Integrative Network Design Project NT C362 Version 11 Univer ✓ Solved

Integrative Network Design Projectntc362 Version 11university Of Phoe

Integrative Network Design Project NTC/362 Version University of Phoenix Material Integrative Network Design Project The integrative network design project (INDP) combines key features of a design approach and considerations, network and data configuration, and hardware and software configuration. Students must apply and demonstrate an understanding of those features to the complete design of a network meeting prescribed performance requirements. This project consists of a series of assignments and culminates with the INDP. Select one of the following businesses from the University of Phoenix Virtual Organizations: Option 1: Riordan Manufacturing Option 2: Kudler Fine Foods (KFF) Option 3: Patton-Fuller Community Hospital Option 1: Riordan Manufacturing · Integrate all locations with common wide area network (WAN) protocols. · Convert the administration networks in each plant to wireless local area networks (WLANs). · Bring voice over Internet protocol (VOIP) to the entire corporation, and decide on what protocols are needed in the satellite link between San Jose and China to support a symmetrical 10 megabits per second (Mbps) connection, real time required, with a quality of service equivalent to a circuit switched data link. Option 2: Kudler Fine Foods (KFF) · Design a WAN to tie all three KFF locations together. Make the internal network configuration in each store a WLAN, and add VOIP to the multi-store network. · Define which store will house the central servers. · Design the network to be expandable beyond the existing stores. Option 3: Patton-Fuller Community Hospital · Convert the administration network to a WLAN, install VOIP in the hospital, and design a high-speed WAN, which will allow PF to connect to three other local hospitals. This configuration will also allow their 15 radiologists two-way high-speed, of at least 20 Mbps, communications to and from their homes. · Include the high-speed links to the doctor’s homes. · PF has an entire environment hosting Macintosh® computers.

Sample Paper For Above instruction

Introduction

The rapidly evolving landscape of healthcare and corporate business demands robust, scalable, and secure networking infrastructures. The design of such networks must incorporate advanced technologies to ensure seamless integration, real-time communication, and future growth. This paper focuses on designing an optimal network architecture for Patton-Fuller Community Hospital (PF), considering its unique operational needs, hardware environment, and the critical requirement for high-speed connectivity with satellite hospitals and remote radiologists. The objective is to develop an integrated network plan that prioritizes performance, security, and scalability while addressing the hospital’s specific technological constraints and business objectives.

Network Design Goals and Requirements

The primary goal of this network design is to enhance PF’s connectivity and operational efficiency. The key requirements include a high-speed WAN connection, wireless local area networks (WLANs) within the hospital, VOIP integration, and secure, reliable links to remote hospital and radiologist locations. Given the prevalence of Macintosh computers within PF’s environment, compatibility and seamless interoperability are essential. Additionally, the design must ensure minimal latency, high availability, and encryption to safeguard sensitive medical data.

Design Components

• Wireless Local Area Network (WLAN): Converting PF’s administration network to WLAN entails deploying enterprise-grade access points throughout hospital areas, administrative offices, and patient care zones. This transition facilitates mobility for staff and enhances communication efficiency.
• High-Speed Wide Area Network (WAN): The WAN must connect PF to three neighboring hospitals via dedicated high-speed links, ensuring fast data exchange for patient records, imaging, and administrative data. The links should support a minimum bandwidth of 100 Mbps—preferably 1 Gbps—to accommodate large data transfers and real-time applications.
• Satellite Links: The satellite link connecting San Jose and China should support a symmetrical 10 Mbps connection with quality of service (QoS) guarantees. Protocols such as MPLS or VPN tunneling should be employed to ensure security and reliable transmission, supporting real-time data and voice traffic.
• VOIP Integration: Implementing VOIP across the network allows cost-effective communication within the hospital and with remote locations. SIP and RTP protocols can be used for voice traffic, with prioritization ensured through QoS mechanisms.
• Compatibility with Macintosh Systems: Network hardware and management tools must be compatible with Macintosh operating systems, accommodating all existing equipment within PF.

Security Considerations

Security remains paramount, especially given the sensitivity of healthcare data. The network design incorporates WPA3 encryption for WLANs, VPN tunnels for external links, and robust firewalls at each entry point. Intrusion detection and prevention systems (IDS/IPS) will monitor for suspicious activity, and multi-factor authentication (MFA) will secure administrative access.

Scalability and Future Expansion

To future-proof the network, fiber optic cabling is recommended for backbone connections, facilitating scalability. Modular wireless access points and switch infrastructure allow incremental upgrades. Additionally, the network design supports virtual LANs (VLANs) to segment traffic, improving security and performance as demands evolve.

Conclusion

The proposed network design for Patton-Fuller Community Hospital integrates high-speed WAN connections, WLAN deployment, VOIP, and secure satellite links. This architecture aligns with PF’s operational needs, supports Macintosh compatibility, and provides a foundation for scalable growth. By leveraging current technologies and best practices, PF can achieve enhanced communication, data security, and operational efficiency, ultimately improving patient care and administrative effectiveness.

References

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• Jewkes, J. (2020). Healthcare Networking Technologies. Healthcare IT Journal, 15(3), 24-30.
• Ross, R. (2018). High-Speed Network Design for Healthcare. Journal of Network Engineering, 5(2), 45-52.
• Microsoft Docs. (2022). Secure Network Design Considerations for Healthcare. Microsoft.
• Sharma, S. (2020). Wireless LAN Deployment Strategies. Journal of Wireless Communications, 8(4), 102-110.
• International Telecommunication Union. (2021). Guidelines for Satellite Communication in Healthcare. ITU Publications.
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