Visible to the public Biblio

Filters: Keyword is DDOS attacks detection  [Clear All Filters]
2021-09-07
Sanjeetha, R, Shastry, K.N Ajay, Chetan, H.R, Kanavalli, Anita.  2020.  Mitigating HTTP GET FLOOD DDoS Attack Using an SDN Controller. 2020 International Conference on Recent Trends on Electronics, Information, Communication Technology (RTEICT). :6–10.
DDoS attacks are pre-dominant in traditional networks, they are used to bring down the services of important servers in the network, thereby affecting its performance. One such kind of attack is HTTP GET Flood DDoS attack in which a lot of HTTP GET request messages are sent to the victim web server, overwhelming its resources and bringing down its services to the legitimate clients. The solution to such attacks in traditional networks is usually implemented at the servers, but this consumes its resources which could otherwise be used to process genuine client requests. Software Defined Network (SDN) is a new network architecture that helps to deal with these attacks in a different way. In SDN the mitigation can be done using the controller without burdening the server. In this paper, we first show how an HTTP GET Flood DDoS attack can be performed on the webserver in an SDN environment and then propose a solution to mitigate the same with the help of the SDN controller. At the server, the attack is detected by checking the number of requests arriving to the web server for a certain period of time, if the number of request is greater than a particular threshold then the hosts generating such attacks will be blocked for the attack duration.
Bülbül, Nuref\c san Sertba\c s, Fischer, Mathias.  2020.  SDN/NFV-Based DDoS Mitigation via Pushback. ICC 2020 - 2020 IEEE International Conference on Communications (ICC). :1–6.
Distributed Denial of Service (DDoS) attacks aim at bringing down or decreasing the availability of services for their legitimate users, by exhausting network or server resources. It is difficult to differentiate attack traffic from legitimate traffic as the attack can come from distributed nodes that additionally might spoof their IP addresses. Traditional DoS mitigation solutions fail to defend all kinds of DoS attacks and huge DoS attacks might exceed the processing capacity of routers and firewalls easily. The advent of Software-defined Networking (SDN) and Network Function Virtualization (NFV) has brought a new perspective for network defense. Key features of such technologies like global network view and flexibly positionable security functionality can be used for mitigating DDoS attacks. In this paper, we propose a collaborative DDoS attack mitigation scheme that uses SDN and NFV. We adopt a machine learning algorithm from related work to derive accurate patterns describing DDoS attacks. Our experimental results indicate that our framework is able to differentiate attack and legitimate traffic with high accuracy and in near-realtime. Furthermore, the derived patterns can be used to create OpenFlow (OF) or Firewall rules that can be pushed back into the direction of the attack origin for more efficient and distributed filtering.
Zebari, Rizgar R., Zeebaree, Subhi R. M., Sallow, Amira Bibo, Shukur, Hanan M., Ahmad, Omar M., Jacksi, Karwan.  2020.  Distributed Denial of Service Attack Mitigation Using High Availability Proxy and Network Load Balancing. 2020 International Conference on Advanced Science and Engineering (ICOASE). :174–179.
Nowadays, cybersecurity threat is a big challenge to all organizations that present their services over the Internet. Distributed Denial of Service (DDoS) attack is the most effective and used attack and seriously affects the quality of service of each E-organization. Hence, mitigation this type of attack is considered a persistent need. In this paper, we used Network Load Balancing (NLB) and High Availability Proxy (HAProxy) as mitigation techniques. The NLB is used in the Windows platform and HAProxy in the Linux platform. Moreover, Internet Information Service (IIS) 10.0 is implemented on Windows server 2016 and Apache 2 on Linux Ubuntu 16.04 as web servers. We evaluated each load balancer efficiency in mitigating synchronize (SYN) DDoS attack on each platform separately. The evaluation process is accomplished in a real network and average response time and average CPU are utilized as metrics. The results illustrated that the NLB in the Windows platform achieved better performance in mitigation SYN DDOS compared to HAProxy in the Linux platform. Whereas, the average response time of the Window webservers is reduced with NLB. However, the impact of the SYN DDoS on the average CPU usage of the IIS 10.0 webservers was more than those of the Apache 2 webservers.
Al'aziz, Bram Andika Ahmad, Sukarno, Parman, Wardana, Aulia Arif.  2020.  Blacklisted IP Distribution System to Handle DDoS Attacks on IPS Snort Based on Blockchain. 2020 6th Information Technology International Seminar (ITIS). :41–45.
The mechanism for distributing information on the source of the attack by combining blockchain technology with the Intrusion Prevention System (IPS) can be done so that DDoS attack mitigation becomes more flexible, saves resources and costs. Also, by informing the blacklisted Internet Protocol(IP), each IPS can share attack source information so that attack traffic blocking can be carried out on IPS that are closer to the source of the attack. Therefore, the attack traffic passing through the network can be drastically reduced because the attack traffic has been blocked on the IPS that is closer to the attack source. The blocking of existing DDoS attack traffic is generally carried out on each IPS without a mechanism to share information on the source of the attack so that each IPS cannot cooperate. Also, even though the DDoS attack traffic did not reach the server because it had been blocked by IPS, the attack traffic still flooded the network so that network performance was reduced. Through smart contracts on the Ethereum blockchain, it is possible to inform the source of the attack or blacklisted IP addresses without requiring additional infrastructure. The blacklisted IP address is used by IPS to detect and handle DDoS attacks. Through the blacklisted IP distribution scheme, testing and analysis are carried out to see information on the source of the attack on each IPS and the attack traffic that passes on the network. The result is that each IPS can have the same blacklisted IP so that each IPS can have the same attack source information. The results also showed that the attack traffic through the network infrastructure can be drastically reduced. Initially, the total number of attack packets had an average of 115,578 reduced to 27,165.
Manikumar, D.V.V.S., Maheswari, B Uma.  2020.  Blockchain Based DDoS Mitigation Using Machine Learning Techniques. 2020 Second International Conference on Inventive Research in Computing Applications (ICIRCA). :794–800.
DDoS attacks are the most commonly performed cyber-attacks with a motive to suspend the target services and making them unavailable to users. A recent attack on Github, explains that the traffic was traced back to ``over a thousand different autonomous systems across millions of unique endpoints''. Generally, there are various types of DDoS attacks and each attack uses a different protocol and attacker uses a botnet to execute such attacks. Hence, it will be very difficult for organizations to deal with these attacks and going for third parties to secure themselves from DDoS attacks. In order to eliminate the third parties. Our proposed system uses machine learning algorithms to identify the incoming packet is malicious or not and use Blockchain technology to store the Blacklist. The key benefit of Blockchain is that blacklisted IP addresses are effectively stored, and usage of such infrastructure provides an advantage of extra security mechanism over existing DDoS mitigation systems. This paper has evaluated three different algorithms, such as the KNN Classifier, the Decision Tree Classifier, Random Forest algorithm to find out the better classifying algorithm. Tree Based Classifier technique used for Feature Selection to boost the computational time. Out of the three algorithms, Random Forest provides an accuracy about 95 % in real-time traffic analysis.
Abisoye, Opeyemi Aderiike, Shadrach Akanji, Oluwatobi, Abisoye, Blessing Olatunde, Awotunde, Joseph.  2020.  Slow Hypertext Transfer Protocol Mitigation Model in Software Defined Networks. 2020 International Conference on Data Analytics for Business and Industry: Way Towards a Sustainable Economy (ICDABI). :1–5.
Distributed Denial of Service (DDoS) attacks have been one of the persistent forms of attacks on information technology infrastructure connected to a public network due to the ease of access to DDoS attack tools. Researchers have been able to develop several techniques to curb volumetric DDoS attacks which overwhelms the target with large number of request packets. However, compared to volumetric DDoS, low amount of research has been executed on mitigating slow DDoS. Data mining approaches and various Artificial Intelligence techniques have been proved by researchers to be effective for reduce DDoS attacks. This paper provides the scholarly community with slow DDoS attack detection techniques using Genetic Algorithm and Support Vector Machine aimed at mitigating slow DDoS attack in a Software-Defined Networking (SDN) environment simulated in GNS3. Genetic algorithm was employed to select the features which indicates the presence of an attack and also determine the appropriate regularization parameter, C, and gamma parameter for the Support Vector Machine classifier. Results obtained shows that the classifier had detection accuracy, Area Under Receiver Operating Curve (AUC), true positive rate, false positive rate and false negative rate of 99.89%, 99.89%, 99.95%, 0.18%, and 0.05% respectively. Also, the algorithm for subsequent implementation of the selective adaptive bubble burst mitigation mechanism was presented.
Sanjeetha, R., Srivastava, Shikhar, Kanavalli, Anita, Pattanaik, Ashutosh, Gupta, Anshul.  2020.  Mitigation of Combined DDoS Attack on SDN Controller and Primary Server in Software Defined Networks Using a Priority on Traffic Variation. 2020 International Conference for Emerging Technology (INCET). :1–5.
A Distributed Denial of Service ( DDoS ) attack is usually instigated on a primary server that provides important services in a network. However such DDoS attacks can be identified and mitigated by the controller in a Software Defined Network (SDN). If the intruder further performs an attack on the controller along with the server, the attack becomes successful.In this paper, we show how such a combined DDoS attack can be instigated on a controller as well as a primary server. The DDoS attack on the primary server is instigated by compromising few hosts to send packets with spoofed IP addresses and the attack on the controller is instigated by compromising few switches to send flow table requests repeatedly to the controller. With the help of an emulator called mininet, we show the severity of this attack on the performance of the network. We further propose a common technique that can be used to mitigate this kind of attack by observing the variation of destination IP addresses and setting different priorities to switches and handling the flow table requests accordingly by the controller.
Jonker, Mattijs, Sperotto, Anna, Pras, Aiko.  2020.  DDoS Mitigation: A Measurement-Based Approach. NOMS 2020 - 2020 IEEE/IFIP Network Operations and Management Symposium. :1–6.
Society heavily relies upon the Internet for global communications. Simultaneously, Internet stability and reliability are continuously subject to deliberate threats. These threats include (Distributed) Denial-of-Service (DDoS) attacks, which can potentially be devastating. As a result of DDoS, businesses lose hundreds of millions of dollars annually. Moreover, when it comes to vital infrastructure, national safety and even lives could be at stake. Effective defenses are therefore an absolute necessity. Prospective users of readily available mitigation solutions find themselves having many shapes and sizes to choose from, the right fit of which may, however, not always be apparent. In addition, the deployment and operation of mitigation solutions may come with hidden hazards that need to be better understood. Policy makers and governments also find themselves facing questions concerning what needs to be done to promote cybersafety on a national level. Developing an optimal course of action to deal with DDoS, therefore, also brings about societal challenges. Even though the DDoS problem is by no means new, the scale of the problem is still unclear. We do not know exactly what it is we are defending against and getting a better understanding of attacks is essential to addressing the problem head-on. To advance situational awareness, many technical and societal challenges need still to be tackled. Given the central importance of better understanding the DDoS problem to improve overall Internet security, the thesis that we summarize in this paper has three main contributions. First, we rigorously characterize attacks and attacked targets at scale. Second, we advance knowledge about the Internet-wide adoption, deployment and operational use of various mitigation solutions. Finally, we investigate hidden hazards that can render mitigation solutions altogether ineffective.
2021-02-16
Başkaya, D., Samet, R..  2020.  DDoS Attacks Detection by Using Machine Learning Methods on Online Systems. 2020 5th International Conference on Computer Science and Engineering (UBMK). :52—57.
DDoS attacks impose serious threats to many large or small organizations; therefore DDoS attacks have to be detected as soon as possible. In this study, a methodology to detect DDoS attacks is proposed and implemented on online systems. In the scope of the proposed methodology, Multi Layer Perceptron (MLP), Random Forest (RF), K-Nearest Neighbor (KNN), C-Support Vector Machine (SVC) machine learning methods are used with scaling and feature reduction preprocessing methods and then effects of preprocesses on detection accuracy rates of HTTP (Hypertext Transfer Protocol) flood, TCP SYN (Transport Control Protocol Synchronize) flood, UDP (User Datagram Protocol) flood and ICMP (Internet Control Message Protocol) flood DDoS attacks are analyzed. Obtained results showed that DDoS attacks can be detected with high accuracy of 99.2%.
2020-02-26
Kaur, Gaganjot, Gupta, Prinima.  2019.  Hybrid Approach for Detecting DDOS Attacks in Software Defined Networks. 2019 Twelfth International Conference on Contemporary Computing (IC3). :1–6.

In today's time Software Defined Network (SDN) gives the complete control to get the data flow in the network. SDN works as a central point to which data is administered centrally and traffic is also managed. SDN being open source product is more prone to security threats. The security policies are also to be enforced as it would otherwise let the controller be attacked the most. The attacks like DDOS and DOS attacks are more commonly found in SDN controller. DDOS is destructive attack that normally diverts the normal flow of traffic and starts the over flow of flooded packets halting the system. Machine Learning techniques helps to identify the hidden and unexpected pattern of the network and hence helps in analyzing the network flow. All the classified and unclassified techniques can help detect the malicious flow based on certain parameters like packet flow, time duration, accuracy and precision rate. Researchers have used Bayesian Network, Wavelets, Support Vector Machine and KNN to detect DDOS attacks. As per the review it's been analyzed that KNN produces better result as per the higher precision and giving a lower falser rate for detection. This paper produces better approach of hybrid Machine Learning techniques rather than existing KNN on the same data set giving more accuracy of detecting DDOS attacks on higher precision rate. The result of the traffic with both normal and abnormal behavior is shown and as per the result the proposed algorithm is designed which is suited for giving better approach than KNN and will be implemented later on for future.