Category: Industry Scoop

Sometimes, you can deploy firewalls or physical security measures to segment an asset and prevent an intrusion. In other circumstances, you may have to transition to an entirely new approach—even if that means replacing an otherwise functional segment.

Common ICS Threats

Years ago, the industrial cycle was powered by machines without computational abilities. Therefore, they could not be influenced by secluded hacks, network interruptions, or data exfiltration. However, in the existing industrial landscape, there are several omnipresent threats.

External Threats and Targeted Attacks

Because industrial processes directly impact many people’s health and quality of life, they are often the prey of hacktivists, terrorists, and others seeking detriment.

It requires a defense-in-depth strategy that covers crucial systems from those striving to interrupt or stop necessary procedures. Even a momentary interruption would be adequate to influence the lives of thousands. An outer person or group aims to steal intellectual property, exfiltrate data or stop production to either yield a competitive benefit or cause damage to targeted parties.

Internal Threats

As many ICS systems lack authentication standards that govern who can access respective production elements, when a person has been granted access, they may be able to affect many machines and systems all by themselves. This makes internal threats particularly problematic because one individual can do much harm.

With the preface of malware to a software-dependent system, it can halt the entire production. Also, with credentials to an internal database, a thief can pocket large amounts of data quickly and easily.

Human Error

Human error—such as misconfiguring equipment, incorrectly programming machinery, or overlooking alerts—can considerably affect operations. Often, these mistakes may result from a well-meaning person serving someone with more understanding of operating a machine or system—their lack of experience upshots in pricey supervision.

ICS Security Best Techniques

Limit access to the crucial regions of the system’s network and functionality. For example, firewalls can form a fence between the machinery and the organization’s grid.

Confine those who do not need a physical permit to come into contact with necessary ICS apparatuses. This may enclose physical actions like guards or digital methods such as card readers.

Use security measures for individual elements of the ICS. To do this, you can block unused ports, seat security patches, and implement least-privilege principles to ensure that only those who require access to the system can.
Safeguard data from being altered while it is being stored or transmitted.

Security Standards

Several security standards are commonly involved in ICS cybersecurity. These incorporate the National Institute of Standards and Technology (NIST) Special Publication (SP) 800-82, legislated by the U.S. Department of Commerce to sustain advanced secure, valuable methods in industrial backgrounds.

Also, the American National Standards Institute/International Society of Automation has published the ANSI/ISA A99 benchmark. This body sustains automated interfaces for establishments managing their control systems.

How Can TSAROLABS Assist?

The TSAROLABS industrial control systems/supervisory control and data acquisition key protect various industrial aids and approaches. Security is facilitated by preferring the most efficacious tools for corporate IT infrastructures, concealing from the data camp to the network edge to the cloud.

Visibility hinges on defining the attack surface’s various elements and the data traveling to and from each area. Control is achieved through network segmentation and micro-segmentation, sandboxing, quarantining, and multi-factor authentication (MFA) strategies to control who has credentials to limit the consequence of events.
Behavioral analytics studies the practices of users, computers, and networks to detect risk events and incorporates reacting to events and limiting or inverting their impact on the system.

Related Tags
Cybersecurity, Cyber Attack, Industrial Control System, Firewalls, Network Interruption, data exfiltration, Internal Threat, Human Error.

Maritime cyber risk alludes to a proportion of the degree to which an innovation resource could be a potential circumstance or event, which might bring about transportation-related operations, safety, or security failures because of data or frameworks being corrupted, lost or compromised.

Cyberattacks on overall port offices have featured the critical requirement for port facility security officers (PFSOs) to redesign their network safety information and abilities.

According to IMO (International Maritime Organization), the Maritime Safety Committee, at its 98th session in June 2017, also adopted Resolution MSC.428(98) – Maritime Cyber Risk Management in Safety Management Systems. The resolution encourages administrations to ensure that cyber risks are appropriately addressed in existing safety management systems (as defined in the ISM Code) no later than the first annual verification of the company’s Document of Compliance after 1 January 2021.

Recently, some port communities have taken key first steps to drive cyber security capability development in their environments by engaging with investors and experts. For example, cyber security efforts are rapidly strengthening at key port trade hubs as a direct result of a new wave of investment accelerators, technical centers of excellence, and academic programs focused on innovative technologies, including start-ups in ports and maritime trade logistics.

Cybertechnologies have become essential to the operation and management of numerous systems critical to the safety and security of shipping and protection of the marine environment. In some cases, these systems are to comply with international standards and Flag Administration requirements. However, the vulnerabilities created by accessing, interconnecting, or networking these systems can lead to cyber risks which should be addressed. Vulnerable systems could include, but are not limited to:

•  Bridge systems
• Cargo handling and management systems
• Propulsion and machinery management and power control systems
• Access control systems
• Passenger servicing and management systems
• Passenger facing public networks
• Administrative and crew welfare systems and
• Communication systems

Also, Cyber incidents can arise as the result of:

• A cyber security incident, which affects the availability and integrity of OT, for example corruption of chart data held in an Electronic Chart Display and Information System (ECDIS).
• An unintended system failure occurring during software maintenance and patching, for example using an infected USB drive to complete the maintenance.
• Loss of or manipulation of external sensor data, critical for the operation of a ship. This includes but is not limited to Global Navigation Satellite Systems (GNSS), of which the Global Positioning System (GPS) is the most frequently used.
• Failure of a system due to software crashes and/or “bugs”.
• Crew interaction with phishing attempts, which is the most common attack vector by threat actors, which could lead to the loss of sensitive data and the introduction of malware to shipboard systems.

Perceiving that no two associations in the transportation business are something similar, these Guidelines are communicated in expansive terms to have a far-reaching application. Ships with restricted digital related frameworks might track down a basic use of these Guidelines to be adequate; in any case, ships with complex digital related frameworks might require a more prominent degree of care and ought to look for extra assets through respectable industry and Government accomplices.

A few functional elements that support effective cyber risk management and these functional elements are of not sequential, and all should be concurrent and continuous in practice and should be incorporated appropriately in a risk management framework:

1. Identify: Define personnel roles and responsibilities for cyber risk management and identify the systems, assets, data, and capabilities that, when disrupted, pose risks to ship operations.
2. Protect: Implement risk control processes and measures, and contingency planning to protect against a cyber-event and ensure continuity of shipping operations.
3. Detect: Develop and implement activities necessary to detect a cyber-event in a timely manner.
4. Respond: Develop and implement activities and plans to provide resilience and to restore systems necessary for shipping operations or services impaired due to a cyber-event.
5. Recover: Identify measures to back-up and restore cyber systems necessary for shipping operations impacted by a cyber-event.

Few Organizations to watch:

IAPH (International Association of ports and Harbors) – Founded in 1955, is a non-profit-making global alliance of 170 ports and 140 port-related organizations covering 90 countries. Its member ports handle more than 60 percent of global maritime trade and around 80 percent of world container traffic. IAPH has consultative NGO status with several United Nations agencies. In 2018, IAPH established the World Ports Sustainability Program (WPSP). WPSP covers five main areas of collaboration: energy transition, resilient infrastructure, safety and security, community outreach and governance.

ICHCA (International Cargo Handling Coordination Association) -Founded in 1952, is dedicated to improving the safety, security, sustainability, productivity and efficiency of cargo handling by all modes and through all phases of national and international supply chains. ICHCA International’s privileged NGO status enables it to represent its members and industry at large in front of national and international agencies and regulatory bodies including IMO. ICHCA’s International Technical Panel also provides technical advice and publications on a wide range of practical cargo handling issues.

Cyberattack scenarios at the port community level

• Acquiring critical data to steal high value cargo or allow illegal trafficking through a targeted attack.
• Propagation of ransomware leading to a total shutdown of port operations.
• Compromise of port community systems for manipulation or theft of data.
• Compromise of operational technology systems creating a major accident in port areas.

The Organizational ISSUE: To exacerbate the situation, implications will fill the vacuum made by the shortfall of normal definitions. For instance, when the term ‘cyber security’ emerges in the administration gatherings of numerous associations, non-technical leadership habitually highlight the “IT Person” as the de-facto individual answerable for dealing with the cyber risk. Such a response, and the practically visually impaired spread of this insight inside numerous associations and gatherings thereof, basically addresses a dismissal of aggregate liability. C-level administration could rather embrace by figuring out that digitalization and cyber security “are not IT issues, but rather business issues.” However, establishing a shared vocabulary is just the first step in creating a common language. The challenge remains to bridge the language barrier between technical and nontechnical leadership, with the latter group representing most port community stakeholders.

Asking yourself? What is lacking in Cyber defense of port security?

While the reasons for the lack of a community approach vary with each port, typical contributing factors include:

1. Lack of a Port Community Policy
2. Lack of Visibility
3. Unwillingness to Share Cyber Information
4. Lack of Resources
5. Early Warning System
6. Collaboration Forum

Case Study Example:

• The Port of Los Angeles Cyber Security Operations Center employs advanced technologies with layered detection capabilities. At the perimeter of the network, some 40 million unauthorized intrusion attempts are blocked every month. Within the network, multiple intrusion detection layers are used to continuously search for, detect and contain suspicious activities.
• The Port of Rotterdam Authority has developed its own cyber crisis response strategy which includes a Port Crisis Team. The aim of this team is to make strategic decisions on the continuation of safe and efficient handling of shipping. The Port Crisis Team is supported by three action centers. One focuses on maritime issues, another on solving the IT issue at hand and the final center aims to align communication (both inward and outward) between the parties involved.

Recent Scenario in India:

Mumbai Port under Ransomware attack: A suspected cyber-attack of the management information system (MIS) has vastly affected the container terminal run by the state-owned port authority at Jawaharlal Nehru Port which handles about 50% of the overall containerized cargo volume, across major ports in India, this incident was happened on February 21, 2022. This the same port that was under cyber attack in the year 2017 as well, as you see the more blind spotted Ness among the companies that handle the ports and government of India not taking proper measurements like the contingency plans for cyber threats and action response/ Incident response to happen this has been failed. As this port is handled by Danish shipping giant AP Moller-Maersk, which said that the cyber-attack had caused outages in its computer systems globally and couldn’t share proper details.

As these types of attacks will increase the load at other connected ports and without proper contingency plans, we can say it’s a clear “Critical Infrastructure Failure” by the government and by the shipping community which I personally hope they will resolve this at the earliest.

This is one of the key Industrial Control Security failure that a developing country like India, with huge population needs to address immediately as Nation wide threat actors are espying on the areas of vulnerabilities.

Published by – Sai Ram

Source:

https://www.iacs.org.uk/publications/recommendations/161-180/rec-166-new-corr2-cln/

https://www.ics-shipping.org/wp-content/uploads/2021/02/2021-Cyber-Security-Guidelines.pdf

https://wwwcdn.imo.org/localresources/en/OurWork/Security/Documents/MSC-FAL.1-Circ.3%20-%20Guidelines%20On%20Maritime%20Cyber%20Risk%20Management%20(Secretariat).pdf

https://sustainableworldports.org/wp-content/uploads/IAPH-Port-Community-Cyber-Security-Report-Q2-2020.pdf

 

Related Tags- cyberrisk, cyberattack, transportation, data, framework, cybertechnology, security, cybersecurity, sensordata, protect, detect, protection

Need for Cloud Security

Cyber threats to the BFSI system are rapidly increasing. The average cost of a financial services mega breach in 2022 was USD 387 million, taking 277 days to identify and contain a violation. And hence the global community must cooperate to protect it. Financial institutions are the richest sources of personally identifiable information of clients, customers, and stakeholders—they are primary breach targets and need a comprehensive threat defense plan.

Customer expectations, emerging technologies, and alternative business models are changing, and financial institutions must start implementing an action plan to help them prepare for any future threat. Recognizing the importance of cloud adoption, safe migration, and cloud security are significant. Cloud is the most uncontroversial goal for banks and other financial services firms to store and protect data and applications and permit advanced software applications via the internet. In addition, once massive data sets are combined in one place, the institution can apply advanced analytics for integrated insights.

Benefits to BFSI by adopting Cloud technologies

By moving workloads to the cloud, financial institutions can achieve the following.

1. Securing sensitive data of customers and mission-critical workloads safe and compliant.
2. Mitigating risk and accelerating cloud adoption for their most sensitive workloads.
3. Financial institutions can reshape customer experiences, streamline operations, and unlock new revenue models. Compromising security or regulatory compliance is unacceptable, especially on a public cloud.
4. Address compliance requirements with a standard controls platform built in collaboration with the finance industry.
5. Accelerating innovation with an ecosystem of ISVs, fintech, and SaaS providers
6. Protecting data with industry-leading security capabilities
7. Operate with choice and agility using hybrid cloud deployment options
8. Reduce your time to obtain cloud production approval using a standardized framework, compliance posture documentation, and continuous compliance tooling
9. Protection of Identity and Access through Cloud Identity and Access Management solutions. Financial Institutions must achieve authentication and authorization of user accounts and Access controls to restrict legitimate and malicious users from entering and compromising sensitive data and systems. In addition, password management, multi-factor authentication, and other methods of IAM make a strong cloud posture.

Want more from us on Cloud Services?
Please visit our service page https://tsarolabs.com/cloud-services/ to know more.
Get in touch with our security experts at connect@tsarolabs.com to understand you better!

Supply chain attacks are diverse and impact various industries. For example, the manufacturing industry has witnessed massive cyber security attacks by tampering with a company’s manufacturing processes, either by hardware or software. Due to the weak links in the supply chain, criminals get access to organization data and systems to infiltrate overall digital infrastructure.

Installing Malware at any stage of the supply chain can cause either disruptions or outages of an organization’s services. Therefore, manufacturers must be aware of many familiar sources of supply chain attacks, for example, commercial software, open-source supply chains, and foreign products.

How can manufacturers detect a supply chain attack?

• Building a systematic verification process for every possible pathway into a system. An inventory of all the assets and data pathways within a supply chain should be made, which should help detect potential security gaps within a system.
• To create a threat model of the organization’s environment. The threat models can include assigning assets to adversary categories.
• Cyber security training for the workforce and top management must be deployed to timely identify, respond to, and monitor the threats.

How can TSARO Labs help manufacturers Mitigate the Risk of Supply Chain Attacks?

• Evaluate the Risk of Third Parties by complying with appropriate cybersecurity regulations, conducting self-assessments and audits, and investing in proper cyber insurance.
• Limit Users’ Ability to Install Shadow IT (Unapproved Software) and Audit Unapproved Shadow IT Infrastructure
• Include Appropriate Termination Clauses in Vendor Contracts
• Review Access to Sensitive Data
• Secure IoT Devices
• Continually Monitor and Review Cybersecurity
• Build Secure Software Updates as Part of the Software Development Life Cycle
• Use Strong Code Integrity Policies To Allow Only Authorized Apps To Run
• Using client-side protection tools to filter downloaded content, looking for—and stopping—malicious code before it gets installed on a machine on your network.

Want More from TSAROLABS on Cybersecurity?
Contact our team of cyber security experts today at connect@tsarolabs.com.