Construction Of A Network Infrastructure For A New Office

Construction of a Network Infrastructure for a New Office Facility

Congratulations, you have been chosen to build out a network for a new facility for your company, ACME, Inc. Office Schematic, (select (Picture of office will be in uploaded files) * ) each office is approximately a 10'x10' space with 10' ceilings. Building is roughly 125'x150'. Each office should contain two network ports minimum, one for Voice and one for Data.

Room B will serve as your network closet. You will need to provide the following items in your submission: Estimated Purchases list (some examples below) Switches Cable Port plates Punch Boards UPS and Power Etc. A timeline of installation (estimated) Chosen Typology (estimated) Basic Network configuration (estimated) Remember to justify your choices. Your proposal should answer the questions above. If you have experience in networking, there are additional things you would "want", but hold on those till later assignments, as the assignments build upon one another. NOTE* This means you may reuse information from this assignment in future assignments as well, and I am granting you a waiver of not citing yourself in those assignments.

Paper For Above instruction

The successful implementation of a network infrastructure within a new office facility requires meticulous planning, strategic selection of hardware and topology, and precise scheduling. This paper provides an estimated timeline, the adopted network typology, and the basic network configuration for ACME, Inc.'s new office layout, justified by industry standards and best practices.

Estimated Timeline of Installation

The installation timeline is projected over four weeks, with preparation, procurement, and installation phases. The first week will be dedicated to site inspection, layout finalization, and procurement of networking hardware. Weeks 2 and 3 will focus on physical cabling installation, port plate setup, and switch deployment. The final week involves configuration, testing, and troubleshooting to ensure network integrity and performance. This timeline allows for coordinating with vendors and ensuring minimal disruption to ongoing office setup activities.

Chosen Network Topology

The network topology selected is a star configuration, which is ideal for office environments due to its scalability, ease of management, and fault containment. In this topology, each office connects directly to a central network switch in Room B, functioning as the network closet. The star topology allows for straightforward additions or relocations of offices without impacting the entire network. Its fault tolerance is enhanced by ring or redundant links, but for simplicity and cost, a single-star configuration suffices for this deployment.

Basic Network Configuration

The network will utilize gigabit Ethernet switches at the core, with fiber optic uplinks for high-speed interconnection between the main switch in Room B and the edge switches located within the offices. Each office will have at least two Ethernet ports—one designated for voice (VoIP phone) and the other for data, connected to the central switch. The network will implement VLANs for separating voice and data traffic to enhance security and Quality of Service (QoS). A DHCP server will dynamically assign IP addresses, and the network will be secured via WPA2 encryption for wireless components, if applicable. Power over Ethernet (PoE) capability will be incorporated into switches designated for VoIP to simplify installation and management.

Justification of Choices

The star topology ensures that a failure in one connection does not compromise the entire network, facilitating easier troubleshooting and maintenance. Gigabit Ethernet provides sufficient bandwidth for typical office activities, including VoIP and data transfers, ensuring smooth operation. Fiber optic uplinks future-proof the network by supporting higher bandwidth demands and redundancy. VLAN segmentation enhances security and traffic management, critical in a corporate environment. PoE switches reduce cabling complexity and provide power to VoIP IP phones, which simplifies the deployment process and reduces overall costs.

Estimated Purchase List

• Gigabit Ethernet Switches with PoE support
• Fiber optic cabling and connectors
• Category 6 Ethernet cables
• Wall-mounted Cable Port Plates
• Punch-down blocks and patch panels
• Uninterruptible Power Supplies (UPS)
• Rack-mounted network cabinets
• Power strips and cable management accessories
• VoIP phones
• Networking tools (crimpers, testers)

Conclusion

This network installation plan for ACME, Inc. balances cost, performance, and scalability. The star topology with gigabit switches and fiber backbone ensures robust, high-speed connectivity. The proposed timeline minimizes disruption and ensures timely deployment, while the configurations support current and future needs. Justifying each choice ensures alignment with industry best practices, which will facilitate a reliable and manageable network environment.

References

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