Multiservice Provisioning Platform Market Poised to Grow at a Robust Pace Owing to Increasing Demand

Market Overview The multiservice provisioning platform market allows operators to deliver a variety of telecommunication services such as voice, data, and multimedia over a single network infrastructure. The platform enables service providers to seamlessly roll out new converged data, voice and multimedia services for residential and business customers. It offers a simplified and automated approach for adding new connection types and innovative service bundles. Leveraging software-defined networking and virtualization technologies, multiservice provisioning platforms help operators maximize resource utilization, simplify operations and improve time-to-market for new services.

Global multiservice provisioning platform market is estimated to be valued at USD 47.83 Bn in 2024 and is expected to reach USD 65.27 Bn by 2031, exhibiting a compound annual growth rate (CAGR) of 4.5% from 2024 to 2031.

Key Takeaways Key players operating in the multiservice provisioning platform market are Alcatel SA, Ciena Corporation, Cisco Systems Inc., ECI Telecom Ltd., Ericsson, Fujitsu Network Communications Inc., Lucent Technologies Inc., Marconi Corporation plc. The Multiservice Provisioning Platform Market Size  is expected to witness growing opportunities due to increasing demand for cloud-based, software-defined and virtualized services. Multiservice provisioning platforms enable simplified, automated and unified delivery of various digital services including voice, data, content, mobility and smart home solutions. Globally, North America dominates the multiservice provisioning platform market currently. However, Asia Pacific is anticipated to witness the highest growth over the forecast period supported by rapid infrastructure development, 5G deployment and growing population. Major players are focused on expansion opportunities in emerging economies through partnerships and collaborations. Market Drivers The increasing demand for convergence services is a major growth driver for this market. Customers expect seamless access to different services through multiple devices. Multiservice provisioning platforms allow telecom operators to offer innovative converged service bundles across different technologies through a single solution. Multiservice Provisioning Platform Market Size and Trends simplifies operations and improves customer experience. Multiservice provisioning platforms also help operators maximize infrastructure utilization and monetize existing network assets through efficient rollout of new services.

PEST Analysis Political: The globalization and emergence of multinational corporations has led many nations to form regulations and policies encouraging digitalization and connectivity. This has positively impacted the adoption of multiservice provisioning platforms. Economic: Growing economies worldwide have increased spending on network infrastructure. Telecom operators are investing significantly in upgrading legacy systems to keep pace with rising data usage and demand for high-speed networks. This presents opportunities for multiservice provisioning platform providers. Social: Widespread internet and smartphone adoption have changed consumer behavior and preferences. People now demand high-speed reliable connectivity for accessing real-time entertainment, social media, and collaboration tools from anywhere. This has accelerated the need for platforms offering centralized operations. Technological: Emerging technologies like 5G, IoT, and edge computing require more flexible, software-defined infrastructure that can rapidly deploy new services. Multiservice provisioning platforms allow dynamic service creation, integration and optimization across physical and virtual networks through open APIs and SDN/NFV principles. The market in terms of value is concentrated primarily in North America and Western Europe. This is due to high mobile and broadband penetration along with major telecom operators headquartered in these regions who are leading adopters for modernizing their networks. The Asia Pacific region, especially countries like China and India, presents the fastest growth opportunity. Rapid digitalization initiatives by governments coupled with increasing consumer demand for broadband and rising smartphone usage are driving massive network investments. Key telecom firms view multiservice platforms as strategic to handle exponentially rising data traffic and support new technologies.

Get more insights on Multiservice Provisioning Platform Market

For Deeper Insights, Find the Report in the Language that You want

French

German

Italian

Russian

Japanese

Chinese

Korean

Portuguese

Priya Pandey is a dynamic and passionate editor with over three years of expertise in content editing and proofreading. Holding a bachelor's degree in biotechnology, Priya has a knack for making the content engaging. Her diverse portfolio includes editing documents across different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. Priya's meticulous attention to detail and commitment to excellence make her an invaluable asset in the world of content creation and refinement.

(LinkedIn- https://www.linkedin.com/in/priya-pandey-8417a8173/)

The Multiservice Provisioning Platform (MSPP) Market is projected to grow from USD 47,795 million in 2024 to USD 65,915.61 million by 2032, reflecting a compound annual growth rate (CAGR) of 4.1% over the forecast period. The Multiservice Provisioning Platform (MSPP) market plays a critical role in modern telecommunications, enabling the convergence of various services such as voice, data, and video onto a single network infrastructure. These platforms offer service providers the ability to efficiently manage multiple communication services across a unified network, reducing costs, increasing network flexibility, and improving scalability. As the demand for higher bandwidth and more efficient network management grows, the MSPP market is poised for significant expansion.

Browse the full report at https://www.credenceresearch.com/report/multiservice-provisioning-platform-market

Understanding Multiservice Provisioning Platforms (MSPP)

Multiservice Provisioning Platforms are network devices that integrate various transport technologies such as Synchronous Optical Networking (SONET), Synchronous Digital Hierarchy (SDH), and Ethernet. They allow for the transmission of different types of services, such as internet, telephony, and video streaming, over a single physical infrastructure. This integration not only simplifies network management but also enhances the efficiency and reliability of the communication network.

The primary functions of MSPPs include the aggregation, switching, and routing of traffic across different network layers. These platforms enable service providers to deliver multiple services over a common infrastructure, reducing the need for separate networks dedicated to each type of service. By converging services, MSPPs help reduce operational costs, improve service delivery times, and enable rapid deployment of new services.

Market Growth Drivers

1. Increasing Demand for High-Speed Internet

With the rapid expansion of cloud computing, IoT devices, and the proliferation of data-driven applications, the demand for high-speed internet is increasing at an unprecedented rate. Enterprises and consumers alike expect fast, reliable internet connections capable of supporting bandwidth-intensive applications. MSPPs are critical in this context, as they allow service providers to deliver high-speed broadband over existing infrastructures while also supporting the integration of future technologies such as 5G.

2. Rise of 5G Networks

The deployment of 5G networks is a significant driver for the MSPP market. 5G promises faster speeds, lower latency, and support for a massive number of connected devices. As service providers upgrade their networks to accommodate 5G, the need for scalable, flexible platforms like MSPPs becomes crucial. These platforms enable the smooth transition from legacy network technologies to next-generation solutions, facilitating the deployment of 5G services.

3. Cost Efficiency and Network Optimization

The cost-efficiency offered by MSPPs is another key driver of market growth. By enabling the convergence of various services onto a single platform, service providers can optimize their network resources and reduce the need for expensive hardware. This consolidation reduces both capital and operational expenditures, making it an attractive proposition for telecommunication companies and internet service providers looking to optimize their infrastructure investments.

4. Growing Need for Enhanced Security

As networks grow more complex and data traffic increases, ensuring the security of communication channels becomes more challenging. MSPPs offer enhanced security features, allowing service providers to manage multiple services securely over a single platform. This added layer of security is especially important in industries like finance, healthcare, and government, where the protection of sensitive data is paramount.

Market Challenges

While the MSPP market is experiencing growth, it is not without challenges. One major challenge is the competition from alternative technologies such as Packet-Optical Transport Systems (P-OTS), which offer similar functionalities. P-OTS systems are gaining popularity due to their ability to integrate packet and optical technologies more efficiently, thus posing a threat to the traditional MSPP market.

Another challenge is the high initial cost of deploying MSPP systems. While these platforms offer long-term cost savings, the upfront investment can be substantial, especially for smaller service providers. This can slow down the adoption of MSPPs in some regions, particularly in developing markets.

Future Outlook

The future of the MSPP market looks promising, driven by advancements in network technologies and the increasing demand for high-speed, secure communication services. The transition to 5G and the growing emphasis on cloud computing and IoT will continue to fuel the demand for multiservice provisioning platforms.

Key Player Analysis:

Cisco Systems, Inc.

Juniper Networks, Inc.

Alcatel-Lucent (acquired by Nokia)

Ciena Corporation

Huawei Technologies Co., Ltd.

Fujitsu Limited

Ericsson AB

NEC Corporation

ZTE Corporation

Infinera Corporation

Segmentations:

By Component

Hardware

Software

Services

By Deployment

On-premises

Cloud-based

By End User

Telecommunications Service Providers

Internet Service Providers (ISPs)

Enterprises

Others

By Region

North America

The U.S

Canada

Mexico

Europe

Germany

France

The U.K.

Italy

Spain

Rest of Europe

Asia Pacific

China

Japan

India

South Korea

South-east Asia

Rest of Asia Pacific

Latin America

Brazil

Argentina

Rest of Latin America

Middle East & Africa

GCC Countries

South Africa

Rest of Middle East and Africa

Browse the full report at https://www.credenceresearch.com/report/multiservice-provisioning-platform-market

About Us:

Credence Research is committed to employee well-being and productivity. Following the COVID-19 pandemic, we have implemented a permanent work-from-home policy for all employees.

Contact:

Credence Research

Please contact us at +91 6232 49 3207

Email: [email protected]

Website: www.credenceresearch.com

CTE NEXT in Torino

*Machine translated.

https://www.torinocitylab.it/it/update-to/cte-next

Description of the project

The project, launched on 1 March 2021 and lasting four years, will promote the acceleration of start-ups and technology transfer towards SMEs.

The goal of CTE NEXT is to create in Turin, in close collaboration with the Turin universities and other strategic partners - selected from the relevant and competent partners of Torino City Lab - a  center for widespread technology transfer on emerging technologies enabled by 5G ( IoT, Big Data, Artificial Intelligence, Blockchain) .

The City has in fact identified 4 strategic vertical sectors for development and innovation on which the lines of action of the CTE and business support services will address:

Smart Road

Innovative solutions enabling advanced, safe and intelligent mobility, from connected vehicles to V2X communications, from integration with mobility scenarios to algorithms for autonomous driving.

Urban Air Mobility. (((drones, because Turin loves those)))

Innovative solutions to enable the use of aerial platforms to support sustainable and safe mobility of goods and people, from monitoring and control applications to their integration as means of transport.

Industry 4.0

Innovative solutions to connect machines, objects, resources and people in the production environment and along the company supply chain, along the entire life cycle of the product / service, to improve the effectiveness and efficiency of production but also of relations with suppliers and customers.

Innovative Urban Services

Innovative solutions to support the Public Administration, for the provision of services to citizens, the management of resources, goods and public spaces, the enhancement of the territory and the development of business from public-private collaboration.

The places of the CTE NEXT

Within the broader framework of Torino City Lab, the innovation policy of the City of Turin, an attractive and generative environment will be created for start-ups and SMEs from abroad, promoting services and acceleration programs for start-ups (or aspiring enterprises), technology transfer services aimed at SMEs and in general support for testing in real conditions. 

CTE NEXT will therefore make available places, assets and skills spread throughout the territory, including a multiservice technological infrastructure that can be used on-demand by companies and partners for the needs of development and demonstration of innovative solutions in the various verticals.

With CTE NEXT, the City of Turin aims to propose a new cooperative model of urban innovation ecosystem, which can be transferred to other urban contexts on a national and European scale and consequently create new forms of collaboration and new markets for businesses. and the innovative urban solutions accompanied in Turin. CTE NEXT will be able to generate a measurable fallout in terms of new businesses, new jobs, new widespread skills and new urban services enabled by 5G tested and therefore ready to enter our cities.

The partners

Municipality of Turin Polytechnic of Turin University of Turin Links Foundation CIM 4.0 I3P CSI PIEDMONT 5T srl Torino Wireless Digital Magics Talent Garden Foundation TIM SpA

Ons-xc-10g-ep58

ONS-XC-10G-EP58.1

ONS-XC-10G-EP58.1 Cisco Edge Performance - LC Single-Mode XFP Transceiver for ONS 15454 SONET Multiservice Provisioning Platform - 10 GBPS.

General Information Manufacturer Cisco Systems, Inc Manufacturer Part Number ONS-XC-10G-EP58.1 Manufacturer Website Address http://www.cisco.com Brand Name Cisco Product Model ONS-XC-10G-EP58.1= Product Name XFP Transceiver Module Product Type XFP Technical Information Application/Usage Data Networking Application/Usage Optical Network Interfaces/Ports Interfaces/Ports Details 1 x LC Duplex OC-192/STM-64 Network Media Performance Media Type Supported Optical Fiber Fiber Mode Supported Single-mode Network Technology OC-192/STM-64 Maximum Data Transfer Rate 10 Gbit/s Miscellaneous Compatibility Cisco ONS 15400 Series

Click to buy: Ons-xc-10g-ep58 from Mac Palace Products Feed https://ift.tt/2PkOLoU

JDSU Acterna FST-2310 Test Pad

Welcome to a Biomedical Battery specialist of the Acterna Battery

The FST-2310 TestPad with battery such as Agilent E6000A E6000B E6000C Adapter, Li202S Li202SX ME202C M4605A SM204 MTS-6000 LI204SX JD1600LP Battery Charger Adapter, Agilent E6000A E6000B E6000C Adapter, Li202S-60A Battery, Li202S-66C Battery, Li202S Battery, Li202S-6600 Battery, Li202SX Battery, Li202SX-7800 Battery, JDSU LI204SX Battery, JDSU MTS-6000 Battery, GE SM201-6 Battery has put the power to provision, troubleshoot, and maintain DS0 to OC-48 services in your hands, minimizing lost revenue on your network.

Highlights: * Comprehensive testing with multirates, multiservices, and multimodes. * Easy-to-use, touch-screen graphical user interface (GUI) simplifies and expedites testing. * Engineered for the field with rugged construction, lightweight design, and battery-powered operation. * Modular TestPad 2000 architecture enables up-to-date support for established and emerging technologies in a single platform. * Automated testing features minimize training costs and testing complexity. * Remote control functionality using the module's GUI.

Applications: * Perform end-to-end BER testing using a wide range of stress test patterns. * Analyze network performance by simulating abnormal conditions and inserting various errors and alarms. * Perform in-service monitoring of the circuit under test to ensure Quality of Service (QoS). * Verify proper provisioning of network multiplexers and demultiplexers. * Verify proper network timing by measuring jitter at DS1 and DS3 tributary interfaces. * Qualify protocol services such as ATM, GR-303, and ISDN and decode protocol messages. * Perform bulk payload testing on SDH circuits at STM-1c/-4c/-16c rates.

COIT20265 | Capstone Project Case Study | Networks and Information Security Project

The First National University (FNU) Background

The First National University (FNU) is a major public higher education institution. It was the first higher education institution in the country to launch distance education and more recently online programs. Apart from its main Campus, the University has operations in five (5) regional campuses (RCs) and ten (10) metropolitan campuses (MCs). At present, FNU provides diverse range of undergraduate and postgraduate programs as well as Vocational and Educational Training (VET) and short professional programs.

More than 45,000 students are currently studying various levels of programs at FNU as on-campus students. Additionally, around 15,000 students are currently studying at FNU under the online and distance education programs.

FNU has three (3) major facilities to support its information technology services, namely, Headquarters, Operations (Data Centre) and Backup. The Headquarters facility is located in the main Campus. The Operations facility is located 50Kms from the Headquarters in a warehouse the University owns near an industrial area. The Operations facility houses the back-office technical functions, the Data Centre, and the IT staff. The Backup facility is located in the country area about 1000km from the headquarters. FNU uses the Backup facility as a warm-site facility that can be operational within minutes in the event the Operations facility fails.

Apart from the main campus, all regional and metropolitan campuses are very similar in terms of size, staff, and technologies. Their IT infrastructure uses relatively old and complex technologies. FNU still uses a number of protocols to enable campus communication to the main server farm located at the Operations.

Each campus is connected to the university backbone through old Multiservice Platform Routers for flexible LAN and WAN configurations, easy upgrades, and the handling of various protocols at the internet and transport layers. The router enables the campus to communicate with different FNU campuses located in different sites.

To support the day-to-day learning and teaching activities, academics and administrative staff at FNU also deals with a dozen (12) of external partners including hospitals, research centres, vendor support, and technology partners in many different ways, non-necessarily compatible each other.

At FNU the current network has consistency, performance, and reliability problems owing to a growth in enrolments and recent operations expansion. The IT department has been informed about an increase in student and faculty complaints. Particularly, faculties and academic staff claim that owing to network problems, they cannot efficiently submit grades, maintain contact with colleagues at other campuses, keep up with research, and conduct their daily tasks. Similarly, students say they have submitted student work late due to network problems. Assignments submission has been problematic since the introduction of the online submission approach. Students complain that late submissions have impacted their grades badly. Despite the complaints about the network, faculty, academic staff, and students use of the network has almost tripled in the last three few years

Another issue at FNU is that there are no BYOD and Work-at-home (WAT) policies. This has become a focus of contention between the IT department, staff and students. The IT department is concerned about a number of rogue wireless ad-hoc access points often placed by students within the campus premises. The vast majority of staff, faculty and students agree that there is a need of implementing secure wireless and remote access including the WAT and BYOD policies. The evidence is overwhelming on the need to rethink the way network services are provided at FNU.

The senior management at FNU has identified a number of key business factors that need immediate attention:

Enrolment for both on-campus and distance education is to increase 50% in the next three

Improve faculty efficiency and allow academic staff to participate in more research projects with colleagues at other campuses and partner universities

Improve student support efficiency and eliminate problems with assignment online

As part of the BYOD policy, allow students, staff and visitors to the University to access the campus network and the Internet wirelessly using their mobile devices including notebooks, smartphones, and

As part of the WAT, allow students and staff to remotely access the campus network from

Secure the campus networks from

In response to the senior management call, the IT department at FNU developed a list of technical goals that should be implemented as soon as possible:

Redesign the current network including provision for wireless

Overhaul the IP addressing

Increase the bandwidth of the Internet connection to support new applications and the expanded use of current

Provide a secure, private wireless network for students, staff and visitors to access the campus network and the

Provide a network that offers a response time of less than a second for interactive applications.

Provide a network that is available approximately 99.9 percent of the time and offers an MTBF (mean-time-between-failure) of 6000 hours and an MTTR (mean-time-to- repair) of less than 90 minutes.

Provide security to protect the Internet connection and internal network from

Provide a network that can scale to support future expanded usage of multimedia applications including online

Automate the majority of the network tasks and services including plug and play, network configuration, network management, troubleshooting, network monitoring, resource sharing, load balancing, updates, and data backups.

Wide Area Networks (WANs) at FNU

Currently, FNU supports its wide area network operations using a mesh topology of three (3) Layer2 VPLS (Virtual Private LAN Service) point-to-point circuits. This mesh guarantees redundancy between the Headquarters, Operations (Data Centre), and Backup sites.

Each regional and metropolitan campus is also redundantly connected to the major facilities (links to Headquarters, Operations and Backup respectively) via Frame Relay permanent virtual circuits (PVC). Similarly, two separate frame relay Internet Service Providers (ISP) are used for redundant Internet access: one PVC via the main Campus (Headquarters) and the other PVC via the Backup site. The external partners are connected to FNU via DSL.

Campus Network in FNU (Main, Metro, and Regional Campuses)

Each FNU campus is supported by 100Base-TX Switched Ethernet LANs, and FNU is expecting to upgrade to more modern Switched Ethernets. Staff at FNU are distributed as follows:

250 employees including academic (x150), administrative (x50) and management staff (x50). There are about 2,000 on-campus students in each of the regional and metro

The main campus houses around 2,000 employees including academic (x1000); administrative (x500) and management staff (x500). Nearly 15,000 on-campus students are studying at the main

The Operations facility is also supported by 100Base-TX Switched Ethernet LANs. In the Operations facility, there are 100 engineers in charge of technical support of the data centre, networking, maintenance, and application development. The organisational and operational structure of the Backup facility is similar to the structure of the Operations facility.

Academic staff at the main campus, regional, and metro campuses teach courses in seven faculties, namely: arts and humanities, business, social sciences, mathematics, computer science, the physical sciences, and health sciences. The administrative staff handle admissions, student records, and other student operational functions. The management staff consists of human resources, senior management and information technology. Enrolment at FNU has almost tripled in the past three years; and the faculty and admin staff has doubled in size.

Each campus backbone (including main, regional and metro campuses) supports the operations of the seven faculties, management, and administrative staff. The following are the details of the IT infrastructure:

A high-end switch in each building is connected to a high-end Campus core switch in the campus backbone.

Within each building, 24-port Ethernet switches on each floor connect end user

Floor switches are connected to the high-end building

The 100Base-TX switches are layer-2 switches running the IEEE 802.1D Spanning Tree Protocol.

All devices are part of the same broadcast domain. All devices (except public servers) are part of the 192.168.0.0 internal network

Addressing for end-user hosts is accomplished with DHCP. A Windows server in the cluster located in the Operations facility acts as the DHCP

A Windows-based network management software package monitors the switches using SNMP and RMON. The software runs on a server in the cluster located in the Operations

FNU email and web servers use public addresses assigned by AARNET (Discuss with your mentor the allocation of these public addresses). The system also provides a DNS server that the FNU All these public servers are located in the Operations facility.

The Multiservice Platform router in each campus has a default route to the WAN and does not run a routing protocol.

Campus servers support for local file storage (students and staff) and data backups that are periodically transferred to the main data centre at the Operations Facility

The logical topology of the Operations facility is similar to the Campus backbone. The main difference is that the server farm with the public services (Web, email and file services) are housed in the Data Centre of this facility. The Multiservice Platform router at the Operations facility acts as a NAT-Firewall.

ICT infrastructure at Metro and Regional campusesHardware

Staff equipped with Desktop PCs running Windows 7 (dual monitors)

Staff PCs equipped with first generation headsets and webcams

4 networked Laser Printers in each faculty

10 computer labs, each equipped with 24 PCs running Windows and a printer

One Network Attachment Storage for local storage

100Base-TX Switched Ethernet

ICT infrastructure at Headquarters (main campus)Hardware

Staff equipped with Desktop PCs running Windows 10 (dual monitors)

Staff PCs equipped with latest generation headsets and webcams

20 networked Laser Printers (also capable of scanning and photocopying)

50 computer labs, each equipped with 24 Desktop PCs running Windows 10 and a printer

One Network Attachment Storage (NAS) for local storage

Staff equipped with VoIP video phones

100Base-TX Switched Ethernet

ICT infrastructure at Operations site

Operating systems: Combination of Windows and Linux servers

Staff equipped with Desktop PCs running Windows 8

All operational servers including file, web, mail, DHCP, DNS, Authentication, Blackboard, Domain Controllers, Database, SAN, Load Balancing and video streaming servers are concentrated in this facility. The Operations facility also contains the infrastructure to support FNU’s learning management and student information systems; and ERP services.

ICT infrastructure at Backup site

As mentioned, the Backup is a warm-site facility that can take over within minutes in the event that the Operations facility fails. The backup site infrastructure mirrors the Operations facility.

Problem Statement

FNU business processes rely on a combination of systems and services with a very complex ICT infrastructure. FNU academic board acknowledges this as major issue that could compromise FNU’s growth and sustainability. The senior executive argues that currently the University is spending a huge amount of money to maintain and integrate disparate and cumbersome systems, with little room to expand and improve services. FNU needs to change and re-provision the ICT infrastructure to provide high quality learning and teaching in the most cost-effective way.

As part of this change, the transition to interoperability should be achieved in a smooth manner while leveraging the latest advancements in network and information security infrastructure to guarantee “zero” problems. This might also include the migration of key university applications and services to the Cloud.

In terms of network and information security, the ICT infrastructure should safeguard appropriate access and use of resources; and ensure unauthorised and malicious internal and external network attacks are properly blocked. Network redundancy is currently achieved with the mesh topologies (VPLS and Frame Relay); however, nothing has been done in terms of security plans for both disaster recovery (DRP) and business continuity (BCP).

Statement of Works

Your task is to plan and implement a project to help FNU re-provision its ICT infrastructure in accordance with its rapidly changing needs. The project consists of three parts: network security plan, network redesign, and technology implementation.

Part 1: Network Security plan

The network security plan should include as minimum the following items:

Introduction outlining the importance of the plan and its purpose. Your introduction should also provide a brief description of the components of the proposed network security plan in terms of the First National University

Scope outlining the areas of the organisation that the Plan applies. The scope also relates to the breakdown of the tasks that are needed to make sure that the network is

Assumptions documenting any assumptions you have made in order to prepare the plan. There are things that might not be clear from the case study, hence you have either to consult with the mentor or assume them in a reasonable way with a clear

Clear and concise statements about what the Security Plan is designed to achieve. This statement must relate the business and technical goals of

Summary and analysis of the organisation’s risks, highlighting the current threats, challenges and vulnerabilities along with an assessment of current security environment and treatments in place. This is perhaps the most important component of the security plan. It includes the complete assessment of each of the network assets (computer hardware, PCs, servers, application and system software, network devices, employees, partners and the like) and its importance for the normal operation of the network

The analysis also investigates the vulnerabilities of each asset and its associated threat that might exploit those vulnerabilities.

Network Security policies to address all possible network attacks and vulnerabilities. Note that these policies address the likely issues that might occur during the transmission of the data through the

Information Security policies to address unauthorized and misappropriate use of FNU data and software applications. Note that these policies address the likely issues that might occur during the storage and processing of the

Disaster recovery and Business continuity

Security Strategies and Recommended controls including security policies. The recommended controls are the action points you are to put in place to mitigate the risks you uncovered as part of your risk

In practice, achieving total security in an organisation is impossible. Residual risks that remain after all possible (cost-effective) mitigation or treatment of risks should be taken into account. Your security plan should estimate, describe and rate these residual risks to guide the priorities for ongoing monitoring of

Resources for implementing the recommendation. This should include any type of resources like humans, communities of practice, quality audit groups, and the

You are advised to use the network security plan template posted in the Moodle site to ensure you address all required items (refer to the marking criteria).

Part 2: Network Redesign

The redesign should be justified in terms of scalability, availability, network performance, security, manageability, usability, adaptability, and affordability. To do this, you need to make a number of assumptions. For example, assume that a great number of University services operate 24/7. Other services are to operate from 6:00am to 8:00pm Monday to Friday. Other aspects to consider are user’s behaviour, type of applications and services, bandwidth requirements, and the like. Make sure you discuss this further with your team mates, mentor, and teacher.

Specifically, for this redesign take into account the following:

Traffic generated by the hosts: clients, servers, and backup

Appropriateness of WAN links to support current traffic and forecast

Appropriateness of wired LANs and Wireless LANs to support future

VLAN configuration.

Network devices including routers and switches at each site (wired and wireless); and the respective network protocols and quality of service

IP address allocation of each network and main network

Sub-netting to separate traffic.

Firewalls positioning and

Proxy

DMZ

Firewalls Access Control

Network diagram (logical and physical topologies).

You are advised to use the network redesign template posted in the Moodle site to ensure you address all required items (refer to the marking criteria).

Part 3: Security Technology Implementation

As part of the security technology implementation, and in line with the recommended controls mentioned above in the network security plan (item 9), you are required to document, implement, and test at least five (5) recommended controls. The following are some suggestions of security technologies you could implement:

Data backup and recovery technology including the procedures for backup and recovery. Note that there are NASs at the campuses to back up the data generated locally, however the vast majority of data is backed up to the File Servers in each campus and ultimately to the Operations facility through the WAN. You need to provide the strategy of the backup, technical details, specifications and functionalities of the recommended backup

A proper authentication system that takes care of highly secured roles and permissions to access, share, download, upload files and folders. This should include authentication for wireless and mobile services as well (according to WAT and BYOD policies). You need to provide the complete details of the recommended technology including the product and vendor

Services like File, Web (and secure Web), Mail (and secure Mail including spam email prevention), DHCP, DNS, Domain Controllers. For example, you may suggest Apache HTTT Server as the Web server software. If that is the case, then you must describe the full configuration of the Apache HTTP Server and the application architecture used to include the load balancer, replica web server, and data server (if you opt for a three-tier architecture for example). Again, you need to provide details of the software vendor and recommended hardware to run the

Hardening of servers described mentioned in section 3. All the services need to be hardened with products as recommended in the network security

Network security including DMZs, Firewalls, Intrusion Detection and Prevention Systems (IDSs and IPSs).

Security technologies 1 to 5 mentioned above are suggestions only. Discuss with your mentor and teacher any other options of your interest.

Proof of concept

As part of the project requirements, you are required to implement and test the recommended controls suggested in the security technology implementation section above. The solution should address current needs of FNU, including the installation of the software, configuration of the system, and developing of test cases to check the complete functionality of the system.

For the proof of concept, it is mandatory that you include the documented results (procedures and screen dumps) of various network security attacks tests (such as Network Penetration Test) as part of your final project report. You may use your choice of security software/tools (including freeware open software systems) and operating systems (Windows, Linux, or Ubuntu) in a virtualized environment to build and simulate the security tests. You are required to demonstrate your implementations at the end of the term.

You are advised to use the security technology implementation template posted in the Moodle site to ensure you address all required items (refer to the marking criteria).

Order Now