Architecture Design. TSCTI designs customized Zero Trust architectures tailored to the organization's infrastructure. Leveraging frameworks like BeyondCorp and tools such as Google's BeyondCorp Enterprise, we create an architecture that validates and authenticates all users and devices attempting network access, minimizing the attack surface and enhancing overall security. 3. Implementation and Integration: Our team ensures the seamless implementation of Zero Trust principles across the organization. This involves integrating identity and access management solutions, multifactor authentication, and continuous monitoring tools to enforce strict access controls and continuously verify the trustworthiness of users and devices. 4. Risk Assessment and Mitigation: TSCTI conducts thorough risk assessments to identify potential vulnerabilities and threat vectors within the existing infrastructure. Through techniques like penetration testing and vulnerability management, we pinpoint areas of concern and develop strategies to mitigate risks, aligning with the principles of a Zero Trust model. 5.
Architecture Design. Due date of deliverable: March. 31th, 2014 Actual submission date: April 21st, 2015 Start date of project: January 1, 2014 Duration: 36 months Lead contractor for this deliverable: i2CAT Foundation Project co-funded by the European Commission within the Seventh Framework Programme Dissemination Level PU Public X PP Restricted to other programme participants (including the Commission Services) RE Restricted to a group specified by the consortium (including the Commission Services) CO Confidential, only for members of the consortium (including the Commission Services) Executive Summary On the basis of the defined requirements carried out in Tasks T1.1, T1.2, this deliverable reports possible network architecture designs with respect to the data and control plane requirements for future DCN. The deliverable compiles a full set of requirements (reviews D1.1 requirements and completes the list) whose analysis enables to identify basic functionalities, layers and interfaces suitable for the COSIGN architecture design. Besides, a review of recent related initiatives has been carried out. It is not the aim of WP1 partners to compare them, but to use them as a starting reference point and identify major innovations that COSIGN architecture may bring to future DCNs. Starting from these previous analysis, the document describes possible data plane network architecture designs. The document describes a set of physical layer scenarios for the short, medium, and long-term which rely on novel features and optical technologies, that are being developed under the WP2 umbrella. In terms of control plane, a layered architecture has been proposed defining the functional blocks and interfaces and also explaining the innovation items which brings into scene. The complete control plane architecture specification and implementation is in the scope of WP3. In order to complete the full picture, the document also describes a preliminary version of the orchestrator (to be further developed in WP4) and the service and application layers. A first version of the interfaces between the different COSIGN architecture layers is provided too. Finally, based on the architecture design and the proposed use cases, it is provided the description of the COSIGN service delivery model specifying roles, actors and phases. The service delivery model justifies the whole COSIGN ecosystem, putting together the use cases, the requirements and the proposed architecture design .
Architecture Design. Task – Frontend Architecture Outline of the logical and physical structure of the Web-Application’s user-side interfaces. Task – Backend Architecture Outline of the logical and physical structure of the Web-Application’s backend administrative interfaces. Task – Database Architecture Data model phase in which the tables, fields, indexes, and relationships of the database are established.
Architecture Design. This Task investigated emerging architectures in European projects as well as novel extensions to those architectures. The design of the overall IoT Lab architecture also considers the requirements coming from Task 1.1. WP1 coordinates and aligns the overall strategy and facilitates activities for the overall project.
Architecture Design. This section is targeted to to describe the modelling methodology applicable to the three phases of an eDIANA platform architecture design, namely, the Application Architecture Design phase, the Platform Architecture Design phase and the System Allocation phase. The models involved in each of these phases will be explained in terms of views, modelling languages, etc. and a set of modelling guidelines and constraints will be given. In order to develop a completely coherent model-driven development framework, it is necessary to constrain the modelling languages to a subset in order to enable the reusability of the model transformation engines, e.g. to connect system designs with analysis tools. Lastly, eDIANA specific components will be addressed in the methodology framework in order to ease the designers’ job to use this modelling methodology.
Architecture Design. Work Package WP 3.1, Architecture Design Lead Author (Org) Xxxxxx Xxxxxxxxx (Do IT Systems) & Xxxxx Xxxx (UCit) Contributing Author(s) (Org) Xxxxxxx Xxxxxxxxxxx (UCit), Xxxxxxxx Xxxxxxxx (UCit), Xxxxxx Xxxxxxxx (UCit), Xxxx Xxxxxx (HPCNow!), Xxxxxx Xxxxxxxx (BSC), Xxxxxx Xxxx (UCit) Reviewed by Xxx Xxxxxxxxx (HPCNow!), Xxxx Xxxxxx (HPCNow!), Xxxxxxx Xxxxxxxx (UCit), Xxxxxxxx Xxxxxxx (UCit) Approved by Management Board Due Date 31.08.2021 Date 03.09.2021 Version V4.0 Dissemination Level X PU: Public PP: Restricted to other program participants (including the Commission) RE: Restricted to a group specified by the consortium (including the Commission) CO: Confidential, only for members of the consortium (including the Commission) Versioning and contribution history Version Date Author Notes
