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We're here to help you find itThe Aruba Certified Design Professional (ACDP) - Designing Aruba Solutions course is a comprehensive training program designed to equip learners with the necessary skills to design Aruba-based wireless and wired network solutions. The course covers a wide range of topics from understanding customer requirements to RF planning, Campus design, Network Security, VLANs, Redundancy, QoS, High-density environments, Branch networking, and Network management.
Through a series of modules, participants will delve into the specifics of stakeholder expectations, network usage, application bandwidth needs, security compliance, and roaming requirements. Additionally, they will gain hands-on experience with RF fundamentals, Site surveys, Aruba campus WLAN architecture, Controller scaling, License selection, VLAN planning, Redundancy strategies, and Traffic prioritization.
By completing the course, learners will be well-prepared to tackle real-world networking challenges, making them valuable assets in the design and implementation of Aruba solutions. The Aruba Certified Design Professional certification demonstrates their expertise and commitment to excellence in the field.
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You can request classroom training in any city on any date by Requesting More Information
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To successfully undertake training in the Aruba Certified Design Professional (ACDP) - Designing Aruba Solutions course, the following prerequisites are recommended:
These prerequisites are intended to provide a solid foundation that will help you maximize the benefits of the ACDP course. However, individuals with a strong desire to learn and a commitment to understanding the material can also succeed in this course.
The Aruba Certified Design Professional (ACDP) course equips IT professionals with advanced skills in designing Aruba solutions, tailored for network architects and engineers.
The Aruba Certified Design Professional (ACDP) course equips students with the expertise to design robust Aruba solutions, focusing on RF planning, campus design, security, and network management.
Identify Customer Requirements:
RF Planning:
Aruba Campus Design:
Wired Network Design:
VLANs and Network Segmentation:
Redundancy Planning:
Quality of Service (QoS):
High-Density Network Design:
Branch and SMB Networking:
By completing the course, students will be able to design tailored Aruba solutions that meet specific business needs while ensuring high performance, security, and scalability.
RF planning is the process used by telecommunications engineers to design and optimize radio frequency (RF) networks, such as cellular networks. It involves determining the best locations and parameters for antennas to ensure wide coverage and strong signal quality while minimizing interference and cost. Effective RF planning maximizes network performance and improves user experience by ensuring reliable communication and data transfer over wireless systems. This process utilizes various software tools and analytical methodologies to strategically place network elements and meet regulatory and technical standards.
Campus design in networking refers to the architecture used to interconnect computers and devices within a geographic area such as a university, corporate site, or interconnected buildings. This design supports efficient and secure communication across various parts of the campus. It often includes multiple local area networks (LANs) connected via switches and routers, focusing on optimal traffic management, scalability, and redundancy to ensure consistent network performance and reliability. Effective campus design is crucial for handling the breadth of modern network demands, embracing principles like fault tolerance and high availability.
Network security is a set of technologies and practices designed to protect a computer network from unauthorized access, attacks, and data breaches. It involves implementing both hardware and software solutions to secure the network infrastructure and data flowing through it. Key practices include using firewalls, antivirus software, and intrusion detection systems to monitor and prevent potential threats. Effective network security ensures that sensitive information is kept safe, provides reliable access to data and resources for authorized users, and protects against cyber threats such as malware and ransomware.
VLANs, or Virtual Local Area Networks, are a technology used to divide a single physical network into multiple virtual networks. This separation allows for better organization, security, and management of network resources. By creating VLANs, network administrators can control traffic within a network by grouping devices with similar functions or requirements, thereby enhancing performance and security. Each VLAN acts as its own separate network, though all VLANs can coexist on the same physical infrastructure, simplifying network design and reducing hardware costs.
Redundancy in technology refers to the duplication of critical components or functions of a system with the intention of increasing reliability of the system, ensuring that if one part fails, another can take over immediately. This strategy is crucial for maintaining operations without interruption, thereby enhancing system resilience and availability. Commonly used in data centres, networks, and cloud applications, redundancy helps mitigate risks and prevent system failures by providing a backup that can seamlessly execute tasks when needed.
High-density environments refer to spaces where there are numerous devices or users connected to a network within a small area. In such environments, managing network efficiency and reliability is crucial due to the high volume of data traffic and potential interference between devices. Technologies and strategies are used to optimize connectivity, such as advanced Wi-Fi solutions and network design principles that ensure bandwidth allocation, reduce delays, and maintain consistent communication quality. These environments are common in places like stadiums, airports, and large office buildings, where smooth network performance is critical for user satisfaction and operational success.
Branch networking refers to the technology and systems used to connect and manage different remote offices, or "branches," of a larger company back to a central corporate network. These connections allow for secure, reliable communication paths and help in managing the organization's resources more efficiently. By using modern networking technologies, companies can ensure that their branch offices have fast, consistent access to the applications, data, and services hosted at the central headquarters, improving overall operational efficiency and collaboration among geographically dispersed teams.
Network management involves overseeing, controlling, and maintaining a computer network, ensuring it operates smoothly and efficiently. This includes tasks like monitoring network performance, ensuring network security, troubleshooting issues, and managing network resources. Administrators or network managers use various tools and strategies to handle these responsibilities, aiming to provide uninterrupted service and support to all network users. Effective network management helps in reducing downtime, improving system reliability, and enhancing the performance of network-connected devices and applications.
RF fundamentals or Radio Frequency fundamentals refer to the basic concepts and technologies used in transmitting and receiving information via radio waves. This includes understanding how radio waves are generated, their properties (such as frequency and wavelength), and how they are used to transmit data across distances without physical connections. Key aspects include modulation, which is changing the wave to encode information, and antenna design, crucial for effective signal transmission and reception. Mastery of RF fundamentals is essential in designing and troubleshooting wireless networks and systems, a skill that’s crucial for technicians and engineers in telecommunications.
A site survey is an assessment conducted to plan and design an efficient network layout. It typically involves examining a location to identify potential challenges and resources available for network installation. This process helps ensure optimal placement of routers, access points, and other networking equipment to maximize coverage and performance while minimizing interference and signal loss. Site surveys are crucial for creating effective wireless networks in various environments, catering to the specific needs of each site for seamless connectivity and enhanced user experience.
The Aruba campus WLAN architecture is a design for wireless local area networks in academic or corporate campuses. It uses centralized management to optimize both coverage and performance, ensuring consistent connectivity across large spaces. This architecture supports advanced features like seamless roaming, high security, and scalability, adapting to the varying number of users and their demands. Aruba's solutions are known for their reliability and ease of use, making them a popular choice for institutions seeking robust wireless network capabilities. This setup benefits from Aruba's intelligent software that proactively manages network health and traffic distribution.
Controller scaling refers to the process of adjusting the capacity of a network controller to manage increased load and traffic without sacrificing performance or reliability. As the size and complexity of networks grow, especially in environments certified with standards such as Aruba Certified Design Professional, it becomes crucial to enhance controller capabilities to efficiently handle more devices and higher data volumes. This scaling can be achieved through hardware upgrades, software enhancements, or by deploying additional controllers to distribute the workload more evenly across the network.
License selection involves choosing the appropriate software license that aligns with your project requirements and compliance needs. This process includes evaluating whether a license should be proprietary, offering exclusive rights, or open-source, which permits users to modify and share the software. Key considerations typically involve understanding the legal implications, distribution rights, and obligations you must fulfill. Proper license selection ensures your use of software adheres to legal standards, protects intellectual property, and aligns with your business or project objectives. Make informed choices to avoid potential legal issues and to support your project's development and distribution efficiently.
VLAN planning involves organizing a network into multiple broadcast domains by configuring Virtual Local Area Networks (VLANs). This strategy enhances network performance and security by segmenting network traffic based on factors like function, team, or project. Effective VLAN planning requires analyzing the current and future network use cases, understanding the physical layout of the connected devices, and setting up rules that dictate how data moves across different parts of the network. Properly implemented, VLANs can ensure smoother, safer, and more efficient network operations by limiting unnecessary data transmission and potential access breaches.
Redundancy strategies in technology involve creating duplicates of critical components or systems to ensure that if one part fails, another can immediately take its place with no interruption. This approach is crucial for maintaining continuous service and protecting data. Common redundancy methods include using multiple hardware devices, creating software duplicates, and implementing failover processes, where one system seamlessly takes over from another if the primary system encounters issues. Redundancy is essential for high availability and is widely adopted in network designs, data centers, and critical computing environments.
Traffic prioritization is the process of arranging network traffic in a way that ensures more important or sensitive data, like live video streams or critical system updates, gets higher priority over less urgent data. This management reduces buffering, improves response times, and enhances the overall performance of a network by ensuring top priority tasks receive the bandwidth and speed they require. This is crucial in environments where multiple tasks compete for limited network resources, helping to maintain efficient workflow and user satisfaction.
The Aruba Certified Design Professional (ACDP) course equips IT professionals with advanced skills in designing Aruba solutions, tailored for network architects and engineers.
The Aruba Certified Design Professional (ACDP) course equips students with the expertise to design robust Aruba solutions, focusing on RF planning, campus design, security, and network management.
Identify Customer Requirements:
RF Planning:
Aruba Campus Design:
Wired Network Design:
VLANs and Network Segmentation:
Redundancy Planning:
Quality of Service (QoS):
High-Density Network Design:
Branch and SMB Networking:
By completing the course, students will be able to design tailored Aruba solutions that meet specific business needs while ensuring high performance, security, and scalability.
