinEngineeringConference’,Vol.7,AmericanSocietyofMechanical Engineers.

XVII Dhillon,G.S.&Horch,K.W.(2005),‘Directneuralsensoryfeedbackandcontrolof aprostheticarm’,IEEEtransactionsonneuralsystemsandrehabilitationengineering 13(4),468–472.

XVIII Edell, D., Riso, R., Devaney, L., Larsen, B., Koris, M. & DeLorenzo, D. (1996), Intraneuralmicrostimulationforenhancedprostheticcontrolusingaperipheralnerve interface,in‘EngineeringinMedicineandBiologySociety,1996.BridgingDisciplines for Biomedicine. Proceedings of the 18th Annual International Conference of the IEEE’, Vol. 1, IEEE, pp.337–338.

XIX. Eder, C. F. (2015), ‘System for recording electroneurographic activity’. US Patent 9,107,636.

XX. Englehart, K., Hugdins, B. & Parker, P. (2000), ‘Multifunction control of prostheses using the myoelectricsignal’.

XXI. Fukuda, O., Bu, N. & Ueno, N. (2010), Training of grasping motion using a virtual prosthetic control system, in ‘Systems Man and Cybernetics (SMC), 2010 IEEE International Conference on’, IEEE, pp.1793–1798.

XXII. Geethanjali, P. & Ray, K. (2011), ‘Identification of motion from multi-channel emg signals for control of prosthetic hand’, Australasian physical & engineeringsciences in medicine 34(3),419–427.

XXIII. Grahn, E. C., Duff, S. J. et al. (2001), ‘A new externally powered, myoelectrically controlled prosthesis for persons with partial-hand amputations at the metacarpals’, JPO:JournalofProstheticsandOrthotics13(2),26.

XXIV. Hauschild, M., Davoodi, R. & Loeb, G. E. (2006), Designing and fitting fes and prosthetic systems in a virtual reality environment, in ‘Virtual Rehabilitation, 2006 International Workshop on’, IEEE, pp.167–173.

XXVHerberts, P., Almstrom, C. & Caine, K. (1978), ‘Clinical application study of multifunctionalprosthetichands’,Bone&JointJournal60(4),552–560.XXVI. Herberts, P., Almström, C., Kadefors, R. & Lawrence, P. D. (1973), ‘Handprosthesis controlviamyoelectricpatterns’,ActaOrthopaedicaScandinavica44(4-5),389–409.

XXVII. Hesse, F. & Herrmann, J. M. (2010), Homeokinetic prosthetic control: collaborative selectionofmyosignalfeatures,in‘RO-MAN,2010IEEE’,IEEE,pp.410–415.

XXVIII. Hong-liu, Y., Sheng-nan, Z. & Jia-hua, H. (2010), Mmg signal and its applications in prosthesis control, in ‘Proceedings of the 4th International Convention on RehabilitationEngineering&AssistiveTechnology’,SingaporeTherapeutic,Assistive & Rehabilitative Technologies (START) Centre, p.58.

XXIX. Huang, H., Jiang, L., Liu, Y., Hou, L., Cai, H. & Liu, H. (2006), The mechanical designandexperimentsofhit/dlrprosthetichand,in‘RoboticsandBiomimetics,2006. ROBIO’06. IEEE International Conference on’, IEEE, pp.896–901.

XXX. Ishii, C., Harada, A., Nakakuki, T. & Hashimoto, H. (2011), Control of myoelectric prosthetic hand based on surface emg, in ‘Mechatronics and Automation (ICMA), 2011 International Conference on’, IEEE, pp.761–766.

XXXI. Jacobson,S.C.,Knutti,D.F., Johnson,R.T.&Sears,H.H.(1982),‘Developmentof theutahartificialarm’,IEEETransactionsonBiomedicalEngineering(4),249–269. Kamikawa,Y.&Maeno,T.(2008),Underactuatedfive-fingerprosthetichandinspired by grasping force distribution of humans, in ‘Intelligent Robots and Systems, 2008. IROS2008.IEEE/RSJInternationalConferenceon’,IEEE,pp.717–722.

XXXII. Kessler, H. H. & Kiessling, E. A. (1965), ‘The pneumatic arm prosthesis’, The American journal of nursing pp.114–117.

XXXIII. Khezri, M. & Jahed, M. (2007), ‘Real-time intelligent pattern recognition algorithm for surface emg signals’, Biomedical engineering online 6(1),45.

XXXIV. Kim, G., Asakura, Y., Okuno, R. & Akazawa, K. (2006), Tactile substitution system for transmitting a few words to a prosthetic hand user, in ‘Engineering in Medicine andBiologySociety,2005.IEEE-EMBS2005.27thAnnualInternationalConference of the’, IEEE, pp.6908–6911.

XXXV. Kim,K.&Colgate,J.E.(2012),‘Hapticfeedbackenhancesgripforcecontrolofsemg-controlled prosthetic hands in targeted reinnervation amputees’, IEEE Transactions on Neural Systems and Rehabilitation Engineering 20(6),798–805

XXXVI.Kim,K.,Colgate,J.E.,Santos-Munné,J.J.,Makhlin,A.&Peshkin,M.A.(2010),‘On the design of miniature haptic devices for upper extremity prosthetics’, IEEE/ASME TransactionsonMechatronics15(1),27–39.

XXXVII. Kim, Y.-J., Bhamra, H. S., Joseph, J. & Irazoqui, P.P. (2015), ‘An ultra-low-power rf energy-harvesting transceiver for multiple-node sensor application’, IEEE TransactionsonCircuitsandSystemsII:ExpressBriefs62(11),1028–1032.

XXXVIII. Kundu, S. K. & Kiguchi, K. (2008), Development of a 5 dof prosthetic arm for above elbow amputees, in ‘Mechatronics and Automation, 2008. ICMA 2008. IEEE International Conference on’, IEEE, pp.207–212.

XXXIX.Langenfeld, C. C., Evans, C. O., Smith III, S. B., Muller, A. H., Kerwin, J. M., Schnellinger, T. S., Guay, G. M. & Van der Merwe, D. A. (2015), ‘Arm prosthetic device’. US Patent9,114,028.

XL. Lee, H. & Roberson, D. J. (2007), A systemic view of an upper extremityprosthesis, in ‘System of Systems Engineering, 2007. SoSE’07. IEEE International Conference on’, IEEE, pp.1–6.

XLI. Lenzi, T., Lipsey, J. & Sensinger, J. W. (2016), ‘The ric arm⣔a small anthropomorphic transhumeral prosthesis’, IEEE/ASME Transactions on Mechatronics 21(6),2660–2671.

XLII.Li, G. & Kuiken, T. A. (2008), ‘Modeling of prosthetic limb rotation control by sensingrotationofresidualarmbone’,IEEETransactionsonBiomedicalEngineering 55(9),2134–2142.

XLIII.Light,C.,Chappell,P.,Hudgins,B.&Engelhart,K.(2002),‘Intelligentmultifunction myoelectriccontrolofhandprostheses’,Journalofmedicalengineering&technology 26(4),139–146.

XLIV.Magenes, G., Passaglia, F. & Secco, E. L. (2008), A new approach of multi-dof prosthetic control, in ‘Engineering in Medicine and Biology Society, 2008. EMBS 2008. 30th Annual International Conference of the IEEE’, IEEE, pp.3443–3446. Marks,G.E.(1888),ATreatiseonMarks’PatentArtificialLimbswithRubberHands and Feet, AAMarks.

XLV. Marquardt, E. (1965), ‘The heidelberg pneumatic arm prosthesis’, Bone & Joint Journal 47(3),425–434.XLVI. Massa,B.,Roccella,S.,Carrozza,M.C.&Dario,P.(2002),Designanddevelopment ofanunderactuatedprosthetichand,in‘Robotic sand Automation,2002.Proceedings. ICRA’02. IEEE International Conference on’, Vol. 4, IEEE, pp.3374–3379.

XLVII. McLeish,R.(1968),‘Adesignstudyofahydraulicallyoperatedartificialarmpowered bynormalwalking’,MedicalandBiologicalEngineeringandComputing6(1),3–17.

XLVIII. Micera,S.&Navarro,X.(2009),‘Bidirectionalinterfaceswiththeperipheralnervous system’, International review of neurobiology 86,23–38.

XLIX.Micera,S.,Carpaneto,J.&Raspopovic,S.(2010),‘Controlofhandprosthesesusing peripheral information’, IEEE Reviews in Biomedical Engineering 3,48–68.

L. Micera, S., Jensen, W., Sepulveda, F., Riso, R. R. & Sinkjær, T. (2001), ‘Neuro-fuzzy extractio of angular information from muscle afferents for ankle control during standing in paraplegic subjects:ananimalmodel’,IEEET ransactionson Biomedical Engineering 48(7),787–794.

LI. Micera, S., Navarro, X., Carpaneto, J., Citi, L., Tonet, O., Rossini, P. M., Carrozza,M.C.,Hoffmann,K.P.,Vivo,M.,Yoshida,K.etal.(2008),‘Ontheuseoflongitudinal intrafascicular peripheral interfaces for the control of cybernetic hand prostheses in amputees’, IEEE Transactions on Neural Systems and Rehabilitation Engineering 16(5),453–472.

LII. Montgomery, S. (1968), Paper 12: Design of an experimental arm prosthesis: Engineering aspects, in ‘Proceedings of the Institution of Mechanical Engineers, Conference Proceedings’, Vol. 183, SAGE Publications Sage UK: London, England, pp.68–73.

LIII. Moore, E. J., De Marco, R. M., Foulds, R. A. & Alvarez, T. L. (2003), The implementation of an emgcontrolled robotic arm to motivate pre-college students to pursue biomedical engineering careers, in ‘Engineering in Medicine and Biology Society,2003.Proceedingsofthe25thAnnualInternationalConferenceoftheIEEE’, Vol. 4, IEEE, pp.3517–3520.

LIV. Moradi, M., Hashtrudi-Zaad, K., Mountjoy, K. & Morin, E. (2008), An emg-based force control system for prosthtic arms, in ‘Electrical and Computer Engineering, 2008. CCECE 2008. Canadian Conference on’, IEEE, pp.001737–001742.

LV.Muzumdar,A.(2004),PoweredUpperLimbProstheses:Control,Implementationand Clinical Application; 11 Tables, Springer Science & BusinessMedia.

LVI.Neogi,B.,Mukherjee,S.,Ghosal,S.,Das,A.&Tibarewala,D.N.(2011),‘Design and implementation of prosthetic arm using gear motor control technique with appropriate testing’,CoRR.

LVII.Nomura, K., Yada, K., Saihara, M. & Yoshida, M. (2006), Interferential current stimulation for sensory communication between prosthetic hand and man, in ‘Engineeringin Medicine and Biology Society,2005.IEEE-EMBS2005.27thAnnual International Conference of the’, IEEE, pp.6923–6926.

LVIII. O’Neill,C.(2014),Anadvanced, low cost prostheticarm,in‘SENSORS,2014IEEE’, IEEE, pp.494–498.

LIX.Parker, P., Englehart, K. & Hudgins, B. (2006), ‘Myoelectric signal processing for control of powered limb prostheses’, Journal of electromyography and kinesiology 16(6),541–548.

LX. Peerdeman, B., Boerey, D., Kallenbergy, L., Stramigioli, S. & Misra, S. (2010), A biomechanical model for the development of myoelectric hand prosthesis control systems, in ‘Engineering in Medicine and Biology Society (EMBC), 2010 Annual International Conference of the IEEE’, IEEE, pp.519–523.

LXI. Phinyomark, A., Limsakul, C. & Phukpattaranont, P.(2009), ‘A novel feature extractionforrobustemgpatternrecognition’,arXivpreprintarXiv:0912.3973.

LXII. Potluri,C.,Anugolu,M.,Yihun,Y.,Kumar,P.,Chiu,S.,Schoen,M.P.&Naidu,D. S. (2011), Implementation of semg-based real-time embedded adaptive finger force control for a prosthetic hand, in ‘Decision and Control and European Control Conference (CDC-ECC), 2011 50th IEEE Conference on’, IEEE, pp. 861–866.

LXIII. Rieger, R., Schuettler, M., Pal, D., Clarke, C., Langlois, P., Taylor, J. & Donaldson,N. (2006), ‘Very low-noise eng amplifier system using cmos technology’, IEEE Transactions on Neural Systems and Rehabilitation Engineering 14(4), 427–437

.LXIV. Rodriguez-Cheu, L. E. & Casals, A. (2006), Sensing and control of a prosthetic hand withmyoelectric feedback, in ‘Biomedical Robotics and Biomechatronics, 2006.BioRob2006.TheFirstIEEE/RAS-EMBSInternationalConferenceon’,IEEE, pp.607–612.

LXV. Rossini,P.M.,Micera,S.,Benvenuto,A.,Carpaneto,J.,Cavallo,G.,Citi,L.,Cipriani,C.,Denaro,L.,Denaro,V.,DiPino,G.etal.(2010),‘Doublenerveintraneuralinterface implant on a human amputee for robotic hand control’, Clinical neurophysiology 121(5),777–783.

LXVI. Sasaki, Y., Nakayama, Y. & Yoshida, M. (2002), Sensory feedback system using interferential current for emg prosthetic hand, in ‘Engineering in Medicine and Biology,2002.24thAnnualConferenceandtheAnnualFallMeetingoftheBiomedical Engineering Society EMBS/BMES Conference, 2002. Proceedings of the Second Joint’, Vol. 3, IEEE, pp.2402–2403.

LXVII.VScherillo, P., Siciliano, B., Zollo, L., Carrozza, M., Guglielmelli, E. & Dario, P. (2003), Parallel force/position control of a novel biomechatronic hand prosthesis, in ‘Advanced Intelligent Mechatronics, 2003. AIM 2003. Proceedings. 2003 IEEE/ASME International Conference on’, Vol. 2, IEEE, pp.920–925.

LXVIII. Schorsch, J. F., Maas, H., Troyk, P. R., DeMichele, G. A., Kerns, D. A. & Weir, R.F. (2008), Multifunction prosthesis control using implanted myoelectric sensors(imes), MyoelectricSymposium.

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LXX. Sebastiani,F.,Roccella,S.,Vecchi,F.,Carrozza,M.&Dario,P.(2003),Experimental analysis and performance comparison of three different prosthetic hands designed accordingtoabiomechatronicapproach,in‘AdvancedIntelligentMechatronics,2003. AIM 2003. Proceedings. 2003 IEEE/ASME International Conference on’, Vol. 1, IEEE, pp.64–69.

LXXI. Simpson, D. & Smith, J. (1977), ‘An externally powered controlled complete arm prosthesis’,Journalofmedicalengineering&technology1(5),275–277.

LXXII. Song, R., Tong, K.-y., Hu, X. & Zhou, W. (2013), ‘Myoelectrically controlled wrist robot for stroke rehabilitation’, Journal of neuroengineering andrehabilitation 10(1),52.

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Abstract:

n this paper, we implement divide by 32/33 dual modulus prescaler(DMP) using I-ETSPC based: divide by 2/3prescaler and divide by 4/5 by prescaler at 180nm CMOS technology. The divide by 32/33 dual modulus prescaler using 2/3 prescaler and 4/5 prescaler consumes 1.03mW and 0.85mW power from 1.2V and 1V respectively. To further improve speed and reduce design complexity with low power consumption a pseudo divide by 32/33 dual modulus prescaler is proposed. According to simulation results the pseudo divide by 32/33 dual modulus prescaler reaches a maximum 9.2 GHz working frequency at 1V with a 0.17mw power consumption. This prescaler is compared with Proposed I-ETSPC based divide by 32/33 using 2/3 and 4/5 prescalers and also with other recently published divide by 32/33 prescalers.Compared with previous conventional divide by 32/33 DMPs, this design contains fewer transistor numbers.

Keywords:

2/3 prescaler, 4/5 prescaler, divide by 32/33 prescalers, I –ETSPC,Sleepy Keeper Approach,

Refference:

I.C. Lee, L. C. Cho and S. I. Liu, “A 44GHz Dual-Modulus Divide-by-4/5 Prescaler in 90nm CMOS Technology,” IEEE Custom Integrated Circuits Conference (CICC ’06),San Jose, CA, pp. 397-400, 2006.

II.F. P. H. Miranda, J. Navarro and W. A. M. Van Noije, “ A 4 GHz Dual Modulus Divider-by 32/33 Prescaler in 0.35μm CMOS Technology” In Proc. of the 17th annual symposium on Integrated circuits and system design(SBCCI‟04), Pernanbuco, Brazil, pp. 94-99, Sept. 7-11, 2004.

III.F. P. H. Miranda, J. Navarro and W. A. M. Van Noije,“A 4.1 GHz Prescaler Using Double Data Throughput E-TSPC Structures,” In Proc. of the 20th annual symposium on Integrated circuits and system design(SBCCI‟07),Rio de Janeiro, Brazil, pp. 123-127, Sept. 3-6, 2007.

IV.J. N. Soares, Jr. and W. A. M. Van Noije, “A 1.6-GHz dual modulus prescaler using the extended true-single-phase-clock CMOS circuit technique (E-TSPC),” IEEE J. Solid-State Circuits, vol. 34, no. 1, pp. 97–102, Jan. 1999.

V.J.C. Park, V. J. Mooney, P. Pfeiffenberger, “Sleepy Stack Reduction of Leakage Power”,Proceeding of the International Workshop on Power and Timing Modeling Optimization and Simulation, pp. 148-158, September 2004.

VI.J. Wu, et al.: “A low-power high-speed true single phase clock divide-by-2/3 prescaler,” IEICE Electron. Express10 (2013) 20120913 (DOI: 10.1587/elex. 10.20120913).

VII.J. Navarro, and G. C. Martins, “Design of High Speed Digital Circuits with E-TSPC Cell Library,” In Proc. of the 24th symposium on Integrated circuits and systems design(SBCCI ’11), João Pessoa, Brazil, pp. 167-172, Aug. 30–Sept. 2, 2011 .

VIII.M. V. Krishna, M. A. Do, K. S. Yeo, C. C. Boon, and W. M. Lim, “Design and analysis of ultra-low power true single phase clock CMOS2/3 prescaler,” IEEE Trans. Circuits Syst. I, Reg. Papers, vol. 57, no. 1, pp. 72–82, Jan. 2010.

IX.R Jain, U Nirmal et al “Design and Optimization of Pseudo-NMOS basedImproved extended True Single-Phase Clock Technique low-Power Prescaler”, International Conference on Soft Computing,Intelligent Systems and Applications, April 8-9, 2016, Bangalore, India.

X.R. Jain, U. Nirmal et al., “Low Voltage Low Power 4/5 Dual Modulus Prescaler in 180nm CMOS Technology”, International Conference on Research Advances in Integrated Navigation Systems(RAINS -2016), May 6-7, 2016.

XI.S. Bhargava, U. Nirmal, “AUnified Approach in the Analysis of Prescalers and Dual Modulus Prescalers for low-power systems”International Journal of Applied Engineering Research ISSN 0973-4562 Volume 12, Number 12 (2017) pp. 3042-3048.

XII.S. Pellerano , S. Levantino , C. Samori , and A. L. Lacaita, “ A 13.5-mW 5-GHz Frequency Synthesizer with dynamic-logic frequency divider,” IEEE J. Solid-State Circuits, vol. 39, no. 2, pp. 378–383, Feb. 2004.

XIII.Song Jia, Shilin Yan et al, “Low-power, high-speed dual modulus prescaler based on branch-merged true single-phase clocked scheme” ELECTRONICS LETTERS,Vol. 51 No. 6 pp. 464–465, March 2015.

XIV.W.-H. Chen and B. Jung, “High-speed low-power true single-phase clock dual-modulus prescalers,” IEEE Transactions on Circuits and Systems II: Express Briefs, vol. 58, no. 3, pp. 144 –148, March 2011.

XV.W Jiang et. Al., “A low-power high-speed true single-phase clock-based divide-by-2/3 prescaler” IEICE Electronics Express, Vol 14, No. 1, 1 –6, 2017.

XVI.Xincun Ji et. Al., “ A 2.4 GHz fractional-N PLL with a low power true single phase clock prescaler ” IEICE Electronics Express, Vol 14, No. 8, 1 –8, 2017.

XVII.X.P. Yu, M.A. Do, W. M. Lim, K. S. Yeo, and J. G. Ma, “Design and optimization of the extended true single-phase clock-based prescaler,” IEEE Trans. Microwave Theory Tech., vol. 54, no. 11, pp. 3828–3835, Nov. 2006.

XVIII.Z. Deng and A. Niknejad, “The speed-power trade-off in the design of CMOS true-single-phase-clock dividers,” IEEE Journal of Solid-State Circuits, vol. 45, no. 11, pp. 2457 –2465, Nov. 2010.

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Abstract:

Observing the effect of PSO algorithm on the PID (Proportional-Integral-Derivative) controller is an advanced approach for getting a stable and linear response of any system. From few decades conventional PID tuning rules are used for analyzing any complex system. But these rules did not give always a satisfactory result as our requirement. That’s why a better algorithm was introduced which is actually based on Evolutionary Computation method. This methodology provides a very high accuracy in the response in comparison with other tuning rules.From thevery past, PID controller has been very popular and is being used in maximum industries. So, there’s always a need to control the accuracy and efficiency of the controller because depending on this controller the whole industry might be functioning. If any large error occurs in the controller (PID), the functioning of the industry might be hampered. That’s why using PSO algorithm for determining the PID parameter is a good idea to get an efficient and accurate output. This approach may help in future to improve the performance of PID controller and also may help to reduce errors encountered in the industries.

Keywords:

Particle Swarm Optimization (PSO),Evolutionary Computation Method,PID (Proportional-Integral-Derivative) controller,Ziegler-Nichols tuning method,

Refference:

I.Ankita Nayak, Mahesh Singh. “Study of Tuning of PID controllers by using Particle Swarm Optimization”. Int. J. Adv. Engg. Res. Studies/IV/II/Jan.-March,2015/346-350.

II.Arnob Senapati, A. K. Kashyap, B. K. Mondal, S. Chattarjee. “Speed performance Analysis of DC Servomotor Using Linear and Non Linear Controller”.International Journal for Research in Applied Science & Engineering Technology, Volume 6 Issue III, March 2018.

III.K.Lakshmi Sowjanya, L.Ravi Srinivas. “Tuning of PID controllers using Particle Swarm Optimization”. IJIEEE, Volume-3, Issue-2, Feb-2015.

IV.Mahmud Iwan Solihin, Lee Fook Tack, Moey Leap Kean. “Tuning of PID controllers using Particle Swarm Optimization”. ISC 2011, Malaysia, 14-15 January 2011.

V.Neha Kundariya, Jyoti Ohri. “Tuning of PID Controller for Time Delayed Process using Particle Swarm Optimization”. IJSET, Volume No.2, Issue No.7, PP: 665-669.

VI.S. Easter Selvan, Sethu Subramanian, S. Theban Solomon. “Novel Technique for PID Tuning by Particle Swarm Optimization”.

VII.S.M.GirirajKumar, Deepak Jayaraj, Anoop.R.Kishan. “PSO based Tuning of a PID Controller for a High Performance Drilling Machine”. International Journal of Computer Applications (0975-8887), Volume 1-No. 19.

VIII.Subhojit Malik, Palash Dutta, Sayantan Chakrabarti, Abhishek Barman. “Parameter Estimation of a PID Controller using Particle Swarm Optimization”. IJARCCE, Vol. 3, Issue 3, March 2014.

IX.Turki Y. Abdalla, Abdulkareem. A. A. “PSO-based Optimum design of PID Controller for Mobile Roboat Trajectory Tracking”. International Journal of Computer Applications (0975-8887), Volume 47-No. 23, June 2012.

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