Migrating Packet Dropping in Mobile Ad-hoc Network Based on Modified ACK-Based Scheme

Dynamic topology and infrastructure less behavior provide a great facility for adhoc network. Such facility generates easy connection of adhoc network and provides node mobility without loss of connection. In such ability packet dropping is a serious challenge for quality performance of adhoc network. The adhoc network suffered some serious security threats such attacks are black hole attack, malicious attack and worm hole attack that attack occurred a packet dropping problem in adhoc network. For the minimization of attack and packet dropping various authors built various method such method is node authentication, passive feedback scheme, ack-based scheme, reputation based scheme and incentive based scheme, ack-based scheme suffered a problem of massive overhead due to extra acknowledgment  packet and it also suffered decision ambiguity if the requested node refuse to send back Acknowledgment. In this dissertation we uses modified ack-based scheme using secure channel for overcoming the problem of decision ambiguity for requested node, improved node authentication and minimize packet dropping in adhoc network. Keywords mobile ad-hoc network, routing misbehaviour, AODV routing protocol, ACK based approach, network security

“Reducing Packet Loss in MANET”

Dynamic topology and infrastructure less behaviour provide a great facility for adhoc network. Such facility generates easy connection of adhoc network and provides node mobility without loss of connection. In such ability packet dropping is a serious challenge for quality performance of adhoc network. The adhoc network suffered some serious security therats such attacks are black hole attack, malicious attack and worm hole attack that attack occurred a packet dropping problem in adhoc network. For the minimization of attack and packet dropping various authors built various method such method is node authentication, passive feedback scheme, ack-based scheme,reputation based scheme and incentive based scheme, ack-based scheme suffered a problem of massive overhead due to extra acknowledgment  packet and it also suffered decision ambiguity if the requested node refuse to send back Acknowledgment. In this dissertation we uses modified ack-based scheme using secure channel for overcoming the problem of decision ambiguity for requested node, improved node authentication and minimize packet dropping in adhoc network. Keywords- mobile ad-hoc network, routing misbehaviour, AODV routing protocol, ACK based approach, network security

Different Security Mechanisms for Wireless Sensor Networks

In today’s world security becomes one of the important constraints in every research field. As increasing use of Wireless Sensor Networks (WSN) in various crucial applications security of wireless networks is becoming more important day by day. Today almost each and every important area makes use of wireless sensor networks. As Wireless Sensor Network is infrastructure-less network; data moves openly from one node to another thus it can be captured easily by attackers. To avoid data from being stolen security mechanism has to be applied. Many protocols are available for providing security on wireless network. We perform a detailed study of different security mechanisms used in sensor network against some criteria such as nature of algorithm, working, its benefits and some of the disadvantages of mechanism and also compare them

QoS Routing Protocols and Privacy in Wireless Sensor Networks

Full network level privacy has often been categorized into four sub-categories: Identity, Route, Location and Data privacy. Achieving full network level privacy is a challenging problem due to the conditions imposed by the sensor nodes (e.g., energy, memory and computation power), sensor networks (e.g., mobility and topology) and QoS issues (e.g., packet reach-ability and timeliness). This proposed paper consists of two algorithms IRL algorithm and data privacy mechanism that addresses this problem. The proposed system provides additional trustworthiness, less computation power, less storage space and more reliability. Also, we proved that our proposed solutions provide protection against various privacy disclosure attacks, such as eavesdropping and hop-by-hop trace back attacks

Public key cryptography in resource-constrained WSN

In this paper we present a detailed review of the works on public key cryptography (PKC) in wireless sensor networks (WSNs). In the early days of sensor networks, public key cryptography was thought to be completely unfeasible considering its computational complexity and energy requirements. By this time, several works have proved that the lightweight versions of many well-known public key algorithms can be utilized in WSN environment. With the expense of a little energy, public key based schemes could in fact be the best choice for ensuring data security in high-security demanding WSN applications. Here, we talk about the notion of public key cryptography in WSN, its applicability, challenges in its implementation, and present a detailed study of the significant works on PKC in WSN

The PASSERINE Public Key Encryption and Authentication Mechanism

PASSERINE is a lightweight public key encryption mechanism which is based on a hybrid, randomized variant of the Rabin public key encryption scheme. Its design is targeted for extremely low-resource applications such as wireless sensor networks, RFID tags, embedded systems, and smart cards. As is the case with the Rabin scheme, the security of PASSERINE can be shown to be equivalent to factoring the public modulus. On many low-resource implementation platforms PASSERINE offers smaller transmission latency, hardware and software footprint and better encryption speed when compared to RSA or Elliptic Curve Cryptography. This is mainly due to the fact that PASSERINE implementations can avoid expensive big integer arithmetic in favor of a fully parallelizable CRT randomized-square operation. In order to reduce latency and memory requirements, PASSERINE uses Naccache-Shamir randomized multiplication, which is implemented with a system of simultaneous congruences modulo small coprime numbers. The PASSERINE private key operation is of comparable computational complexity to the RSA private key operation. The private key operation is typically performed by a computationally superior recipient such as a base station

A Survey of Access Control Models in Wireless Sensor Networks

Copyright 2014 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/)Wireless sensor networks (WSNs) have attracted considerable interest in the research community, because of their wide range of applications. However, due to the distributed nature of WSNs and their deployment in remote areas, these networks are vulnerable to numerous security threats that can adversely affect their proper functioning. Resource constraints in sensor nodes mean that security mechanisms with a large overhead of computation and communication are impractical to use in WSNs; security in sensor networks is, therefore, a challenge. Access control is a critical security service that offers the appropriate access privileges to legitimate users and prevents illegitimate users from unauthorized access. However, access control has not received much attention in the context of WSNs. This paper provides an overview of security threats and attacks, outlines the security requirements and presents a state-of-the-art survey on access control models, including a comparison and evaluation based on their characteristics in WSNs. Potential challenging issues for access control schemes in WSNs are also discussed.Peer reviewe

An asymmetric key-based security architecture for wireless sensor networks

In spite of previous common assumptions about the incompatibility of public key cryptography (PKC) schemes with wireless sensor networks (WSNs), recent works have shown that they can be utilized for such networks in some manner. The major challenge of employing a PKC-based scheme in a wireless sensor network is posed by the resource limitations of the tiny sensors. Considering this sensor feature, in this paper we propose an efficient PKC-based security architecture with relatively lower resource requirements than those of previously proposed PKC schemes for WSN. In addition, our scheme aims to provide robust security in the network. Our security architecture comprises two basic components; a key handshaking scheme based on simple, linear operations and the derivation of a decryption key by a receiver node. Our architecture enables node-to-base-station and node-to-node secure communications. Analysis and simulation results show that our proposed architecture ensures a good level of security for network communications, and can be effectively implemented with the limited computational, memory, and energy budgets of current-generation sensor nodes

Security In Wireless Sensor Networks Based On Lightweight Algorithms : An Effective Survey

At the level of both individuals and companies, Wireless Sensor Networks (WSNs) get a wide range of applications and uses. Sensors are used in a wide range of industries, including agriculture, transportation, health, and many more. Many technologies, such as wireless communication protocols, the Internet of Things, cloud computing, mobile computing, and other emerging technologies, are connected to the usage of sensors. In many circumstances, this contact necessitates the transmission of crucial data, necessitating the need to protect that data from potential threats. However, as the WSN components often have constrained computation and power capabilities, protecting the communication in WSNs comes at a significant performance penalty. Due to the massive calculations required by conventional public-key and secret encryption methods, information security in this limited context calls for light encryption techniques. In many applications involving sensor networks, security is a crucial concern. On the basis of traditional cryptography, a number of security procedures are created for wireless sensor networks. Some symmetric-key encryption techniques used in sensor network setups include AES, RC5, SkipJack, and XXTEA. These algorithms do, however, have several flaws of their own, including being susceptible to chosen-plaintext assault, brute force attack, and computational complexity

GossiCrypt: Wireless Sensor Network Data Confidentiality Against Parasitic Adversaries

Resource and cost constraints remain a challenge for wireless sensor network security. In this paper, we propose a new approach to protect confidentiality against a parasitic adversary, which seeks to exploit sensor networks by obtaining measurements in an unauthorized way. Our low-complexity solution, GossiCrypt, leverages on the large scale of sensor networks to protect confidentiality efficiently and effectively. GossiCrypt protects data by symmetric key encryption at their source nodes and re-encryption at a randomly chosen subset of nodes en route to the sink. Furthermore, it employs key refreshing to mitigate the physical compromise of cryptographic keys. We validate GossiCrypt analytically and with simulations, showing it protects data confidentiality with probability almost one. Moreover, compared with a system that uses public-key data encryption, the energy consumption of GossiCrypt is one to three orders of magnitude lower