Biblio

Ad Hoc Network is wireless networks that get more attention from past to present. Mobile ad hoc network (MANET) is one of the types of ad hoc networks, it deployed rapidly because it infrastructure-less. A node in a mobile ad hoc network communicates through wireless links without wired channels. When source nodes want to communicate with the destination outside its transmission range it uses multi-hop mechanisms. The intermediate node forwards the data packet to the next node until the data packet reaches its destination. Due wireless links and lack of centralized administration device, mobile ad hoc network is more vulnerable for security attacks. The rushing attack is one of the most dangerous attacks in the on-demand routing protocol of mobile ad hoc networks. Rushing attack highly transmits route request with higher transmission power than the genuine nodes and become participate between source and destination nodes, after that, it delays or drop actual data pass through it. In this study, the researcher incorporates rushing attack in one of the most commonly used mobile ad hoc network routing protocols namely Ad hoc on-demand multipath distance vector and provides a rushing attack prevention method based on the time threshold value and random route selection. Based on the time RREQ arrives a node takes a decision, if the RREQ packet arrives before threshold value, the RREQ packet consider as came from an attacker and discarded else RREQ packet received then randomly select RREQ to forward. In this study performance metrics like packet delivery ratio, end-to-end delay and throughput have been evaluated using Network simulation (NS-2.35). As a result of simulation shows newly proposed prevention mechanism improves network performance in all cases than the network under attacker. For example, the average packet delivery ratio enhanced from 54.37% to 97.69%, throughput increased from 20.84bps to 33.06bpsand the average delay decreased from 1147.22ms to 908.04ms. It is concluded that the new proposed techniques show improvement in all evaluated performance metrics.

Mobile Ad hoc Networks ‘MANETs’ are still defenseless against peripheral threats due to the fact that this network has vulnerable access and also the absence of significant fact of administration. The black hole attack is a kind of some routing attack, in this type of attack the attacker node answers to the Route Requests (RREQs) thru faking and playing itself as an adjacent node of the destination node in order to get through the data packets transported from the source node. To counter this situation, we propose to deploy some nodes (exhibiting some distinctive functionality) in the network called DPS (Detection and Prevention System) nodes that uninterruptedly monitor the RREQs advertised by all other nodes in the networks. DPS nodes target to satisfy the set objectives in which it has to sense the mischievous nodes by detecting the activities of their immediate neighbor. In the case, when a node demonstrates some peculiar manners, which estimates according to the experimental data, DPS node states that particular distrustful node as black hole node by propagation of a threat message to all the remaining nodes in the network. A protocol with a clustering approach in AODV routing protocol is used to sense and avert the black hole attack in the mentioned network. Consequently, empirical evaluation shows that the black hole node is secluded and prohibited from the whole system and is not allowed any data transfer from any node thereafter.

One of the most dynamic network is the Mobile Adhoc (MANET) network. It is a list of numerous mobile nodes. Dynamic topology and lack of centralization are the basic characteristics of MANET. MANETs are prone to many attacks due to these characteristics. One of the attacks carried out on the network layer is the blackhole attack. In a black-hole attack, by sending false routing information, malicious nodes interrupt data transmission. There are two kinds of attacks involving a black-hole, single and co-operative. There is one malicious node in a single black-hole attack that can act as the node with the highest sequence number. The node source would follow the direction of the malicious node by taking the right direction. There is more than one malicious node in the collaborative black-hole attack. One node receives a packet and sends it to another malicious node in this attack. It is very difficult to detect and avoid black-hole attacks. Many researchers have invented black-hole attack detection and prevention systems. In this paper, We find a problem in the existing solution, in which validity bit is used. This paper also provides a comparative study of many scholars. The source node is used to detect and prevent black hole attacks by using a binary partition clustering based algorithm. We compared the performance of the proposed solution with existing solution and shown that our solution outperforms the existing one.

Mobile Ad Hoc Network is a infrastructure less wireless network where the mobile nodes leaves and joins the mobile network very frequently. The routing of the packets from source node to destination node, the routing protocol is used. On Demand Distance Vector Routing protocol is very common and implemented with Mobile Ad Hoc Network nodes to handle the operations of packet routing from by any node as a source node to destination node. In this paper prevention of black hole attack by modifying the On Demand Distance Vector routing protocol. The sequence number of 32 bit is initiated with the Route Reply and route sequence packet broadcast to determine the request reply from black hole node under the Mobile Ad Hoc Network. The sequence number and On demand Distance Vector Routing protocol are integrated with a mechanism to find the Request Reply of message containing routing information from source to destination node in Mobile Ad Hoc Network.

VANET plays a vital role to optimize the journey between source and destination in the growth of smart cities worldwide. The crucial information shared between vehicles is concerned primarily with safety. VANET is a MANET sub-class network that provides a free movement and communication between the RSU and vehicles. The self organized with high mobility in VANET makes any vehicle can transmit malicious messages to some other vehicle in the network. In the defense horizon of VANETs this is a matter of concern. It is the duty of RSU to ensure the safe transmission of sensitive information across the Network to each node. For this, network access exists as the key safety prerequisite, and several risks or attacks can be experienced. The VANETs is vulnerable to a range of security attacks including masquerading, selfish node attack, Sybil attack etc. One of the main threats to network access is this Denial of Service attack. The most important research in the literature on the prevention of Denial of Service Attack in VANETs was explored in this paper. The limitations of each reviewed paper are also presented and Game theory based security model is defined in this paper.

Mobile Adhoc networks (MANETs) comprises of mobile devices or nodes that are connected wirelessly and have no infrastructure. Detecting malicious activities in MANETs is a challenging task as they are vulnerable to attacks where the performance of the entire network degrades. Hence it is necessary to provide security to the network so that the nodes are prone to attack. Selecting a good routing protocol in MANET is also important as frequent change of topology causes the route reply to not arrive at the source node. In this paper, R-AODV (Reverse Adhoc On-Demand Distance Vector) protocol along with ECC (Elliptic Key Cryptography) algorithm is designed and implemented to detect and to prevent the malicious node and to secure data transmission against blackhole attack. The main objective is to keep the data packets secure. ECC provides a smaller key size compared to other public-key encryption and eliminates the requirement of pre-distributed keys also makes the path more secure against blackhole attacks in a MANET. The performance of this proposed system is simulated by using the NS-2.35 network simulator. Simulation results show that the proposed protocol provides good experimental results on various metrics like throughput, end-to-end delay, and PDR. Analysis of the results points to an improvement in the overall network performance.

This paper presents Forensic methods for detection and prevention of multiple attacks along with neural networks like Denial-of-Service (DoS), probe, vampire, and User-to-Root (U2R) attacks, in a Mobile Ad hoc Network (MANET). We accomplish attacker(s) detection and prevention percentage upto 99% in varied node density scenarios 50/100/150.

Blackhole (BH) attacks are one of the most serious threats in mobile ad-hoc networks. A BH is a security attack in which a malicious node absorbs data packets and sends fake routing information to neighboring nodes. BH attacks are widely studied. However, existing defense methods wrongfully assume that BH attacks cannot overcome the most common defense approaches. A new wave of BH attacks is known as smart BH attacks. In this study, we used a highly aggressive type of BH attack that can predict sequence numbers to overcome traditional detection methods that set a threshold to sequence numbers. To protect the network from this type of BH attack, we propose a detection-and-prevention method that uses local information shared with neighboring nodes. Our experiments show that the proposed method successfully detects and contains even smart BH threats. Consequently, the attack success rate decreases.

The dynamic and adaptable characteristics of mobile ad hoc networks have made it a significant field for deploying various applications in wireless sensor networks. Increasing popularity of the portable devices is the main reason for the development of mobile ad hoc networks. Furthermore, the network does not require a fixed architecture and it is easy to deploy. This type of network is highly vulnerable to cyber-attacks as the nodes communicate with each other through a Wireless medium. The most critical attack in ad hoc network is jellyfish attack. In this research we have proposed a Direct Trust-based Detection Algorithm to detect and prevent jellyfish attack in MANET.

MANETs are wireless networks, providing properties such as self-configuration, mobility, and flexibility to the network, which make them a popular and widely used technique. As the usage and popularity of the networks increases, security becomes the most important factor to be concerned. For the sake of security, several protocols and methodologies have been developed for the networks. Along with the increase in security mechanisms, the number of attacks and attackers also increases and hence the threat to the network and secure communication within it increases as well. Some of the attacks have been resolved by the proposed methodologies but some are still a severe threat to the framework, one such attack is Black Hole Attack. The proposed work integrates the SUPERMAN (Security Using Pre-Existing Routing for Mobile Ad-hoc Networks) framework with appropriate methodology to detect and prevent the network from the Black Hole Attack. The mechanism is based on the AODV (Ad-hoc On-demand Distance Vector) routing protocol. In the methodology, the source node uses two network routes, from the source to the destination, one for sending the data packet and another for observing the intermediate nodes of the initial route. If any node is found to be a Black Hole node, then the route is dropped and the node is added to the Black Hole list and a new route to send the data packet to the destination is discovered.

Mobile Ad hoc Network (MANET) is one of the emerging technologies to communicate between nodes and its decentralized structure, self-configuring nature are the few properties of this Ad hoc network. Due to its undefined structure, it has found its usage in the desired and temporary communication network. MANET has many routing protocols governing it and due to its changing topology, there can be many issues arise in recent times. Problems like no central node, limited energy, and the quality of service, performance, design issues, and security challenges have been bugging the researchers. The black hole attacks are the kind that cause ad hoc network to be at loss of information and make the source to believe that it has the actual least distance path to the destination, but in real scenario the packets do not get forwarded to neighbouring nodes. In this paper, we have discussed different solutions over the past years to deal with such attacks. A summary of the schemes with their results and drawbacks in terms of performance metrics is also given.

Today, intrusion detection and prevention systems (IDS / IPS) are a necessary element of protection against network attacks. The main goal of such systems is to identify an unauthorized access to the network and take appropriate countermeasures: alarming security officers about intrusion, reconfiguration of firewall to block further acts of the attacker, protection against cyberattacks and malware. For traditional computer networks there are a large number of sufficiently effective approaches for protection against malicious activity, however, for the rapidly developing dynamic adhoc networks (Internet of Things - IoT, MANET, WSN, etc.) the task of creating a universal protection means is quite acute. In this paper, we review various methods for detecting polymorphic intrusion activity (polymorphic viral code and sequences of operations), present a comparative analysis, and implement the suggested technology for detecting polymorphic chains of operations using bioinformatics for IoT. The proposed approach has been tested with different lengths of operation sequences and different k-measures, as a result of which the optimal parameters of the proposed method have been determined.

The paper emphasizes the various aspects of ad-hoc networks. The different types of attacks that affect the system and are prevented by various algorithms mentioned in this paper. Since Ad-hoc wireless networks have no infrastructure and are always unreliable therefore they are subject to many attacks. The black hole attack is seen as one of the dangerous attacks of them. In this attack the malicious node usually absorbs each data packets that are similar to separate holes in everything. Likewise all packets in the network are dropped. For this reason various prevention measures should be employed in the form of routing finding first then the optimization followed by the classification.

Vehicular Adhoc Network (VANET), a specialized form of MANET in which safety is the major concern as critical information related to driver's safety and assistance need to be disseminated between the vehicle nodes. The security of the nodes can be increased, if the network availability is increased. The availability of the network is decreased, if there is Denial of Service Attacks (DoS) in the network. In this paper, a packet detection algorithm for the prevention of DoS attacks is proposed. This algorithm will be able to detect the multiple malicious nodes in the network which are sending irrelevant packets to jam the network and that will eventually stop the network to send the safety messages. The proposed algorithm was simulated in NS-2 and the quantitative values of packet delivery ratio, packet loss ratio, network throughput proves that the proposed algorithm enhance the security of the network by detecting the DoS attack well in time.

Mobile ad hoc networks (MANETs) are self-configuring, dynamic networks in which nodes are free to move. These nodes are susceptible to various malicious attacks. In this paper, we propose a distributed trust-based security scheme to prevent multiple attacks such as Probe, Denial-of-Service (DoS), Vampire, User-to-Root (U2R) occurring simultaneously. We report above 95% accuracy in data transmission and reception by applying the proposed scheme. The simulation has been carried out using network simulator ns-2 in a AODV routing protocol environment. To the best of the authors' knowledge, this is the first work reporting a distributed trust-based prevention scheme for preventing multiple attacks. We also check the scalability of the technique using variable node densities in the network.

Vehicular ad-hoc networks (VANETs) are designed to play a key role in the development of future transportation systems. Although cooperative awareness messages provide the required situational awareness for new safety and efficiency applications, they also introduce a new attack vector to compromise privacy. The use of ephemeral credentials called pseudonyms for privacy protection was proposed while ensuring the required security properties. In order to prevent an attacker from linking old to new pseudonyms, mix-zones provide a region in which vehicles can covertly change their signing material. In this poster, we extend the idea of mix-zones to mitigate pseudonym linking attacks with a mechanism inspired by chaff-based privacy defense techniques for mix-networks. By providing chaff trajectories, our system restores the efficacy of mix-zones to compensate for a lack of vehicles available to participate in the mixing procedure. Our simulation results of a realistic traffic scenario show that a significant improvement is possible.

In this research paper, we describe an algorithm that could be implemented on an intrusion response system (IRS) designed specifically for mobile ad hoc networks (MANET). Designed to supplement a MANET's hierarchical intrusion detection system (IDS), this IRS and its associated algorithm would be implemented on the root node operating in such an IRS, and would rely on the optimized link state routing protocol (OLSR) to determine facts about the topology of the network, and use that determination to facilitate responding to network intrusions and attacks. The algorithm operates in a query-response mode, where the IRS function of the IDS root node queries the implemented algorithm, and the algorithm returns its response, formatted as an unordered list of nodes satisfying the query.

A mobile ad hoc network (MANET) is an infrastructure-less network of various mobile devices and generally known for its self configuring behavior. MANET can communicate over relatively bandwidth constrained wireless links. Due to limited bandwidth battery power and dynamic network, topology routing in MANET is a challenging issue. Collaborative attacks are particularly serious issues in MANET. Attacks are liable to occur if routing algorithms fail to detect prone threats and to find as well as remove malicious nodes. Our objective is to examine and improve the performance of network diminished by variety of attacks. The performance of MANET network is examined under Black hole, Wormhole and Sybil attacks using Performance matrices and then major issues which are related to these attacks are addressed.

Mobile ad hoc networking (MANET) has been most popular research area for last decade. In MANET node (mobile node) is communicate with each other over wireless link where all nodes behave like both as host and router. In comparison with wired networks, mobile network is more vulnerable to security threat because of no centralized administration. One of the momentous routing protocols used in MANET is AODV (Ad hoc On demand Distance Vector) protocol. The Ad hoc On demand Distance Vector (AODV) protocol is compromised with its security by a various types of attacks due to malicious nodes present in the network. A hybrid approach is given for intrusion detection by removing malicious nodes during the route discovery process. The proposed approach increases the network performance in terms of PDR, throughput and end to end delay and security also.

MANET (Mobile ad-hoc network) is a wireless network. Several mobile nodes are present in MANET. It has various applications ranging from military to remote area communication. Several routing protocols are designed for routing of the packets in the network. AODV (ad hoc on demand vector) is one such protocol. Since, nodes are mobile in the network, security is a main concern. Blackhole attack is a network layer attack that tries to hamper the routing process. In this attack the data packets are dropped. The paper focuses on the analysis of AODV routing protocol under blackhole attack. First we have implemented blackhole attack in AODV and then analyzed the impact of blackhole attack on AODV under metrics like throughput, end to end delay and packet delivery fraction.

A MANET is a collection of self-configured node connected with wireless links. Each node of a mobile ad hoc network acts as a router and finds out a suitable route to forward a packet from source to destination. This network is applicable in areas where establishment of infrastructure is not possible, such as in the military environment. Along with the military environment MANET is also used in civilian environment such as sports stadiums, meeting room. The routing functionality of each node is cause of many security threats on routing. In this paper addressed the problem of identifying and isolating wormhole attack that refuse to forward packets in wireless mobile ad hoc network. The impact of this attack has been shown to be detrimental to network performance, lowering the packet delivery ratio and dramatically increasing the end-to-end delay. Proposed work suggested the efficient and secure routing in MANET. Using this approach of buffer length and RTT calculation, routing overhead minimizes. This research is based on detection and prevention of wormhole attacks in AODV. The proposed protocol is simulated using NS-2 and its performance is compared with the standard AODV protocol. The statistical analysis shows that modified AODV protocol detects wormhole attack efficiently and provides secure and optimum path for routing.

A group of wireless nodes forming a dynamic wireless network without any infrastructure is a MANET. As network is becoming an important technology for commercial and military based distributed applications, implementation of security over MANET has proved to be mandatory, as such networks are more vulnerable to attacks. When dealing with data transfer between the nodes in MANET, confidentiality and message integrity are the two important factors that need to be focused carefully. This paper proposes the implementation of a security algorithm over data transfer in Optimized Link State Routing protocol providing Trust Management in MANET by implementing confidentiality through Digital Signatures and Message Integrity through 256-bit strong AES cryptographic techniques using Openssl.

Mobile Ad-Hoc Network is a wireless networking exemplar of mobile hosts which are connected by wireless links without usual routing infrastructure and link fixed routers. Dynamic Source Routing (DSR) is one of the extensively used routing protocol for packet transfer from source to destination. It relies on maintaining most recent information, for which, each adhoc node maintains hop count and sequence number field. They are vulnerable to security attacks due to their mutable nature. Analogously, routing updates are transmitted in clear text, which again poses a security hazard. In this paper, we will propose an improved version of DSR routing protocol using Homomorphic Encryption Scheme which prevents pollution attack and accomplishes in maintaining Integrity Security Standard by following minimum hop count path. HDSR routing scheme is evaluated by simulation and results show that improved throughput and ETE delay can be obtained.

In Mobile Ad hoc Network (MANET) is a self-organizing session of communication between wireless mobile nodes build up dynamically regardless of any established infrastructure or central authority. In MANET each node behaves as a sender, receiver and router which are connected directly with one another if they are within the range of communication or else will depend on intermediate node if nodes are not in the vicinity of each other (hop-to-hop). MANET, by nature are very open, dynamic and distributed which make it more vulnerable to various attacks such as sinkhole, jamming, selective forwarding, wormhole, Sybil attack etc. thus acute security problems are faced more related to rigid network. A Wormhole attack is peculiar breed of attack, which cause a consequential breakdown in communication by impersonating legitimate nodes by malicious nodes across a wireless network. This attack can even collapse entire routing system of MANET by specifically targeting route establishment process. Confidentiality and Authenticity are arbitrated as any cryptographic primitives are not required to launch the attack. Emphasizing on wormhole attack attributes and their defending mechanisms for detection and prevention are discussed in this paper.

Mobile Ad hoc NETworks (MANETs) is a collection of mobile nodes and they can communicate with each other over the wireless medium without any fixed infrastructure. In MANETs any node can join and leave the network at any time and this makes MANETs vulnerable to a malicious attackers. Hence, it is necessary to develop an efficient intrusion-detection system to safeguard the MANET from attacks. In this paper, an Enhanced Adaptive Acknowledgement with Digital Signature Algorithm namely (EAACK-DSA) has been proposed which can detect and isolate the malicious nodes. This algorithm is based on the acknowledgement packet and hence all acknowledgement packets are digitally signed before transmission. The proposed algorithm can be integrated with any source routing protocol and EAACK-DSA gives a better malicious-behavior-detection than the conventional approaches.