Farzanegan Pub Farzanegan DOI info@joas.ir mEDRA 20260610 DOI Registration 01

06 10.22034/zagros.2020.1013.0602 https://rcsj.ir/user/articles/132 Farzanegan Pub mEDRA 01 01 132 zagros Publisher IR 01 132 JB 29 1 4 01 202606 7 10 01 [1] مجموعه مقالات سایت باشگاه نانو [2] Mingxia Gu, Ping Bai, Hong Son Chu, and Er-Ping Li, “Design of Subwavelength CMOS Compatible Plasmonic Photodetector for Nano-Electronic-Photonic Integrated Circuits”, IEEE Photonics Technology Letters 2012 [3] Jie Xiang, Wei Lu, Yongjie Hu, Yue Wu, Hao Yan & Charles M. Lieber, “Ge/Si Nanowire Heterostructures as Highperformance Field-Effect Transistors”, Nature Publishing Group 2006 [4] Bozhi Tian, Xiaolin Zheng, Thomas J. Kempa, Ying Fang, Nanfang Yu, Guihua Yu, Jinlin Huang & Charles M. Lieber, “Coaxial Silicon Nanowires as Solar Cells and Nanoelectronic Power Sources”, Nature Publishing Group 2007 [5] Klaus-Juergen Wolter, Gerald Gerlash, "Advanced Nano- and Biotechniques for Next-Gen Electronic Packaging", IEEE Nanotechnology Magazine 2010 [6] Valeriu Beiu, Jabulani Nyathi, Snorre Aunet, and Mawahib Sulieman, “Femto Joule Switching for Nano Electronics”, IEEE 2006 [7] Sohan Purohit, Ignacio Iñiguez-de-la-Torre, Vikas Kaushal and Martin Margala, “ High Performance Digital Circuit Design Using Ballistic Nano-Electronics”, IEEE 2010 [8] Henk W. Ch. Postma, Tijs Teepen, Zhen Yao, Milena Grifoni, Cees Dekker , “Carbon Nanotube Single-Electron Transistors at Room Temperature”, Science 2001 [9] Nicholas A. Melosh, Akram Boukai, Frederic Diana, Brian Gerardot, Antonio Badolato, Pierre M. Petroff, James R. Heath , “Ultrahigh-Density Nanowire Lattices and Circuits”, Science 2003 [10] Wen-Yan Yin, “Computational Multiphysics Method for RF and Nano Electronics: Challenges and Opportunities” [11] Shamik Das, Alexander J. Gates, Hassen A. Abdu, Garrett S. Rose, Carl A. Picconatto, and James C. Ellenbogen, “Designs for Ultra-Tiny, Special-Purpose Nanoelectronic Circuits”, IEEE Transactions on Circuit and Systems 2007 [12] Alberts, Bruce; Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, and Peter Walters, ”Molecular Biology of the Cell; Fourth Edition”, New York and London: Garland Science. ISBN 0-8153-3218-1 (2002) [13] موریس مانو، ترجمه قدرت سپیدنام، "طراحی دیجیتال"، انتشارات خراسان، مشهد 1347، ISBN:964-6342-Q-1 [14] Stojanovic, M. N., Mitchell, T. E., & Stefanovic, D. (2002). "Deoxyribozyme-based logic gates"; Journal of the American Chemical Society, 124(14), 3555-3561 [15] Stojanovic, M. N., & Stefanovic, D. (2003). "Deoxyribozyme-based half-adder"; Journal of the American Chemical Society, 125(22), 6673-6676 1 A01 علیرضا محمودی فرد، جواد شریفی علیرضا محمودی فرد، جواد شریفی C. علیرضا محمودی فرد، جواد شریفی 01 eng 202606 2026 C. zagros 06 10.22034/zagros.2020.1013.0742 https://rcsj.ir/user/articles/133 Farzanegan Pub mEDRA 01 01 133 zagros Publisher IR 01 133 JB 29 1 4 01 202606 7 10 01 [1] Whitmore, A., Agarwal, A., & Da Xu, L. (2015). The Internet of Things—A survey of topics and trends. Information Systems Frontiers, 17(2), 261-274. [2] Atzori, L., Iera, A., & Morabito, G. (2010). The internet of things: A survey. Computer networks, 54(15), 2787-2805. [3] Hussain, F. (2017). Internet of Things: Building Blocks and Business Models. [4] Van Tilborg, H. C., & Jajodia, S. (Eds.). (2014). Encyclopedia of cryptography and security. Springer Science & Business Media. [5] Ray, P. P. (2016). A survey on Internet of Things architectures. Journal of King Saud University-Computer and Information Sciences. [6] Stojkoska, B. L. R., & Trivodaliev, K. V. (2017). A review of Internet of Things for smart home: Challenges and solutions. Journal of Cleaner Production, 140, 1454-1464. [7] Bucherer, E., & Uckelmann, D. (2011). Business models for the internet of things. In Architecting the internet of things (pp. 253-277). Springer Berlin Heidelberg. [8] Alaba, F. A., Othman, M., Hashem, I. A. T., & Alotaibi, F. (2017). Internet of things Security: A Survey. Journal of Network and Computer Applications. [9] Borgia, E., Gomes, D. G., Lagesse, B., Lea, R. J., & Puccinelli, D. (2016). Special issue on “Internet of Things: Research challenges and Solutions”. Computer Communications, 89, 1-4. [10] Lee, I., & Lee, K. (2015). The Internet of Things (IoT): Applications, investments, and challenges for enterprises. Business Horizons, 58(4), 431-440. [11] Miorandi, D., Sicari, S., De Pellegrini, F., & Chlamtac, I. (2012). Internet of things: Vision, applications and research challenges. Ad Hoc Networks, 10(7), 1497-1516. [12] Di Pietro, R., Guarino, S., Verde, N. V., & Domingo-Ferrer, J. (2014). Security in wireless ad-hoc networks–a survey. Computer Communicatio-ns, 51, 1-20. [13] Roman, R., Zhou, J., & Lopez, J. (2013). On the features and challenges of security and privacy in distributed internet of things. Computer Networks, 57(10), 2266-2279. [14] Bi, Z., Da Xu, L., & Wang, C. (2014). Internet of things for enterprise systems of modern manufacturing. IEEE Transactions on industrial informatics, 10(2), 1537-1546. [15] Samaila, M. G., Neto, M., Fernandes, D. A., Freire, M. M., & Inácio, P. R. (2017). Security Challenges of the Internet of Things. In Beyond the Internet of Things (pp. 53-82). Springer International Publishing. [16] Ukil, A., Sen, J., & Koilakonda, S. (2011, March). Embedded security for Internet of Things. In Emerging Trends and Applications in Computer Science (NCETACS), 2011 2nd National Conference on (pp. 1-6). IEEE. [17] Raza, S. (2013). Lightweight security solutions for the internet of things (Doctoral dissertation, Mälardalen University, Västerås, Sweden). [18] Gamundani, A. M. (2015, May). An impact review on internet of things attacks. In Emerging Trends in Networks and Computer Communications (ETNCC), 2015 International Conference on (pp. 114-118). IEEE. [19] Abomhara, M., & Køien, G. M. (2014, May). Security and privacy in the Internet of Things: Current status and open issues. In Privacy and Security in Mobile Systems (PRISMS), 2014 International Conference on (pp. 1-8). IEEE. [20] Sicari, S., Rizzardi, A., Grieco, L. A., & Coen-Porisini, A. (2015). Security, privacy and trust in Internet of Things: The road ahead. Computer Networks, 76, 146-164. [21] Alqassem, I., & Svetinovic, D. (2014, December). A taxonomy of security and privacy requirements for the Internet of Things (IoT). In Industrial Engineering and Engineering Management (IEEM), 2014 IEEE International Conference on (pp. 1244-1248). IEEE. [22] Xu, T., Wendt, J. B., & Potkonjak, M. (2014, November). Security of IoT systems: Design challenges and opportunities. In Proceedings of the 2014 IEEE/ACM International Conference on Computer-Aided Design (pp. 417-423). IEEE Press. [23] Tamboli, J., Kaneria, R., Patoliya, D., & Ramani, S. (2014). Security in the Internet of Things. Communication, Cloud and Big Data: Proceedings of CCB 2014. [24] Jing, Q., Vasilakos, A. V., Wan, J., Lu, J., & Qiu, D. (2014). Security of the internet of things: Perspectives and challenges. Wireless Networks, 20(8), 2481-2501. [25] Kanuparthi, A., Karri, R., & Addepalli, S. (2013, November). Hardware and embedded security in the context of internet of things. In Proceedings of the 2013 ACM workshop on Security, privacy & dependability for cyber vehicles (pp. 61-64). ACM. [26] Massis, B. (2016). The Internet of Things and its impact on the library. New Library World, 117(3/4), 289-292. [27] Zhang, Y., Shen, Y., Wang, H., Yong, J., & Jiang, X. (2016). On secure wireless communications for IoT under eavesdropper collusion. IEEE Transactions on Automation Science and Engineering, 13(3), 1281-1293. [28] Ma, H. D. (2011). Internet of things: Objectives and scientific challenges. Journal of Computer science and Technology, 26(6), 919-924. [29] Perera, C., Zaslavsky, A., Christen, P., & Georgakopoulos, D. (2014). Context aware computing for the internet of things: A survey. IEEE Communications Surveys & Tutorials, 16(1), 414-454. [30] Bi, Z., Wang, G., & Xu, L. D. (2016). A visualization platform for internet of things in manufacturing applications. Internet Research, 26(2), 377-401. [31] Barreto, L., Celesti, A., Villari, M., Fazio, M., & Puliafito, A. (2015, August). An authentication model for IoT clouds. In Proceedings of the 2015 IEEE/ACM International Conference on Advances in Social Networks Analysis and Mining 2015 (pp. 1032-1035). ACM. [32] Aman, W., & Snekkenes, E. (2015, December). Managing security trade-offs in the internet of things using adaptive security. In Internet Technology and Secured Transactions (ICITST), 2015 10th International Conference for (pp. 362-368). IEEE. [33] Ndibanje, B., Lee, H. J., & Lee, S. G. (2014). Security analysis and improvements of authentication and access control in the internet of things. Sensors, 14(8), 14786-14805. [34] Li, S., Da Xu, L., & Zhao, S. (2015). The internet of things: a survey. Information Systems Frontiers, 17(2), 243-259. [35] Sundmaeker, H., Guillemin, P., Friess, P., & Woelfflé, S. (2010). Vision and challenges for realising the Internet of Things. Cluster of European Research Projects on the Internet of Things, European Commision, 3(3), 34-36. [36] Choi, J., Li, S., Wang, X., & Ha, J. (2012, June). A general distributed consensus algorithm for wireless sensor networks. In Wireless Advanced (WiAd), 2012 (pp. 16-21). IEEE. [37] Ning, H., Liu, H., & Yang, L. T. (2013). Cyberentity security in the internet of things. Computer, 46(4), 46-53. [38] Covington, M. J., & Carskadden, R. (2013, June). Threat implications of the internet of things. In Cyber Conflict (CyCon), 2013 5th International Conference on (pp. 1-12). IEEE. [39] Akhunzada, A., Gani, A., Anuar, N. B., Abdelaziz, A., Khan, M. K., Hayat, A., & Khan, S. U. (2016). Secure and dependable software defined networks. Journal of Network and Computer Applications, 61, 199-221. [40] Babar, S., Stango, A., Prasad, N., Sen, J., & Prasad, R. (2011, February). Proposed embedded security framework for internet of things (iot). In Wireless Communication, Vehicular Technology, Information Theory and Aerospace & Electronic Systems Technology (Wireless VITAE), 2011 2nd International Conference on (pp. 1-5). IEEE. [41] Gubbi, J., Buyya, R., Marusic, S., & Palaniswami, M. (2013). Internet of Things (IoT): A vision, architectural elements, and future directions. Future generation computer systems, 29(7), 1645-1660. [42] Yao, X., Chen, Z., & Tian, Y. (2015). A lightweight attribute-based encryption scheme for the Internet of Things. Future Generation Computer Systems, 49, 104-112. [43] Jiang, H., Shen, F., Chen, S., Li, K. C., & Jeong, Y. S. (2015). A secure and scalable storage system for aggregate data in IoT. Future Generation Computer Systems, 49, 133-141. [44] Moosavi, S. R., Gia, T. N., Rahmani, A. M., Nigussie, E., Virtanen, S., Isoaho, J., & Tenhunen, H. (2015). SEA: a secure and efficient authentication and authorization architecture for IoT-based healthcare using smart gateways. Procedia Computer Science, 52, 452-459. [45] Vučinić, M., Tourancheau, B., Rousseau, F., Duda, A., Damon, L., & Guizzetti, R. (2015). OSCAR: Object security architecture for the Internet of Things. Ad Hoc Networks, 32, 3-16. [46] Hashem, I. A. T., Chang, V., Anuar, N. B., Adewole, K., Yaqoob, I., Gani, A., ... & Chiroma, H. (2016). The role of big data in smart city. International Journal of Information Management, 36(5), 748-758. [47] Botta, A., De Donato, W., Persico, V., & Pescapé, A. (2016). Integration of cloud computing and internet of things: a survey. Future Generation Computer Systems, 56, 684-700. [48] Chakrabarty, S., Engels, D. W., & Thathapudi, S. (2015, October). Black SDN for the Internet of Things. In Mobile Ad Hoc and Sensor Systems (MASS), 2015 IEEE 12th International Conference on (pp. 190-198). IEEE. [49] Bagci, I. E., Raza, S., Chung, T., Roedig, U., & Voigt, T. (2013, June). Combined secure storage and communication for the internet of things. In 2013 IEEE International Conference on Sensing, Communications and Networking (SECON) (pp. 523-531). IEEE. [50] Jucker, S. (2012). Securing the Constrained Application Protocol. no. October, 1-103. [51] Hartke, K., & Bergmann, O. (2012). Datagram Transport Layer Security in Constrained Environments. draft-hartke-core-codtls-01 (work in progress). [52] Naccache, D., & Sauveron, D. (Eds.). (2014). Information Security Theory and Practice. Securing the Internet of Things: 8th IFIP WG 11.2 International Workshop, WISTP 2014, Heraklion, Crete, Greece, June 30-July 2, 2014, Proceedings (Vol. 8501). Springer. [53] Sicari, S., Rizzardi, A., Grieco, L. A., & Coen-Porisini, A. (2015). Security, privacy and trust in Internet of Things: The road ahead. Computer Networks, 76, 146-164. 1 A01 ساسان برهلیا، محمدباقر حق پرست، بردیا علاالديني، امیرحسین جورسرایی ساسان برهلیا، محمدباقر حق پرست، بردیا علاالديني، امیرحسین جورسرایی C. ساسان برهلیا، محمدباقر حق پرست، بردیا علاالديني، امیرحسین جورسرایی 01 eng 202606 2026 C. zagros 06 10.22034/zagros.2020.1013.0849 https://rcsj.ir/user/articles/134 Farzanegan Pub mEDRA 01 01 134 zagros Publisher IR 01 134 JB 29 1 4 01 202606 7 10 01 [1] Abdel-Basset M, Gunasekaran M, Mohamed M, Chilamkurti N. (2019). “A framework for risk assessment, management and evaluation: economic tool for quantifying risks in supply chain.” Future Gen Comput Syst. Vol. 90, PP. 489–502. [2] Ciccone MM, Scicchitano P, Zito A, Agati L, Gesualdo M, Mandolesi S, et al. (2011). “Correlation between coronary artery disease severity, left ventricular mass index and carotid intima media thickness, assessed by radio-frequency.” Cardiovasc Ultrasound. Vol. 9, PP. 32. [3] Faxon DP, Creager MA, Smith SC Jr, Pasternak RC, Olin JW, Bettmann MA, et al. (2004). “Atherosclerotic Vascular Disease Conference: Executive Summary: Atherosclerotic Vascular Disease Conference Proceeding for Healthcare Professionals From a Special Writing Group of the American Heart Association.” Circulation. Vol.109, PP. 2595-2604. [4] Golemati S, Sassano A, Lever MJ, Bharath AA, Dhanjil S, Nicolaides AN. (2003). “Carotid artery wall motion estimated from B-mode ultrasound using region tracking and block matching.” Ultrasound Med Biol. Vol. 29, PP. 387-99. [5] Okimoto H, Ishigaki Y, Koiwa Y. (2008). “A novel method for evaluating human carotid artery elasticity: possible detection of early stage atherosclerosis in subjects with type 2 diabetes.” Atherosclerosis. Vol. 196, PP. 391-7. [6] Lee, H.Y. and B.H. Oh. (2010). “Aging and arterial stiffness.” Circ J. Vol. 74, PP. 2257-62. [7] Vaitkevicius PV, Fleg JL, Engel JH, O'Connor FC, Wright JG, Lakatta LE, et al. (1993). “Effects of age and aerobic capacity on arterial stiffness in healthy adults.” Circulation. Vol. 88, PP. 1456-62. [8] Safar ME, Czernichow S, Blacher J. (2006). “Obesity, arterial stiffness, and cardiovascular risk.” J Am Soc Nephrol. Vol. 17, PP. 109-11. [9] Shenouda, N. (2013). “Arterial Stiffness During the Early Years: Relationship with Adiposity and Physical Activity, in Kinesiology.” McMaster University. [10] Avolio AP, Chen SG, Wang RP, Zhang CL, Li MF, O'Rourke MF. (1983). “Effects of aging on changing arterial compliance and left ventricular load in a northern Chinese urban community.” Circulation. Vol. 68, PP. 50-8. [11] McEniery CM, Yasmin, Hall IR, Qasem A, Wilkinson IB, Cockcroft JR. (2005). “ACCT Investigators. Normal Vascular Aging: Differential Effects on Wave Reflection and Aortic Pulse Wave VelocityThe Anglo-Cardiff Collaborative Trial (ACCT). ” Journal of the American College of Cardiology. Vol. 46, PP. 1753-1760. [12] Zebekakis PE, Nawrot T, Thijs L, Balkestein EJ, van der Heijden-Spek J, Van Bortel LM, et al. (2005). “Obesity is associated with increased arterial stiffness from adolescence until old age.” J Hypertens. Vol. 23, PP. 1839-46. [13] Bots ML, Hofman A, De Jong PT, Grobbee DE. (1996). “Common carotid intima-media thickness as an indicator of atherosclerosis at other sites of the carotid artery. The Rotterdam Study. ” Ann Epidemiol. Vol. 6, PP. 147-53. [14] Iwakiri T, Yano Y, Sato Y, Hatakeyama K, Marutsuka K, Fujimoto S, et al. (2012). “Usefulness of carotid intima-media thickness measurement as an indicator of generalized atherosclerosis: findings from autopsy analysis.” Atherosclerosis. Vol. 225, PP. 359-62. [15] Hoeks AP, Willekes C, Boutouyrie P, Brands PJ, Willigers JM, Reneman RS. (1997). “Automated detection of local artery wall thickness based on M-line signal processing.” Ultrasound Med Biol. Vol. 23, PP. 1017-23. [16] Shroff GR, Cen YY, Duprez DA, Bart BA. (2009). “Relationship between carotid artery stiffness index, BNP and high-sensitivity CRP.” J Hum Hypertens. Vol. 23, PP. 783-7. [17] Kondo K, Nemoto M, Harada N, Fukushima D, Masuda H, Sugo N. (2017). “Comparison between quantitative stiffness measurements and ultrasonographic findings of fresh carotid plaques.” Ultrasound Med Biol. Vol. 43, PP. 138–144. [18] Larsson M, Heyde B, Kremer F, Brodin LÅ, D'hooge J. (2015). “Ultrasound speckle tracking for radial, longitudinal and circumferential strain estimation of the carotid artery – an in vitro validation via sonomicrometry using clinical and high-frequency ultrasound. ” Ultrasonics. Vol. 56, PP. 399–408. [19] Khan AA, Sikdar S, Hatsukami T, Cebral J, Jones M, Huston J, et al. (2017). “Noninvasive characterization of carotid plaque strain.” J Vasc Surg. Vol. 65, PP. 1653–1663. [20] Czernuszewicz TJ, Homeister JW, Caughey MC, Farber MA, Fulton JJ, Ford PF, et al. (2015). “Non-invasive in vivo characterization of human carotid plaques with acoustic radiation force impulse ultrasound: comparison with histology after endarterectomy.” Ultrasound Med Biol. Vol. 41, PP. 685–697. [21] Yousefi Rizi F, Behnam H, Setarehdan SK, Alizadeh Sani Z. (2014). “Study of the effects of age and body mass index on the carotid wall vibration: Extraction methodology and analysis.” Journal of Engineering in Medicine. PP. 1-16. [22] Sharifi S, Behnam H, Alizadeh Sani Z. (2019). “A new technique for the measurement and assessment of carotid artery wall vibrations using ultrasound echoes.” Turk J Elec Eng & Comp Sci. Vol. 27, PP. 4340 – 4353. [23] Salehi, L, Behnam H. (2008). “Extracting the small vibrations of a vessel wall.” Physiol Meas. Vol. 29, PP. 1041-53. [24] Khamdaeng T, Luo J, Vappou J, Terdtoon P, Konofagou EE. (2012). “Arterial stiffness identification of the human carotid artery using the stress-strain relationship in vivo.” Ultrasonics. Vol. 52, PP. 402-11. [25] Rabben SI, Baerum S, Sørhus V, Torp H. (2002). “Ultrasound-based vessel wall tracking: an auto-correlation technique with echo center frequency estimation.” Ultrasound Med Biol. Vol. 28, PP. 507-17. 1 A01 سامرند شریفی، حمید بهنام، زهرا علیزاده ثانی سامرند شریفی، حمید بهنام، زهرا علیزاده ثانی C. سامرند شریفی، حمید بهنام، زهرا علیزاده ثانی 01 eng 202606 2026 C. zagros 06 10.22034/zagros.2020.1121.0612 https://rcsj.ir/user/articles/135 Farzanegan Pub mEDRA 01 01 135 zagros Publisher IR 01 135 JB 29 1 4 01 202606 7 10 01 [1] Deng, L., Li, D., Cai, Z., & Hong, L. (2019). Smart IOT information transmission and security optimization model based on chaotic neural computing. Neural Computing and Applications, 1-14. [2] Wang N, Gao X, Tao D, Yang H, Li X (2018) Facial feature point detection: a comprehensive survey. Neurocomputing275:50–65. [3] Ghorai G, Pal M (2018) A note on ‘‘Regular bipolar fuzzy graphs’’ Neural Computing and Applications 21 (1) (2012) 197–205. Neural Compute Apply 30(5):1569–1572. [4] Qiu Y, Bi Y, Li Y, Wang H (2018) High resolution remote sensing image denoising algorithm based on sparse representation and adaptive dictionary learning. In Computational vision and bio inspired computing. Springer, Cham, pp 892–901 [5] Wang N, Gao X, Li J (2018) Random sampling for fast face sketch synthesis. Pattern Recogn 76:215–227 [6] Dadras S, Momeni H.R(2009) A novel three-dimensional autonomous chaotic system generating two, three and four-scroll attractors. doi:10.1016/j.physleta.2009.07.088 [7] Faezeh Rezaee, Dr Masode Taleb Ziabari, Dr Ahmad Bagheri (2019), Encrypting information using the chaotic model in IOT,http/:csc2019.guilan.ac.ir [8] Niu Z, Hua G, Wang L, Gao X (2018) Knowledge-based topic model for unsupervised object discovery and localization. IEEE Trans Image Process 27(1):50–63 [9] Y. A. Liu, Q. Yu, S. G. Hu, G. C. Qiao, and Y. Liu(2019) A memristor-based transient chaotic neural network model and its application. https://doi.org/10.1063/1.5115540 [10] L.Salim, B.Stelios (2019) Cryptocurrency forecasting with deep learning chaotic neural networks. [11] https://doi.org/10.1016/j.chaos.2018.11.014 [12] C.Stergiou, K.E. Psannis, B-Gyu.Kim, B.Gupta (2016) Secure integration of IoT and Cloud Computing.http://dx.doi.org/10.1016/j.future.2016.11.031 1 A01 فائزه رضائی ملاسرائی، مسعود طالب ضیابری، احمد باقری فائزه رضائی ملاسرائی، مسعود طالب ضیابری، احمد باقری C. فائزه رضائی ملاسرائی، مسعود طالب ضیابری، احمد باقری 01 eng 202606 2026 C. zagros 06 10.22034/zagros.2020.1202.0712 https://rcsj.ir/user/articles/136 Farzanegan Pub mEDRA 01 01 136 zagros Publisher IR 01 136 JB 29 1 4 01 202606 7 10 01 [1] Falkenberg, B., Mprrison, M. (2015). “Why More is Different?.” Springer. [2] Foote, R. (2007) “Mathematics and Complex Systems.” Science. Vol. 318, No. 5849, PP. 410-412. [3] Thurner, S., Klimek, P., Hanel, R. (2018) “Introduction to the Theory of Complex Systems.” Oxford University Press. [4] Wolfram, S. (2002). “A New Kind of Science.” Wolframe Media. [5] Gallavotti, G., Reiter, W.L., Yngvason, J. (2007). “Boltzmann’s Legacy.” European Mathematical Society. [6] Tao, T. (2008). “Structure and Randomness.” American Mathematical Society. [7] Copeland, B. J., Posy, C. J., Shagrir, O. (2013). “Computability: Turing, Godel, Church and Beyond.” MIT Press. [8] Kari, J. J., Rozenberg, G., Back, T., Kok, J. N. (Eds.) (2012). “Handbook of Natural Computing.” Springer. [9] Brandt, F., Conitzer, V., Endriss, U., Lang, J., Procaccia, A. D. (2016). “Handbook of Computational Social Choice.” Cambridge University Press. [10] Birrell, E., Pass, R. (2011). “Approximately Strategy-Proof Voting.” Proceeding of the 22nd International Joint Conference on Artificial Intelligence. July. Barcelona. Spain. [11] Arora, S., Barak, B. (2009). “Computational Complexity: A Modern Approach.” Cambridge University Press. [12] Stays, j. (2012). “Boolean Function Complexity: Advances and Frontiers.” Springer. [13] Capcarrere, M. (2002). “Cellular Automata and Other Cellular Systems: Design & Evolution.” Phd Thesis. ETH. [14] Boccara, N. (2010). “Modeling Complex Systems.” 2nd Edition. Springer. [15] Land, M. et al, (1995). “No Perfect Two-State Cellular Automata for Density Classification Task Exists” Physical Review Letters. Vol. 74, PP. 5148-5150. [16] Mohri, M., Rostamizadeh, A., Talwalkar, A. (2018). “Foundations of Machine Learning.” Second edition. MIT Press. 1 A01 امیراحمد نیری امیراحمد نیری C. امیراحمد نیری 01 eng 202606 2026 C. zagros 06 10.22034/zagros.2020.1202.0754 https://rcsj.ir/user/articles/137 Farzanegan Pub mEDRA 01 01 137 zagros Publisher IR 01 137 JB 29 1 4 01 202606 7 10 01 [1] M. Ammar, G. Russello, and B. Crispo, "Internet of Things: A survey on the security of IOT frameworks," Journal of Information Security and Applications, vol. 38, pp. 8-27, 2018. [2] N. M. Radwan, "A Study: The Future of the Internet of Things and its Home Applications," International Journal of Computer Science and Information Security (IJCSIS), vol. 18, no. 1, 2020. [3] S. Chowdhury, R. Jain, M. Thimmaiah, R. Prajwal, and K. Rakesh, "IOT based home automation and security systems: A literature survey," International Journal of Advance Research, Ideas and Innovations in Technology, vol. 5, no. 2, 2019. [4] H. Hosseinian, H. Damghani, L. Damghani, G. Nezam, and H. Hosseinian, "Home appliances energy management based on the IOT system," International Journal of Nonlinear Analysis and Applications, vol. 10, no. 1, pp. 167-175, 2019. [5] S. P. Yadav, A. Kumbhare, and R. Parab, "Smart Home Application using Internet of Things," perception, vol. 6, no. 02, 2019. [6] Z. Zhao et al., "A novel framework of three-hierarchical offloading optimization for MEC in industrial IOT networks," IEEE Transactions on Industrial Informatics, vol. 16, no. 8, pp. 5424-5434, 2019. [7] A.-R. Sadeghi, C. Wachsmann, and M. Waidner, "Security and privacy challenges in industrial internet of things," in 2015 52nd ACM/EDAC/IEEE Design Automation Conference (DAC), 2015, pp. 1-6: IEEE. [8] T. Perković, S. Damjanović, P. Šolić, L. Patrono, and J. J. Rodrigues, "Meeting Challenges in IOT: Sensing, Energy Efficiency, and the Implementation," in Fourth International Congress on Information and Communication Technology, 2020, pp. 419-430: Springer. [9] K. D. Kumar, M. Sudhakara, and R. K. Poluru, "Towards the Integration of Blockchain and IOT for Security Challenges in IOT: A Review," in Transforming Businesses With Bitcoin Mining and Blockchain Applications: IGI Global, 2020, pp. 45-67. [10] S. Stankovski, G. Ostojić, L. Tarjan, M. Stanojević, and M. Babić, "CHALLENGES OF IOT PAYMENTS IN SMART SERVICES," Annals of DAAAM & Proceedings, vol. 30, 2019. [11] Z.-K. Zhang, M. C. Y. Cho, C.-W. Wang, C.-W. Hsu, C.-K. Chen, and S. Shieh, " IOT security: ongoing challenges and research opportunities," in 2014 IEEE 7th international conference on service-oriented computing and applications, 2014, pp. 230-234: IEEE. [12] K. Tabassum, A. Ibrahim, and S. A. El Rahman, "Security issues and challenges in IOT," in 2019 International Conference on Computer and Information Sciences (ICCIS), 2019, pp. 1-5: IEEE. [13] F. Hussain, R. Hussain, S. A. Hassan, and E. Hossain, "Machine learning in IOT security: current solutions and future challenges," IEEE Communications Surveys & Tutorials, 2020. [14] M. A. Khan and K. Salah, " IOT security: Review, blockchain solutions, and open challenges," Future Generation Computer Systems, vol. 82, pp. 395-411, 2018. [15] S. Zeadally and M. Tsikerdekis, "Securing Internet of Things (IOT) with machine learning," International Journal of Communication Systems, vol. 33, no. 1, p. e4169, 2020. [16] F. Mclay, "Privacy law: How to save face: Data and privacy safeguards," Governance Directions, vol. 70, no. 4, p. 202, 2018. [17] M. T. Gardner, C. Beard, and D. Medhi, "Using SEIRS epidemic models for IOT botnets attacks," in DRCN 2017-Design of Reliable Communication Networks; 13th International Conference, 2017, pp. 1-8: VDE. [18] L. Munoz Gonzalez and E. Lupu, "The secret of machine learning," 2018. [19] L. E. Kane, J. J. Chen, R. Thomas, V. Liu, and M. Mckague, "Security and Performance in IOT: A Balancing Act," IEEE Access, vol. 8, pp. 121969-121986, 2020. [20] P. Williams, P. Rojas, and M. Bayoumi, "Security Taxonomy in IOT–A Survey," in 2019 IEEE 62nd International Midwest Symposium on Circuits and Systems (MWSCAS), 2019, pp. 560-565: IEEE. [21] Y. Yang, X. Zheng, W. Guo, X. Liu, and V. Chang, "Privacy-preserving smart IOT-based healthcare big data storage and self-adaptive access control system," Information Sciences, vol. 479, pp. 567-592, 2019. [22] N. Nesa, T. Ghosh, and I. Banerjee, "Non-parametric sequence-based learning approach for outlier detection in IOT," Future Generation Computer Systems, vol. 82, pp. 412-421, 2018. [23] F. Li, J. Hong, and A. A. Omala, "Efficient certificateless access control for industrial internet of things," Future Generation Computer Systems, vol. 76, pp. 285-292, 2017. [24] B. Chatterjee, D. Das, S. Maity, and S. Sen, "RF-PUF: Enhancing IOT security through authentication of wireless nodes using in-situ machine learning," IEEE Internet of Things Journal, vol. 6, no. 1, pp. 388-398, 2018. [25] H. Liu and B. Lang, "Machine learning and deep learning methods for intrusion detection systems: A survey," Applied Sciences, vol. 9, no. 20, p. 4396, 2019. [26] R. Doshi, N. Apthorpe, and N. Feamster, "Machine learning ddos detection for consumer internet of things devices," in 2018 IEEE Security and Privacy Workshops (SPW), 2018, pp. 29-35: IEEE. [27] J. Canedo and A. Skjellum, "Using machine learning to secure IOT systems," in 2016 14th annual conference on privacy, security and trust (PST), 2016, pp. 219-222: IEEE. [28] P. C. M. Arachchige, P. Bertok, I. Khalil, D. Liu, S. Camtepe, and M. Atiquzzaman, "A trustworthy privacy preserving framework for machine learning in industrial IOT systems," IEEE Transactions on Industrial Informatics, vol. 16, no. 9, pp. 6092-6102, 2020. 1 A01 منا نجفی سرپیری، محمدرضا سلطان آقایی منا نجفی سرپیری، محمدرضا سلطان آقایی C. منا نجفی سرپیری، محمدرضا سلطان آقایی 01 eng 202606 2026 C. zagros