New 2024 Guaranteed Success with Dumpexams HPE6-A47 Dumps HP PDF Questions [Q12-Q28]

New 2024 Guaranteed Success with Dumpexams HPE6-A47 Dumps HP PDF Questions

Exceptional Practice To Aruba Certified Design Professional Exam Pass the First Time

NEW QUESTION # 12
Read this scenario thoroughly, and then answer each question that displays on the right side of the screen.
An architect proposes these products for a customer who wants a wireless and wired upgrade:
Aruba 2930M switches at the access layer
Aruba 5406R switches at the core
Aruba AP-325s
Aruba 7205 Mobility Controllers (MCs), deployed in a cluster
Aruba Mobility Master (MM)
Aruba ClearPass Cx000V
Aruba AirWare
The architect also needs to propose a security plan for the solution. The customer has 900 employees and up to
30 guests a day. The customer wants to protect the internal perimeter of the network with authentication and simple access controls. The customer is most concerned about wireless security, but also wants to ensure that only trusted users connect on the wire. However, the customer also wants all wired traffic to be forwarded locally on access layer switches. The customer already has a third-party firewall that protects the data center.
The customer wants to use certificates to authenticate user devices, but is concerned about the complexity of deploying the solution. The architect should recommend a way to simplify. For the most part users connect company-issued laptops to the network. However, users can bring their own devices and connect them to the network. The customer does not know how many devices each user will connect, but expects about two or three per-user. DHCP logs indicate that the network supports a maximum of 2800 devices.
Refer to the provided scenario. Which ClearPass licenses should the architect include in the proposal?

• A. 3,000 Access licenses and 3,000 (3x1000) Onboard licenses
• B. 1,000 Access licenses and 1000 Onboard licenses
• C. 1,000 Access licenses and 3,000 (3x1000) Onboard licenses
• D. 3,000 Access licenses (3x1000) and 1000 Onboard licenses

Answer: D

Explanation:
ClearPass Access licenses are required for each unique endpoint that authenticates to ClearPass using any supported protocol, such as 802.1X, MAC authentication, web authentication, or VPN authentication1. ClearPass Onboard licenses are required for each unique endpoint that is provisioned with a certificate using the ClearPass Onboard service2. In this scenario, the customer has 900 employees and up to
30 guests a day, which means there are at most 930 users who need to authenticate to the network. Assuming each user has about two or three devices, the maximum number of devices that need Access licenses is 930 x 3
= 2790, which can be rounded up to 3000. The customer also wants to use certificates to authenticate user devices, which means they need Onboard licenses as well. However, the customer only issues laptops to the employees, which means only 900 devices need Onboard licenses. Therefore, the architect should include
3000 Access licenses and 1000 Onboard licenses in the proposal. References:
1: ClearPass Licensing Guide - Aruba
2: ClearPass Onboard Data Sheet - Aruba

NEW QUESTION # 13
An architect plans 12 APs for an auditorium that is 325 square meters (3, 498 square feet). Each AP has one
2.4 GHz radio and one 5 GHz radio. Both types of radios use 20 MHz channels.
Assume that DFS channels can be used in this design. How many 5 GHz collision domains does this design provide?

• A. 0
• B. 1
• C. 2
• D. 3

Answer: B

Explanation:
A collision domain is a logical area of the network where devices share the same wireless medium and may interfere with each other's transmissions. In a WLAN, a collision domain is defined by the channel and the coverage area of an AP or a client. Devices that operate on the same channel and are within range of each other belong to the same collision domain and must contend for access to the medium using the Carrier Sense Multiple Access with Collision Avoidance (CSMA/CA) protocol. Devices that operate on different channels or are out of range of each other belong to different collision domains and do not interfere with each other.
In this scenario, the architect plans 12 APs for an auditorium that is 325 square meters (3,498 square feet).
Each AP has one 2.4 GHz radio and one 5 GHz radio. Both types of radios use 20 MHz channels. Assuming that DFS channels can be used in this design, the question is how many 5 GHz collision domains does this design provide.
To answer this question, we need to consider the following factors:
The number of available 5 GHz channels in the regulatory domain of the auditorium. Different countries have different regulations on the use of the 5 GHz band, which affects the number and availability of channels for WLANs. For example, in the United States, there are 25 non-overlapping 20 MHz channels in the 5 GHz band, but some of them are subject to Dynamic Frequency Selection (DFS) requirements, which means that they must avoid interfering with radar systems by detecting and switching to another channel if radar signals are present. In other countries, such as Japan, there are 19 non-overlapping 20 MHz channels in the 5 GHz band, but some of them are restricted to indoor use only. Therefore, the number of available 5 GHz channels for the design depends on the regulatory domain of the auditorium.
The channel assignment and distribution of the 12 APs in the auditorium. The channel assignment and distribution of the APs affect the number and size of the collision domains in the WLAN. Ideally, the APs should be assigned to non-overlapping channels and distributed evenly across the auditorium to provide optimal coverage and capacity, while minimizing co-channelinterference and adjacent channel interference. Co-channel interference occurs when devices on the same channel interfere with each other, while adjacent channel interference occurs when devices on nearby channels interfere with each other. Both types of interference degrade the performance and quality of the WLAN. Therefore, the channel assignment and distribution of the APs should follow the best practices of RF design, such as using a channel reuse plan, avoiding channel overlap, and adjusting the transmit power and antenna gain of the APs to match the coverage and capacity requirements of the auditorium.
The coverage and capacity requirements of the auditorium. The coverage and capacity requirements of the auditorium affect the number and placement of the APs and the transmit power and antenna gain settings of the radios. The coverage requirement refers to the minimum signal strength and signal-to-noise ratio (SNR) that the APs and clients need to maintain a reliable wireless connection. The capacity requirement refers to the maximum number of clients and the minimum throughput and quality of service (QoS) that the APs and clients need to support the applications and services of the auditorium.
The coverage and capacity requirements of the auditorium depend on the size and shape of the space, the density and distribution of the clients, the types and characteristics of the applications and services, and the performance and capabilities of the devices. Therefore, the coverage and capacity requirements of the auditorium should be determined by conducting a site survey and a network analysis, and then used to guide the design and configuration of the APs and radios.
Based on these factors, we can estimate the number of 5 GHz collision domains in the design as follows:
Assuming that the auditorium is located in the United States and that DFS channels can be used in the design, there are 25 non-overlapping 20 MHz channels in the 5 GHz band. However, not all of them may be available or suitable for the design, depending on the presence and activity of radar systems in the area, the compatibility and support of the APs and clients, and the interference and noise level of the environment. Therefore, we will use a conservative estimate of 15 available 20 MHz channels in the 5 GHz band for the design.
Assuming that the 12 APs are assigned to non-overlapping channels and distributed evenly across the auditorium, each AP will have its own 5 GHz collision domain, as there will be no co-channel interference or adjacent channel interference among the APs. Therefore, there will be 12 5 GHz collision domains in the design, corresponding to the 12 APs.
Assuming that the coverage and capacity requirements of the auditorium are moderate and that the transmit power and antenna gain settings of the radios are adjusted accordingly, each AP will cover an area of about 27 square meters (290 square feet), which is roughly the size of a small classroom. This means that the APs will provide adequate signal strength and SNR for the clients, while avoiding excessive overlap and interference among the APs. Therefore, there will be no need to further divide or merge the 5 GHz collision domains in the design, as they will match the coverage and capacity requirements of the auditorium.
Hence, the number of 5 GHz collision domains in the design is 12, which is the answer option C. References:
RF Design | Validated Solution Guide - Aruba
Configuring 2.4 Ghz and 5 Ghz Radios - Aruba
Chapter T-5: Understanding RF Collision Domains - Aruba
[Aruba Certified Design Professional Official Certification Study Guide (HPE6-A47)]

NEW QUESTION # 14
An architect plant to purpose an Aruba wireless solution with several Mobility Controllers (MCs) and a Mobility Master (MM) architecture. Wireless users run Skype for Business, a Unified Communications (UC) solution. The architect plans to use the Aruba SDN capabilities to integrate with the UC solution.
What helps to support high availability specifically for the SDN services?

• A. a cluster deployment for MCs
• B. backup controllers defines on the APs
• C. a redundant MM
• D. a redundant master MC

Answer: C

Explanation:
The Aruba SDN Controller is a software component that runs on the Mobility Master (MM) and provides centralized control and management of the network devices and applications that support the SDN services. The SDN Controller communicates with the network devices through the southbound interface (SBI) and exposes the northbound API (NBAPI) for the SDN applications to access the network resources and services1.
One of the SDN applications that can integrate with the Aruba SDN Controller is the Aruba UC and Collaboration Solution, which optimizes the performance and quality of Skype for Business traffic over the wireless network. The Aruba UC and Collaboration Solution consists of three components: the Aruba UC and Collaboration SDN Application, the Aruba UC and Collaboration Dashboard, and the Aruba UC and Collaboration Agent2.
The Aruba UC and Collaboration SDN Application is a software module that runs on the Skype for Business Front End Server and communicates with the Aruba SDN Controller through the NBAPI. The Aruba UC and Collaboration SDN Application monitors the Skype for Business sessions and events, and sends the relevant information to the Aruba SDN Controller, such as the user identity, device type, session type, codec, bandwidth, and quality of service (QoS) requirements2.
The Aruba UC and Collaboration Dashboard is a web-based graphical user interface that provides visibility and analytics of the Skype for Business sessions and events over the wireless network. The Aruba UC and Collaboration Dashboard connects to the Aruba SDN Controller through the NBAPI and displays the information collected by the Aruba UC and Collaboration SDN Application, such as the number of active sessions, session types, session quality, bandwidth consumption, and device distribution2.
The Aruba UC and Collaboration Agent is a software module that runs on the Mobility Controller (MC) and communicates with the Aruba SDN Controller through the SBI. The Aruba UC and Collaboration Agent receives the information from the Aruba UC and Collaboration SDN Application through the Aruba SDN Controller, and applies the appropriate QoS policies and actions on the wireless network, such as prioritizing the Skype for Business traffic, marking the DSCP values, reserving the bandwidth, and adjusting the airtime2.
To support high availability for the SDN services, the Aruba SDN Controller must be deployed in a redundant configuration, with a primary MM and a backup MM. The primary MM runs the active instance of the Aruba SDN Controller, while the backup MM runs the standby instance of the Aruba SDN Controller. The backup MM synchronizes the configuration and state information from the primary MM, and takes over the SDN Controller role in case of a failure or switchover of the primary MM1.
The other options do not provide high availability specifically for the SDN services, although they may provide redundancy for other aspects of the wireless network. A redundant master MC does not run the Aruba SDN Controller, and only provides backup for the master MC role, which is responsible for managing the configuration and licensing of the MCs in the network3. Backup controllers defined on the APs do not run the Aruba SDN Controller, and only provide backup for the local MC role, which is responsible for terminating and managing the APs in the network4. A cluster deployment for MCs does not run the Aruba SDN Controller, and only provides load balancing and fast failover for the APs in the network5.
References: 1: ArubaOS 8.7 User Guide - Aruba, Chapter 42: SDN Controller, pages 1049-1050. 2: Aruba UC and Collaboration Solution Guide - Aruba, Chapter 2: Aruba UC and Collaboration Solution Overview, pages 11-15. 3: ArubaOS 8.7 User Guide - Aruba, Chapter 2: ArubaOS Architecture, pages 25-26. 4: ArubaOS
8.7 User Guide - Aruba, Chapter 3: Configuring Controller Redundancy, pages 39-40. 5: ArubaOS 8.7 User Guide - Aruba, Chapter 4: Configuring Controller Clustering, pages 51-52.

NEW QUESTION # 15
A customer has several clusters of Aruba 325 Instant APs. The customer is happy with the performance of the current APs, but would like to add a Mobility Controller (MC). What should the architect propose?

• A. conversion of the existing Instant APs to campus APs (CAPs)
• B. the purchase of Universal APs that are the same modes as the current APs.
• C. Aruba ClearPass to onboard the APs as campus APs in the new MC-based deployment
• D. a Virtual Mobility Controller (VMC) which can be licensed to control Instant APs

Answer: A

Explanation:
The correct answer is option C, conversion of the existing Instant APs to campus APs (CAPs). This is because the existing Instant APs can be converted to CAPs by changing their operating mode and pointing them to the MC. This way, the customer can leverage the existing APs and avoid purchasing new ones. The MC can then provide centralized management, configuration, and control for the APs.
Option A is incorrect because the purchase of Universal APs is not necessary. Universal APs are APs that can operate in either Instant or CAP mode without requiring a conversion. However, the existing APs can be converted to CAPs without buying new ones.
Option B is incorrect because Aruba ClearPass is not required to onboard the APs as CAPs in the new MC-based deployment. Aruba ClearPass is a network access control (NAC) solution that provides authentication, authorization, and accounting (AAA) services for wired and wireless devices. It is not involved in the conversion of Instant APs to CAPs.
Option D is incorrect because a Virtual Mobility Controller (VMC) is not a valid option to control Instant APs.
A VMC is a software-based MC that runs on a hypervisor. It can control CAPs, but not Instant APs. Instant APs can only be controlled by another Instant AP acting as a Virtual Controller (VC).
References: The information can be referenced from the official HPE documents and learning materials available on HPE Press and Aruba Networks. Specifically, it aligns with the objectives outlined in Chapter 6:
Wireless Network Design, where the Instant and CAP modes and the MC options are discussed. Designing Aruba Solutions Official Certification Study Guide Aruba Instant User Guide Aruba Mobility Controller Data Sheet

NEW QUESTION # 16
An architect plans to deploy a Mobility Controller (MC) at one building in subnet 10.23.01.0/24 and another
MC in another building in subnet 10.44.12.0/24. The MCs need to provide redundancy for each other. What
must the architect take into account in the redundancy plan?

• A. The MCs can be in a cluster, but the cluster will not support features such as stateful failover.
• B. The MCs cannot be in a cluster, and they must use Virtual Router Redundancy Protocol (VRRP) to
  provide redundancy for each other.
• C. The MCs cannot provide any level of redundancy for each other unless one is moved into the other's
  subnet.
• D. Each MC can be the backup LMS for the other MCs' APs, but it cannot be in a cluster with the other
  MC.

Answer: B

NEW QUESTION # 17
An architect proposes Aruba 2930F switches, which do not have OOBM ports. The customer wants to follow
best practices for network management security. Which guideline can the architect follow?

• A. Assign access layer switches IP addresses on a VLAN that is dedicated for switch management.
• B. Ensure that Telnet is enabled and set to listen on production VLANs.
• C. Assign switches static IP addresses on the same VLAN on which APs are deployed.
• D. Ensure that DHCP is enabled on only the switch Default VLAN.

Answer: B

NEW QUESTION # 18
A customer requires a wireless upgrade. The architect proposes:
* Aruba AP-325s
* Mobility Controller (MC) 7210s
* Virtual Mobility Masters (MMs)
* ClearPass
* AirWave
The customer is interested in wired authentication, as well as wireless authentication, but does not have the budget to upgrade the wired network. The wired network does not currently support 802.1X or RADIUS.
Which feature of the Aruba solution should the architect explain to justify the proposed solution?

• A. The customer can direct all wired traffic through the MCs, which will then apply security to that traffic.
• B. ClearPass OnConnect can enable wired authentication on these switches through the use of SNMP.
• C. The customer can direct all wired traffic through the MMs, which will impose basic security checks.
• D. AirWave can manage these switches and shut down their ports if an unknown user or device connects.

Answer: B

NEW QUESTION # 19
Refer to the exhibit.

The customer requires fast failover if any one link or core device fails. Which additional technology should the architect plan on the core VSF fabric to meet these criteria?

• A. BGP
• B. OSPF graceful restart
• C. SmartLink
• D. VRRP

Answer: C

Explanation:
SmartLink is a technology that provides fast failover for access switches connected to the core VSF fabric. It detects link failures on the uplink ports and switches to the backup link within 50 ms. It also shuts down the primary link to prevent loops. SmartLink works with any routing protocol and does not require any additional configuration on the core switches. OSPF graceful restart is a feature that allows OSPF to continue forwarding traffic during a planned or unplanned restart of the routing process. However, it does not provide fast failover for link or device failures. BGP is a routing protocol that is mainly used for inter-domain routing and does not provide fast failover for link or device failures. VRRP is a protocol that provides redundancy for routers by creating a virtual router with a shared IP address. However, it does not provide fast failover for link or device failures. References: ArubaOS-Switch Management and Configuration Guide for WC.16.10), Aruba Validated Design: Campus Wired LAN)

NEW QUESTION # 20
A financial institution has an Aruba wireless system. Each floor is 19 meters by 23 meters (200 feet by 250 feet) and has 20 APs. The organization now requires dedicated Air Monitors (AMs). About how many AMs should the architect recommend per floor?

• A. about 10 to 12 per floor
• B. about 16 to 20 per floor
• C. about 3 to 5 per floor
• D. about 1 or 2 per floor

Answer: C

Explanation:
Air Monitors (AMs) are Aruba access points (APs) that are configured to operate in a dedicated mode for scanning the RF spectrum and detecting rogue APs, clients, and intrusion attacks. AMs do not serve any wireless clients and can scan all channels in both 2.4 GHz and 5 GHz bands. AMs provide better visibility and coverage of the RF environment than APs that serve clients, as they can scan more frequently and thoroughly.
However, AMs also consume more power and network resources than APs, and require additional hardware and licensing costs. Therefore, the optimal number of AMs per floor depends on several factors, such as the size and shape of the floor, the density and distribution of APs and clients, the security and compliance requirements, and the budget and availability of the organization.
According to the Aruba Wireless Intrusion Protection (WIP) Technology Guide1, a general rule of thumb is to deploy one AM for every four to six APs. This ratio can provide adequate coverage and detection for most environments, while balancing the trade-offs between performance and cost. However, this ratio is not fixed and can vary depending on the specific needs and characteristics of each deployment. For example, if the floor has a high density of APs and clients, or a high risk of rogue or malicious activity, more AMs may be needed to provide better security and visibility. Conversely, if the floor has a low density of APs and clients, or a low risk of rogue or malicious activity, fewer AMs may be sufficient to provide adequate security and visibility.
In this case, the floor has 20 APs, which implies a moderate to high density of APs and clients. Assuming that the floor has a rectangular shape and a uniform distribution of APs and clients, a reasonable estimate of the number of AMs per floor would be about 3 to 5, based on the general rule of thumb. This would provide enough coverage and detection for most scenarios, while minimizing the additional costs and resources.
However, this estimate may need to be adjusted if the floor has a different shape or a non-uniform distribution of APs and clients, or if the organization has specific security and compliance requirements that demand more or less AMs per floor. References:
Wireless Intrusion Protection (WIP) Technology Guide
Installing Air Monitors | Wireless Access - Airheads Community
Aruba Certified Design Professional Official Certification Study Guide (HPE6-A47)

NEW QUESTION # 21
Refer to the exhibit.

The customer needs to expand its wired and wireless network to a new building, Building 2, which is near the existing building, Building 1. The exhibit shows the logical plan that the architect has created so far. The aggregation layer switches in the new building should provide the default gateway services for the VLANs in the new building and route traffic to the core. The existing Aruba Mobility Controllers (MCs) will control the new APs.
What should be the VLAN assignment for Link 1, indicated in the exhibit?

• A. the default VLAN and VLAN 14
• B. an unused VLAN such as 200
• C. VLANs 21, 22, and 23 only
• D. VLANs 11, 12, 13, 21, 22, and 23

Answer: D

NEW QUESTION # 22
The customer has an office environment with users who have laptops that can connect with wired or wireless. Users also bring one or two of their own devices. An architect creates a proposal with Aruba AP-
325s, 7210 Mobility Controllers (MCs), a Mobility Master (MM), and Aruba 2930M switches at the access layer to support the laptops and APs.
The architect plans to recommend 802.1X authentication without tunneled node on Aruba 2930M switch ports that connect to laptops. What is one advantage of this form of authentication?

• A. enables user access control and ensures only authorized users connect.
• B. prevents users from connection attempts with more than three devices
• C. ensures that Aruba firewall policies apply to wired user traffic.
• D. provides a second layer of protection for wireless users at the internal perimeter

Answer: A

NEW QUESTION # 23
An architect learns that a customer site is 14,307 square meters (154,000 square feet) and supports 900 employees using WiFi 5 Ghz radio. What additional information should the architect collect to create the RF plan?

• A. whether BLE wayfinding is required
• B. the OS used on wireless devices
• C. software version on Mobility Controllers (MCs)
• D. number of devices used by each user

Answer: D

Explanation:
The number of devices used by each user is an important factor for creating the RF plan, as it affects the network capacity, bandwidth demand, and interference level. The architect should estimate the average number of devices per user and the types of applications they use, such as voice, video, or data. This will help the architect to determine the optimal number and placement of access points, the channel width and selection, the transmit power and data rates, and the radio resource management settings.
The OS used on wireless devices, whether BLE wayfinding is required, and the software version on MCs are not directly relevant for creating the RF plan, as they do not affectthe physical layer characteristics of the wireless network. However, they may have implications for other aspects of the network design, such as security, compatibility, and features.
References:
RF Design | Validated Solution Guide - Aruba
Enterprise Mobility 8.5 Design Guide - WLAN RF Design Considerations [Cisco 5500 Series Wireless Controllers] - Cisco

NEW QUESTION # 24
Refer to the exhibit.

A customer wants to replace the core and aggregation layer of an existing network. Currently the network routes between the aggregation layer and core, and uses the technologies shown in the exhibit.
The customer now wants to route at the core, instead of the aggregation layer, and extend some of the same VLANs in different buildings. However, the customer cannot eliminate the aggregation layer at this point. What should the architect recommend?

• A. Create a backplane stack at the aggregation layer and a VSF fabric at the core.
• B. Implement broadcast filtering on switch-to-switch links across all of the buildings.
• C. Combine all switches in the aggregation layer and core into a single backplane stack.
• D. Use VRRP on the core and aggregation switches, with the aggregation switches acting as standby.

Answer: C

NEW QUESTION # 25
A customer requires a wireless upgrade. The architect proposes:
Aruba AP-325s

Mobility Controller (MC) 7210s

Virtual Mobility Masters (MMs)

ClearPass

AirWave

The customer is interested in wired authentication, as well as wireless authentication, but does not have the budget to upgrade the wired network. The wired network does not currently support 802.1X or RADIUS.
Which feature of the Aruba solution should the architect explain to justify the proposed solution?

• A. The customer can direct all wired traffic through the MCs, which will then apply security to that traffic.
• B. ClearPass OnConnect can enable wired authentication on these switches through the use of SNMP.
• C. The customer can direct all wired traffic through the MMs, which will impose basic security checks.
• D. AirWave can manage these switches and shut down their ports if an unknown user or device connects.

Answer: B

NEW QUESTION # 26
The customer has an office environment with users who have laptops that can connect with wired or wireless.
Users also bring one or two of their own devices. An architect creates a proposal with Aruba AP-325s, 7210
Mobility Controllers (MCs), a Mobility Master (MM), and Aruba 2930M switches at the access layer to
support the laptops and APs.
The architect plans to recommend 802.1X authentication without tunnelled node on Aruba 2930M switch ports
that connect to laptops. What is one advantage of this form of authentication?

• A. enables user access control and ensures only authorized users connect.
• B. prevents users from connection attempts with more than three devices
• C. ensures that Aruba firewall policies apply to wired user traffic.
• D. provides a second layer of protection for wireless users at the internal perimeter

Answer: A

NEW QUESTION # 27
An architect plans where to deploy new Aruba 320 Series APs at a customer site. The architect plans for the APs to be installed on the ceiling where power is inaccessible. The Ethernet cable run to these locations is CAT6, and the customer wants to support at least 1 GbE connectivity. The architect plans to connect each AP with one Ethernet port to a switch in a nearby wiring closet.
Which feature does the switch need to support for this deployment?

• A. PoE+
• B. Smart Rate
• C. Port channel
• D. LACP

Answer: A

Explanation:
The switch needs to support PoE+ for this deployment. PoE+ stands for Power over Ethernet Plus, and it is a technology that allows the switch to provide both data and power to the connected devices over a single Ethernet cable. This eliminates the need for separate power sources or adapters for the devices, and simplifies the installation and management of the network. PoE+ can provide up to 30 watts of power per port,which is sufficient for the Aruba 320 Series APs, which have a maximum power consumption of 20 watts. PoE+ also supports 1 GbE connectivity, which meets the customer's requirement.
The other options are not relevant for this deployment:
Option B is incorrect because LACP is not a feature that the switch needs to support for this deployment. LACP stands for Link Aggregation Control Protocol, and it is a protocol that allows multiple physical links to be combined into a single logical link, providing higher bandwidth and redundancy. However, the architect plans to connect each AP with one Ethernet port to the switch, so there is no need for link aggregation in this scenario.
Option C is incorrect because port channel is not a feature that the switch needs to support for this deployment. Port channel is another term for link aggregation, which is not required for this scenario, as explained above.
Option D is incorrect because Smart Rate is not a feature that the switch needs to support for this deployment. Smart Rate is a technology that allows the switch to provide multi-gigabit Ethernet speeds (up to 10 GbE) and PoE+ to the connected devices, depending on the cable type and length. However, the customer only wants to support at least 1 GbE connectivity, which can be achieved with PoE+ and CAT6 cable, without the need for Smart Rate.
References:
Aruba 320 Series Access Points Data Sheet)
ArubaOS-Switch and ArubaOS-CX Transceiver Guide)
Aruba Certified Design Professional Official Certification Study Guide (HPE6-A47))

NEW QUESTION # 28
......

HPE6-A47 EXAM DUMPS WITH GUARANTEED SUCCESS: https://passguide.dumpexams.com/HPE6-A47-vce-torrent.html