Volume-9 , Issue-1 , Feb 2021, ISSN 2321-3256 (Electronic Version) Go Back

• Open Access   Article

  Provide a Dynamic Routing Algorithm for MPLS Networks Using Fuzzy Filtering Approach

  M. Alizadeh Genaveh, M. Mojarad, H. Arfaeinia

  Research Paper | Journal (IJSRNSC)

  Vol.9 , Issue.1 , pp.1-7, Feb-2021

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  Abstract
  The advent of Multiprotocol Label Switching (MPLS) technology is the basis of the next generation network to improve multimedia applications. One of the most basic traffic engineering concepts in MPLS is routing for Layered Service Provider (LSP). The purpose of providing routing algorithms is to maximize the number of routed requests according to QoS satisfaction. Most research in this area focuses solely on bandwidth, and relatively few studies consider both bandwidth limits and delay. In this paper, a dynamic routing algorithm based on a fuzzy filtering method is proposed which considers both bandwidth limits and end to end delay for route search. The fuzzy system is a prediction model based on fuzzy weighting rules for filtering high-resource requests. The proposed method tries to postpone requests with high bandwidth and maximum end to end delay. Various scenarios have been used to simulate and evaluate the efficiency of the proposed method, and criteria such as the number of requests accepted, average path length and load balance have been measured. The simulation results prove that the proposed method provides optimal routing performance for MPLS networks.

  Key-Words / Index Term
  Routing algorithm, MLPS networks, Quality of service, Fuzzy filtering

  References
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  Citation
  M. Alizadeh Genaveh, M. Mojarad, H. Arfaeinia, "Provide a Dynamic Routing Algorithm for MPLS Networks Using Fuzzy Filtering Approach," International Journal of Scientific Research in Network Security and Communication, Vol.9, Issue.1, pp.1-7, 2021

• Open Access   Article

  Multi-Level and Mutual Log Integrity Preservation Approach for Cloud Forensics using Public Key Infrastructure

  Siva Rama Krishna Tummalapalli, A.S.N. Chakravarthy

  Research Paper | Journal (IJSRNSC)

  Vol.9 , Issue.1 , pp.8-16, Feb-2021

  Abstract

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  Abstract
  The increasing growth of cloud computing makes the forensic investigation complex. It is very significant to collect and preserve the admissible evidences of different actions happened in the cloud environment in spite of collusion problem. The forensic investigation of logs poses a great challenge to make sure that the investigated logs are not tampered and consistent. Various integrity preservation methods are developed to secure the trustworthy evidences of cloud, but storing the logs of user actions and to ensure the trustworthiness with respect to forensic investigation still result a challenging issue in cloud. Hence, an effective multi-level and mutual log integrity preservation method is developed to assure the integrity of log evidence using public key infrastructure. The integrity preservation mechanism is modelled by employing the security mechanisms, such as hashing, encryption, decryption, and walsh transform. The communication between the entities is achieved by generating the keys using the hashing and encryption function with the concatenation operator. However, the public key and the random number is used to generate the message that can be exchanged between the cloud entities. The investigation process is done by the investigator for transferring the encrypted log file to the server. The proposed method achieved higher performance by considering the 500 number of cloud users in terms of detection rate, memory, and time with the values of 0.9828, 2185 bytes, and 7287 ms, respectively.

  Key-Words / Index Term
  Cloud Security, Cloud Forensics, Evidence Integrity, Log Analysis, Public Key

  References
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  Citation
  Siva Rama Krishna Tummalapalli, A.S.N. Chakravarthy, "Multi-Level and Mutual Log Integrity Preservation Approach for Cloud Forensics using Public Key Infrastructure," International Journal of Scientific Research in Network Security and Communication, Vol.9, Issue.1, pp.8-16, 2021

• Open Access   Article

  A Secure Light Weight Authentication Protocol for Wireless Sensor Network in Internet of Things

  M.M. Nareshbabu, A.S.N. Chakravarthy, C. Ravindranath

  Research Paper | Journal (IJSRNSC)

  Vol.9 , Issue.1 , pp.17-19, Feb-2021

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  Abstract
  With the advancement of cloud and Internet of Things (IoT) technology, mobile phones, RFID systems and wireless sensor networks can be integrated to form heterogeneous systems to execute smarter applications. However, data exchange between remote cloud and sensor node via internet poses critical security challenges. The major challenge is the authentication and key exchange among the communication agents. In addition, resource constrained devices such as RFID tags, sensors in WSN and IoT integration (WSNIT) would require robust and light weight authentication schemes. To combat these issues, we establish in this paper a first of its kind of a WSN security protocol in IoT, which is light weight and resistant to cryptographic attacks.

  Key-Words / Index Term
  Internet of Things, Cloud Authentication, Wireless Sensor Networks

  References
  [1] Daniel G., Sergio L., Federico B., Nik B., Eleana A.,“The Role of Ad Hoc Networks in the Internet of Things: A Case Scenario for Smart Environments”. Springer book: Internet of Things and Inter-cooperative Computational Technologiesfor Collective Intelligence , Vol 460, 2013
  [2] Andrew W., Anurag A., Li X.,. 2014, “The Internet of Things—A survey of topics and trends” Springer journal of Information Systems Frontiers. Mar 2014.
  [3] John L., Hua Z., Zhihong L., Xiangcheng W., Yuhong C., “The Wireless Sensor Network Security Protocol Research in Internet of Things”. Advances in Intelligent and Soft Computing Vol 149, pp 241-247, 2012.

  Citation
  M.M. Nareshbabu, A.S.N. Chakravarthy, C. Ravindranath, "A Secure Light Weight Authentication Protocol for Wireless Sensor Network in Internet of Things," International Journal of Scientific Research in Network Security and Communication, Vol.9, Issue.1, pp.17-19, 2021