From the software developers to the ones who implement any digital application, they have to face so many anomalies such as software bugs or security issues. This creates an urge of something that not only fixes bugs and cyber issues but also creates a robust system for the smooth implementation of software applications. This is where digital immune system makes a difference in network security and performance. 

Just like biological immune system which protect, responds and guards the human system towards invading pathogens, digital immune system also do the same. It utilizes a range of software engineering strategies, techniques, technologies, and data analytics to automatically reduce and react to operational and security risks in real time. It makes your system so resilient that you won’t need to install any protective firewalls against them. 

Where enterprises have to face unprecedented challenges in assuring stable operational conditions, quick digital distribution, and dependable end-user experience, having digitally resilient and good-to-go systems is the only thing they need. 

Let’s get started with the query that what is digital immune system and why is this perspective: a future for better world. 

WHAT IS DIGITAL IMMUNE SYSTEM (DIS)? 

digital immune system

IBM created the Digital Immune system, a robust virus defense system. The growing threat of Internet-based viral spread has been the driving force behind this advancement. A logical progression in automated, centralized anti-virus operations is represented by IBM’s DIS. It is a concept that has taken nearly ten years to materialize and illustrates what the anti-virus industry may look like in the future. a time when there is no need for human intervention in any step of the anti-virus process, including signature creation, virus cleaning, and virus detection. 

Integrity monitors and anti-virus heuristics monitoring at the client level, a virus scanner, an algorithm to identify virus features, a signature extractor, a central database, and a method for distributing fresh signatures to other computers were all included in the proposed architecture.

The ability of the virus analysis device to find novel and inventive virus strains is crucial to the success of the digital immune system.
It should be possible to continuously upgrade the Digital Immune System software to stay ahead of the threat by continuously studying and monitoring the viruses discovered in the wild.

HOW DIGTAL IMMUNE SYSTEM WORKS? 

The digital immune system generally follows following steps: 

  • Anti-virus Heuristic Monitoring: Each PC has a monitoring programme that alerts users to the possibility of a virus presence using a range of heuristics based on system behavior, suspicious modifications to programmes, or family signature. Any programme that is suspected of being infected is forwarded to an administrative machine within the organization by the monitoring application.
  • Virus Analysis: The sample is encrypted by the administrative machine before being sent to a centralized virus analysis machine. This steps is done to find the nature of virus so that systems could design sufficient control against that virus. 
  • Prescription: This device produces a setting that makes it safe to launch the infected programme for analysis. Emulation, or the development of a secure environment in which the suspect programme may be run and observed, is a technique employed for this purpose. The equipment that analyses viruses then generates a prescription for finding and eliminating the infection.
  • Administration: It then returns the prescription to the administrative device. The infected client receives the prescription from the administration machine. Other clients in the company are also sent the prescription.
  • Quarantine:  The decoy files are reviewed for updates on a regular basis. The files are quarantined if any modifications are discovered. An algorithm looks for frequent byte sequences and the infection mechanism. Using the typical byte sequences that the infection method algorithm recommended, the signature extractor makes an effort to construct a signature. After that, the virus’s identity is recorded in the database. Finally, the system notifies other computers of the virus via signals.

WHY IS DIS IMPORTANT?

Increased Customer Experience

Nearly half of respondents (48%) to a recent Gartner poll regarding removing obstacles to digital execution claimed that the main goal of their digital investments is to enhance the customer experience (CX). To make sure that CX is not jeopardized by flaws, malfunctions, or abnormalities such software bugs or security problems, DIS will be essential.

Let’s enlist few other reasons which makes DIS a necessary switch from the conventional anti-virus processes. 

Lack of Resilience

In essence, DIS tries to address problems brought on by the software engineering teams’ inability to control the quick rate of change or complexity of systems, which makes it impossible to design strong and durable applications. In other words, DIS aids software firms in developing software applications that are more resilient and less prone to failure.

Increased Risk of Business Assets

Since most of our practices has been shifted to digital networks, it has also made some valuable asset more prone to vulnerabilities which our systems aren’t capable to withstands. Therefore, to address all such issues we need a digital space which prevents the invaders or the hackers to breach or discourage theft. In addition to this, the previous anti-virus protocols are now compromised since  hackers have  find out their way in, despite of the internal controls being fully functional. It means traditional controls are no more promising. 

DIS Assisting Software Engineers 

Software engineering teams can become more visible in addressing threats and vulnerabilities such as functional problems, security vulnerabilities, and data inconsistencies thanks to the integration of technologies and processes in DIS.

PREREQUISITES FOR THE EFFICIENT DIS 

Automation And Testing Using AI

By focusing on integrating context-sensitive monitoring capabilities and automated remediation features directly into an application, it enables businesses to make software testing activities increasingly independent from human intervention. Without the assistance of operations employees, it self-monitors, fixes problems as they arise automatically, and resumes regular functioning.

Observability 

It is the capacity to gauge a system’s state right now using the data it produces. Systems and software can be “seen” thanks to observability. By incorporating observability into programmes, developers are able to alleviate reliability and resilience problems and enhance user experience (UX).

Chaos-Engineering

Exploratory testing is used in chaos engineering to identify weak points in a complicated system. Teams can safely perfect the technique in non-intrusive, test-first environments when applied there. They can then apply what they’ve learned to regular operations and production hardening.

SRE 

It focuses on enhancing customer experience and retention by utilizing service-level goals to control service management. It is a set of engineering principles and techniques. It lessens the burden on development teams of tech debt remediation and risk management while balancing the need for velocity versus stability and risk.

Auto-remediation

A software ecosystem or system is able to keep track of itself and address problems without the need for human intervention. The importance of self-healing and auto-remediation grows as cloud environments expand and system interdependencies increase. It can also avoid problems by fixing a poor user experience by combining chaotic engineering and observability.

STRENGTHS OF DIGITAL IMMUNE SYTEM

This approach has a number of strengths over conventional anti-virus processes. Signature files, especially those written in high-level languages, are as good or better than human-produced signature files. These signature files are created in a significantly faster period of time with fewer instances of false-positives. [4] Additionally, as the number of viruses in the wild grows, an automated system with scaling capabilities will be able to grow faster and handle many more viruses than a system which relies on humans that possesses a special knowledge for decoding viruses and creating signatures. 

DIS has been a system with more resilience, scalability and can cater different problems at a time. To lessen the chance of virus samples and signatures being intercepted in transit, DIS uses encryption and secured channels on HTTP port 80.

For smaller businesses without specialized IT staff to deal with infections, the DIS technology in a fully automated solution becomes essential. Since clearing up viruses would be significantly less expensive with a well set system, minimal maintenance would be needed and a significant return on investment would result. Large businesses can customize the system to provide the most effective level of control and enable specialized IT employees to manage anti-virus activities by providing the control at the Administrators Console.

Finally, IBM and Symantec have made the application flexible so that it may be customized to fit current infrastructures, particularly in terms of Administrator-level controls.