Beckhoff

Debunking the myths: How Machine Learning (ML) benefits cyber security

15 December 2020

Artificial Intelligence (AI) is defined as ‘the theory and development of computer systems able to perform tasks normally requiring human intelligence’. Machine learning (ML) is a sub-field within AI. The pioneer, Arthur Samuel, promoted the term ML in 1959, as the “Field of study that gives computers the ability to learn without being explicitly programmed”.

In the Cambridge Dictionary, ML is referred to as ‘The process of computers changing the way they carry out tasks by learning from new data, without a human being needing to give instructions in the form of a program’. And, in the Oxford Lexico, it is used to describe ‘The use and development of computer systems that are able to learn and adapt without following explicit instructions, by using algorithms and statistical models to analyse and draw inferences from patterns in data’.

Generally speaking, ML relies on mathematical models which are built by analysing patterns in datasets. These patterns are then used to make predictions on new input data. Similar to the way Netflix offers recommendations for new TV series, based on previous viewing experiences, ML is one of the many approaches to AI that uses a system that is capable of learning from experience, and builds upon what has been learnt.

Misconceptions 

People are often scared or apprehensive about what they do not understand. Although ML is not a new concept for experts in the field, many are only just getting to grips with what it is and how it can be used. Because the term ML is associated with depictions portrayed in the media of power-hungry robots with a thirst for human destruction, many recoil at the thought of utilising it in business or private use. But the truth is that these portrayals are not accurate representations, and ML is used by the majority of us, on a daily basis, without us even fully recognising how or where. 

Examples of daily ML in action includes the use of portrait mode on your smart phone, social media feeds on applications such as Facebook or Instagram, music and media streaming including BBC iPlayer or Netflix, online adverts tailored to the user journey, pretty much every online game, banking apps, smart devices…the list is endless. 

From reinforcement learning, semi-supervised learning, self-learning, feature learning, sparse dictionary learning, anomaly detection and robot learning, there are many different approaches and techniques used. But, on the whole, machine learning can be broadly classified into two classes, known as supervised and unsupervised learning. 

Supervised Learning 

Supervised Learning is where a machine learns from training data, and maps out inputs and outputs, based on rules provided in said training data, and from inferred functions. In Supervised Learning, the dataset is labelled, wherein there is a target variable. The value of which the ML model learns to predict, using different algorithms. For instance, it may do this based on IP address location, frequency of web requests and so on. From this, an ML model can then predict if the IP was part of say a Distributed Denial-of-service (DDoS) attack, and more.

The main goal is for the machine to extract the information from the unlabelled data sets, that could aid performance and increase productivity.

Unsupervised Learning 

In Unsupervised Learning, there is no labelled data, thereby, no prediction of a target variable. Unsupervised Learning tries to find interesting associations, or patterns, within a dataset. For instance, clustering can be applied in user analytics where application users can be grouped together. By doing this, it is possible to see what data should belong to a specific group, or not. 

Machine learning is about developing patterns and manipulating those patterns with algorithms. In order to develop patterns, we need a lot of data that has complete, relevant and rich context. It is not just about the quantity of the data, but also the quality. 

Essentially, accurate and rapid security depends on the initial data collection. There are many systems out there, buzzing away, both on-premise and on the Cloud. You need to be able to get the data from those systems, process it, correlate, and analyse those systems. Whether via traditional Syslog, Cloud API, AWS, Azure, Statistical Analysis Systems (SAS) services, or something else, you need to get that data, and have it presented in a way that can be processed quickly and efficiently.

And, once you have the right logs, they need to be validated. You can start to standardise and normalise them. Start with basic correlation. By contextualising the traffic logs against threat intelligence data, analysts can see where risky user activity might be present. This, very quickly, moves along to advanced analytics.

Which is why Data Cleansing is an important part of machine learning, and helps analysts make sense of the raw data captured from multiple sources. 

“If intelligence is a cake, the bulk of the cake is unsupervised learning, the icing on the cake is supervised learning, and the cherry on the cake is reinforcement learning (RL),” said Facebook AI Chief Yann LeCun

Applications of Machine Learning in cyber security

To better understand previous cyber-attacks, and develop respective defence responses, ML can be leveraged in various domains within cyber security to enhance security processes, and make it easier for security analysts to quickly identify, prioritise, deal with and remediate new attacks. 

The following headings are just a few methods ML can be used to aid security. 

Automating tasks

A great benefit of ML in cyber security is its capacity to automate repetitive and time-consuming tasks, such as triaging intelligence, malware analysis, network log analysis and vulnerability assessments. By incorporating ML into the security workflow, organisations can accomplish tasks faster, and act on and remediate threats at a rate that would not be possible with manual human capability alone. Automating repetitive processes means that clients can up or down scale easily, without changing the manpower needed, thus reducing costs in the process. 

The method of automating practices via ML is sometimes referred to as AutoML. AutoML signifies when repetitive tasks involved in development are automated to specifically aid the productivity of the analysts, data scientists and developers. 

Threat detection and classification

Machine learning algorithms are used in applications to detect and respond to attacks. This can be achieved by analysing big data sets of security events and identifying patterns of malicious activities. ML works so that when similar events are detected, they are automatically dealt with by the trained ML model. 

For instance, the dataset to feed a machine learning model can be created by using Indicators of Compromise (IOCs). These can help monitor, identify, and respond to threats in real time. ML classification algorithms can be used using IOC data sets to classify the behaviour of malwares. 

An example of such a use is evident in a report from Darktrace, an ML based Enterprise Immune Solution, that claims to have prevented attacks during the WannaCry ransomware crisis. According to David Palmer, Director of Technology at Darktrace, “Our algorithms spotted the attack within seconds in one NHS agency’s network, and the threat was mitigated without causing any damage to that organisation,” he said of the ransomware, which infected more than 200,000 victims across 150 countries.

Phishing

Traditional phishing detection techniques alone lacks the speed and accuracy to detect and differentiate between harmless and malicious URLs. Latest ML algorithm predictive URL classification models can identify patterns that reveal malicious emails. To do this, the models are trained on features such as email headers, body-data, punctuation patterns, and more to classify and differentiate the malicious from the harmless. 

WebShell

WebShell is a piece of code that is maliciously loaded into a website to provide access to make modifications on the web root directory of the server. This allows attackers to gain access of the database. Which, in turn, enables the bad actor to collect personal information. By using ML, a normal shopping cart behaviour can be detected, and the model can be trained to differentiate between normal and malicious behaviour.

The same goes for User Behaviour Analytics (UBA), which forms a supplementary layer to standard security measures, to provide complete visibility, detect account compromises, and mitigate and detect malicious or anomalous insider activity. By using ML algorithms, patterns of user behaviour are categorised, to understand what constitutes normal behaviour, and to detect abnormal activity. If an unusual action is made on a device on a given network, such as an employee login late at night, inconsistent remote access, or an unusually high number of downloads, the action and user is given a risk score based on their activity, patterns and time.

Network Risk Scoring

Use of quantitative measures to assign risk scores to sections of networks, help organisations to prioritise resources. ML can be used to analyse previous cyber-attack datasets and determine which areas of networks were mostly involved in particular attacks. This score can help quantify the likelihood, and impact of an attack, with respect to a given network area. Thus, helping organisations to reduce the risk of being victimised by further attacks.

When you are doing business profiling, you have to decipher what area, if compromised, is going to destroy your business. It could be a Customer Relationship Management (CRM) system, your accounting system, or your sales system. It’s about knowing, within your specific business environment, what area is most vulnerable. Say, for instance, HR goes down, this may have a low-risk score within your company. But if your oil trading platform goes down, that could bring down your entire business. Every company has a different way of doing security. And once you understand the specifics of an organisation, you know what to really protect. And if there is a hack, you know what to prioritise.

The future of ML

ML is a powerful tool. There is no denying that. But it is no silver bullet. It is important to remember that, while technology is developing, and advancements in AI and ML are evolving at a significant rate, technology is only as good, or as bad, as the minds of the analysts controlling and using it. 

There will always be bad actors developing their skills and technology to find and exploit weaknesses. Which is why it is crucial to combine the best technology and processes with industry experts, to be able to detect and respond to cyber threats accurately and rapidly. 

To learn more about the use of Machine Learning (ML) and Artificial Intelligence (AI) within security analytics, and to debunk some of the common misconceptions and myths surrounding what constitutes AI and ML, view our video on ‘Using Machine Learning & AI to Hunt Risk in the Real World’ here.


More information...

Print this page | E-mail this page


Stone Junction Ltd

This website uses cookies primarily for visitor analytics. Certain pages will ask you to fill in contact details to receive additional information. On these pages you have the option of having the site log your details for future visits. Indicating you want the site to remember your details will place a cookie on your device. To view our full cookie policy, please click here. You can also view it at any time by going to our Contact Us page.