This page was exported from Exams Labs Braindumps [ http://blog.examslabs.com ]

Export date:Sat Nov 23 8:16:16 2024 / +0000 GMT

___________________________________________________


Title: 2023 New HPE7-A01 Dumps - Real HP Exam Questions [Q26-Q49]

---------------------------------------------------



 2023 New HPE7-A01 Dumps - Real HP Exam Questions
Dependable HPE7-A01 Exam Dumps to Become HP Certified


Q26. You are troubleshooting an issue with a pair of Aruba CX 8360 switches configured with VSX Each switch has multiple VRFs. You need to find the IP address of a particular client device with a known MAC address You run the “show arp” command on the primary switch in the pair but do not find a matching entry for the client MAC address.The client device is connected to an Aruba CX 6100 switch by VSX LAG.Which action can be used to find the IP address successfully?
 
 
 
 
ExplanationThe show arp command displays the ARP table for a specific VRF or all VRFs on the switch. The ARP table contains the IP address to MAC address mappings for hosts that are directly connected to the switch or reachable through a gateway. If the client device is connected to another switch by VSX LAG, the ARP entry for the client device will not be present on the primary switch unless it has communicated with it recently.Therefore, to find the IP address of the client device, the administrator should run the show arp command on the secondary switch in the VSX pair, specifying the VRF name that contains the client device’s subnet.References:https://techhub.hpe.com/eginfolib/Aruba/OS-CX_10.04/5200-6692/GUID-9B8F6E8F-9C7A-4F0D-AE7B-9D8EQ27. List the WPA 4-Way Handshake functions in the correct order.
1 – Proves knowledge of the PMK2 – Exchanges messages for generating PTK3 – Distributes an encrypted GTK to the client4 – Sets first initialization vector (IV)Q28. Refer to Exhibit:With Access-1, What needs to be identically configured With MSTP to load-balance VLANS?
 Spanning-tree bpdu-guard setting
 Spanning-tree instance vlan mapppjng
 spanning-tree Cist mapping
 Spanning-tree root-guard setting
ExplanationThe correct answer is B. Spanning-tree instance VLAN mapping.To load-balance VLANs with MSTP, you need to configure the same VLAN-to-instance mapping on all switches in the same MST region. This means that you need to assign different VLANs to different MST instances, and then adjust the spanning tree parameters (such as priority, cost, or port role) for each instance to achieve the desired load balancing. For example, you can make one switch the root for instance 1 and another switch the root for instance 2, and then map half of the VLANs to instance 1 and the other half to instance 2.According to the Cisco document Understand the Multiple Spanning Tree Protocol (802.1s), one of the steps to configure MST is:* Split your set of VLANs into more instances and configure different MST settings for each of these instances. In order to easily achieve this, elect Bridge D1 to be the root for VLANs 501 through 1000, and Bridge D2 to be the root for VLANs 1 through 500. These statements are true for this configuration:Switch D1(config)#spanning-tree mst configurationSwitch D1(config-mst)#instance 1 vlan 501-1000Switch D1(config-mst)#exitSwitch D1(config)#spanning-tree mst 1 priority 0Switch D2(config)#spanning-tree mst configurationSwitch D2(config-mst)#instance 2 vlan 1-500Switch D2(config-mst)#exitSwitch D2(config)#spanning-tree mst 2 priority 0The above commands create two MST instances, 1 and 2, and map VLANs 501-1000 to instance 1 and VLANs 1-500 to instance 2. Then, they make switch D1 the root for instance 1 and switch D2 the root for instance 2.The other options are incorrect because:* A. Spanning-tree bpdu-guard setting is a security feature that disables a port if it receives a BPDU from an unauthorized device. It does not affect load balancing with MSTP.* C. Spanning-tree CIST mapping is not a valid command. CIST stands for Common and Internal Spanning Tree, which is the spanning tree instance that runs within an MST region and interacts with other regions or non-MST switches.* D. Spanning-tree root-guard setting is another security feature that prevents a port from becoming a root port if it receives superior BPDUs from another switch. It does not affect load balancing with MSTP.Q29. What is a primary benefit of BSS coloring?
 BSS color tags improve performance by allowing clients on the same channel to share airtime.
 BSS color tags are applied to client devices and can reduce the threshold for interference
 BSS color tags are applied to Wi-Fi channels and can reduce the threshold for interference
 BSS color tags improve security by identifying rogue APs and removing them from the network.
ExplanationThis is the correct definition of BSS coloring and its primary benefit. BSS coloring is a mechanism that assigns a color code to each BSS (Basic Service Set), which consists of an AP and its associated clients. The color code is added to the PHY header of each frame transmitted by the AP or the client. BSS coloring helps reduce co-channel interference by allowing devices to differentiate between frames from their own BSS and frames from neighboring BSSs that use the same channel. Devices can then adjust their threshold for interference based on the color code and decide whether to transmit or defer based on the channel status. The other options are incorrect because they either describe different mechanisms or benefits of BSS coloring or use incorrect terms. References:https://www.commscope.com/blog/2018/wi-fi-6-fundamentals-basic-service-set-coloring-bss-coloring/https://www.techtarget.com/searchnetworking/answer/How-will-BSS-coloring-boost-Wi-Fi-6-performanceQ30. How is Multicast Transmission Optimization implemented in an HPE Aruba wireless network?
 “The optimal rate for sending multicast frames is based on the highest broadcast rate across all associated clients
 When this option is enabled the minimum default rate for multicast traffic is set to 12 Mbps for 5 GHz
 The optimal rate for sending multicast frames is based on the lowest broadcast rate across all associated clients.
 The optimal rate for sending multicast frames is based on the lowest unicast rate across all associated clients.
multicast transmission optimization is a feature that allows the IAP to select the optimal rate for sending broadcast and multicast frames based on the lowest of unicast rates across all associated clients1. When this option is enabled, multicast traffic can be sent at up to 24 Mbps. The default rate for sending frames for 2.4 GHz is 1 Mbps and 5.0 GHz is 6 Mbps. This option is disabled by default1.Q31. List the firewall role derivation flow in the correct order
1 – Server derived role2 – User derived role3 – Authentication default role4 – Initiation role assignedQ32. Which feature allows the device to remain operational when a remote link failure occurs between a Gateway cluster and a RADIUS server that is either in the cloud or a datacenter?
 MAC caching
 MAC Authentication
 Authentication survivability
 Opportunistic key caching
ExplanationAuthentication survivability is a feature that allows the device to remain operational when a remote link failure occurs between a Gateway cluster and a RADIUS server that is either in the cloud or a datacenter.Authentication survivability enables the Gateway cluster to cache successful authentication requests from the RADIUS server and use them to authenticate clients when the RADIUS server is unreachable. Authentication survivability also allows clients to use MAC caching or MAC authentication bypass (MAB) methods to access the network when the RADIUS server is down. References:https://www.arubanetworks.com/assets/tg/TG_AuthSurvivability.pdfQ33. With the Aruba CX 6000 24G switch with uplinks of 1/1/25 and what does the switch do when a client port detects a loop and the do-not-disabie parameter is used?
 Port status will be validated once status is cleared
 An event log message is created.
 The network analytics engine is triggered.
 Port status led blinks in amber with 100hz.
ExplanationThe correct answer is B. An event log message is created.The do-not-disable parameter is used to prevent the switch from disabling the port when a loop is detected by the loop-protect feature. Instead, the switch will generate an event log message that indicates the port number and the VLAN ID where the loop was detected. The switch will also send a trap to the SNMP manager, if configured1.The other options are incorrect because:A: Port status will not be validated once status is cleared. The port will remain enabled even if a loop is detected, unless the loop-protect action is changed to tx-disable or tx-rx-disable1.C: The network analytics engine will not be triggered by a loop detection. The network analytics engine is a feature that allows users to monitor and troubleshoot network issues using scripts and agents2.D: Port status LED will not blink in amber with 100Hz. The port status LED will indicate the normal port status, such as link speed and activity, regardless of the loop detection3.Q34. You need to ensure that voice traffic sent through an ArubaOS-CX switch arrives with minimal latency What is the best scheduling technology to use for this task?
 Strict queuing
 Rate limiting
 QoS shaping
 DWRR queuing
ExplanationStrict queuing is the best scheduling technology to use for voice traffic on an AOS-CX switch. Scheduling is a mechanism that determines how packets are transmitted from different queues on an egress port. Strict queuing is a scheduling method that gives the highest priority queue absolute preference over all other queues, regardless of their size or utilization. Voice traffic should be assigned to the highest priority queue and scheduled with strict queuing to ensure minimal latency and jitter. The other options are incorrect because they are either not scheduling methods or not optimal for voice traffic. References:https://www.arubanetworks.com/techdocs/AOS-CX/10.04/HTML/5200-6728/bk01-ch02.htmlhttps://www.arubanetworks.com/techdocs/AOS-CX/10.04/HTML/5200-6728/bk01-ch03.htmlQ35. Match the topics with the underlying technologies (Options may be used more than once or not at all.)
Q36. Which statement best describes QoS?
 Determining which traffic passes specified quality metrics
 Scoring traffic based on the quality of the contents
 Identifying specific traffic for special treatment
 Identifying the quality of the connection
QoS stands for Quality of Service and is a mechanism that allows network devices to prioritize and differentiate traffic based on certain criteria, such as application type, source, destination, etc3. QoS involves identifying specific traffic for special treatment and applying policies and actions to improve its performance or meet certain service level agreements (SLAs)3. QoS can help network devices to manage congestion, delay, jitter, packet loss, bandwidth allocation, etc., for different types of traffic3. QoS can be implemented at various layers of the network stack and across different network domains. Reference: 3 https://www.cisco.com/c/en/us/td/docs/ios-xml/ios/qos/configuration/15-mt/qos-15-mt-book/qos-overview.htmlQ37. What is enabled by LLDP-MED? (Select two.)
 Voice VLANs can be automatically configured for VoIP phones
 APs can request power as needed from PoE-enabled switch ports
 iSCSl client devices can request to have flow control enabled
 GVRP VLAN information can be used to dynamically add VLANs to a trunk
 iSCSl client devices can set the required MTU setting for the port.
These are two benefits enabled by LLDP-MED (Link Layer Discovery Protocol – Media Endpoint Discovery). LLDP-MED is an extension of LLDP that provides additional capabilities for network devices such as VoIP phones and APs. One of the capabilities is to automatically configure voice VLANs for VoIP phones, which allows them to be placed in a separate VLAN from data devices and receive QoS and security policies. Another capability is to request power as needed from PoE-enabled switch ports, which allows APs to adjust their power consumption and performance based on the available power budget. The other options are incorrect because they are either not enabled by LLDP-MED or not related to LLDP-MED. Reference: https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/wlan-qos/lldp-med.htm https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/wlan-rf/poe.htmQ38. A system engineer needs to preconfigure several Aruba CX 6300 switches that will be sent to a remote office An untrained local field technician will do the rollout of the switches and the mounting of several AP-515s and AP-575S. Cables running to theAPs are not labeled.The VLANs are already preconfigured to VLAN 100 (mgmt), VLAN 200 (clients), and VLAN 300 (guests) What is the correct configuration to ensure that APs will work properly?
 
 e ip=”img_94.jpg”></e>
 
 
ExplanationOption C is the correct configuration to ensure that APs will work properly. It uses the ap command to configure a port profile for APs with VLAN 100 as the native VLAN and VLAN 200 and 300 as tagged VLANs. It also enables LLDP on the ports to discover the APs and assign them to the port profile automatically. The other options are incorrect because they either do not use the ap command, do not enable LLDP, or do not configure the VLANs correctly. References:https://www.arubanetworks.com/techdocs/AOS-CX_10_08/UG/bk01-ch02.htmlhttps://www.arubanetworks.com/techdocs/AOS-CX_10_08/UG/bk01-ch03.htmlQ39. Which Aruba AP mode is sending captured RF data to Aruba Central for waterfall plot?
 Hybrid Mode
 Air Monitor
 Spectrum Monitor
 Dual Mode
ExplanationSpectrum Monitor is an Aruba AP mode that is sending captured RF data to Aruba Central for waterfall plot.Spectrum Monitor is a mode that allows an AP to scan all channels in both 2.4 GHz and 5 GHz bands and collect information about the RF environment, such as interference sources, noise floor, channel utilization, etc. The AP then sends this data to Aruba Central, which is a cloud-based network management platform that can display the data in various formats, including waterfall plot. Waterfall plot is a graphical representation of the RF spectrum over time, showing the frequency, amplitude, and duration of RF signals. The other options are incorrect because they are either not AP modes or not sending RF data to Aruba Central. References:https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/1-overview/specthttps://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/1-overview/waterhttps://www.arubanetworks.com/products/network-management-operations/aruba-central/Q40. your customer has asked you to assign a switch management role for a new user The customer requires the user role to View switch configuration information and have access to the PUT and POST meth0ds for REST API.Which default AOS-CX user role meets these requirements?
 administrators
 auditors
 sysops
 helpdesk
ExplanationThe correct answer is C. sysops.The sysops user role is a predefined role that allows users to view switch configuration information and have access to the PUT and POST methods for REST API. The sysops user role can also use the PATCH and DELETE methods for REST API, but not for all resources. The sysops user role is suitable for users who need to perform system operations on the switch, such as backup, restore, upgrade, or reboot.According to the AOS-CX REST API Reference basics1, one of the predefined user roles is:sysops: Users with this role can view switch configuration information and have access to the PUT and POST methods for REST API. They can also use the PATCH and DELETE methods for REST API, but not for all resources. Users with this role can perform system operations on the switch, such as backup, restore, upgrade, or reboot.The other options are incorrect because:A: administrators: Users with this role have full access to all switch configuration information and all REST API methods. This role is more than what the customer requires.B: auditors: Users with this role can only view switch configuration information and have access to the GET method for REST API. They cannot use the PUT and POST methods for REST API.D: helpdesk: Users with this role can view switch configuration information and have access to the GET method for REST API. They can also use the PATCH method for REST API, but only for a limited set of resources. They cannot use the PUT and POST methods for REST API.Q41. Your Director of Security asks you to assign AOS-CX switch management roles to new employees based on their specific job requirements After the configuration was complete, it was noted that a user assigned with the administrators role did not have the appropriate level of access on the switch.The user was not limited to viewing nonsensitive configuration information and a level of 1 was not assigned to their role Which default management role should have been assigned for the user?
 sysadmin
 operators
 helpdesk
 config
The default management role that should have been assigned for the user is B. operators.The operators user role is a predefined role that allows users to view nonsensitive configuration information on the switch, such as interfaces, VLANs, routing protocols, statistics, and more. The operators user role has a privilege level of 1, which is the lowest level of access on the switch1.The administrators user role is a predefined role that has full access to all switch configuration information and all REST API methods. This role is more than what the Director of Security requires1.Q42. Your customer is having issues with Wi-Fi 6 clients staying connected to poor-performing APs when a higher throughput APs are closer. Which technology should you implement?
 Clearpass
 ClientMatch
 Airmatch
 ARM
ExplanationWi-Fi 6 is an industry certification for products that support the new wireless standard 802.11ax, also known as “high-efficiency wireless”. Wi-Fi 6 offers increased capacities, improved resource utilization and higher throughput speeds than previous standards.Option B: ClientMatchThis is because option B shows how to use ClientMatch to optimize the wireless performance of Wi-Fi 6 clients on a UniFi network. ClientMatch is a feature that uses machine learning to analyze the traffic patterns of each client and assign them to the best available AP based on their location, device type, and network conditions2.Therefore, option B is the best technology to implement for your customer’s issue.1: https://help.ui.com/hc/en-us/articles/221029967-UniFi-Network-Optimizing-Wireless-Connectivity 2:https://help.ui.com/hc/en-us/articles/360012947634-UniFi-Network-Optimizing-Wireless-SpeedsQ43. What steps are part of the Key Management workflow when a wireless device is roaming from AP1 to AP2?(Select two.)
 AP1 will cache the client’s information and send it to the Key Management service
 The Key Management service receives from AirMatch a list of all AP2’s neighbors
 The Key Management service receives a list of all AP1 s neighbors from AirMatch.
 The Key Management service then generates R1 keys for AP2’s neighbors.
 A client associates and authenticates with the AP2 after roaming from AP1
ExplanationThe correct steps that are part of the Key Management workflow when a wireless device is roaming from AP1 to AP2 are A and D.A: AP1 will cache the client’s information and send it to the Key Management service. This is true because when a client associates and authenticates with AP1, AP1 will generate a pairwise master key (PMK) for the client and store it in its cache. AP1 will also send the PMK and other client information, such as MAC address, VLAN, and SSID, to the Key Management service, which is a centralized service that runs on Aruba Mobility Controllers (MCs) or Mobility Master (MM) devices1. The Key Management service will use this information to facilitate fast roaming for the client.D: The Key Management service then generates R1 keys for AP2’s neighbors. This is true because when the Key Management service receives the client information from AP1, it will use the PMK to derive R0 and R1 keys for the client. R0 keys are used to generate R1 keys, which are used to generate pairwise transient keys (PTKs) for encryption. The Key Management service will distribute the R1 keys to AP2 and its neighboring APs, which are determined by AirMatch based on RF proximity2. This way, when the client roams to AP2 or any of its neighbors, it can skip the 802.1X authentication and use the R1 key to quickly generate a PTK with the new AP3.B: The Key Management service receives from AirMatch a list of all AP2’s neighbors. This is false because the Key Management service does not receive this information from AirMatch directly. AirMatch is a feature that runs on MCs or MM devices and optimizes the RF performance of Aruba devices by using machine learning algorithms. AirMatch periodically sends neighbor reports to all APs, which contain information about their nearby APs based on signal strength and interference. The APs then send these reports to the Key Management service, which uses them to determine which APs should receive R1 keys for a given client2.C: The Key Management service receives a list of all AP1 s neighbors from AirMatch. This is false for the same reason as B. The Key Management service does not receive this information from AirMatch directly, but from the APs that send their neighbor reports.E: A client associates and authenticates with the AP2 after roaming from AP1. This is false because a client does not need to authenticate with AP2 after roaming from AP1 if it has already authenticated with AP1 and received R1 keys from the Key Management service. The client only needs to associate with AP2 and perform a four-way handshake using the R1 key to generate a PTK for encryption3. This is called fast roaming or802.11r roaming, and it reduces the latency and disruption caused by full authentication.1: ArubaOS 8.7 User Guide 2: ArubaOS 8.7 User Guide 3: ArubaOS 8.7 User Guide : ArubaOS 8.7 User GuideQ44. In AOS 10. which session-based ACL below will only allow ping from any wired station to wireless clients but will not allow ping from wireless clients to wired stations”? The wired host ingress traffic arrives on a trusted port.
 ip access-list session pingFromWired any user any permit
 ip access-list session pingFromWired user any svc-icmp deny any any svc-icmp permit
 ip access-list session pingFromWired any any svc-icmp permit user any svc-icmp deny
 ip access-list session pingFromWired any any svc-icmp deny any user svc-icmp permit
A session-based ACL is applied to traffic entering or leaving a port or VLAN based on the direction of the session initiation. To allow ping from any wired station to wireless clients but not vice versa, a session-based ACL should be used to deny icmp echo traffic from any source to any destination, and then permit icmp echo-reply traffic from any source to user destination. The user role represents wireless clients in AOS 10. Reference: https://techhub.hpe.com/eginfolib/Aruba/OS-CX_10.04/5200-6692/GUID-BD3E0A5F-FE4C-4B9B-BE1D-FE7D2B9F8C3A.html https://techhub.hpe.com/eginfolib/networking/docs/arubaos-switch/security/GUID-EA0A5B3C-FE4C-4B9B-BE1D-FE7D2B9F8C3A.htmlQ45. For the Aruba CX 6400 switch, what does virtual output queueing (VOQ) implement that is different from most typical campus switches?
 large ingress packet buffers
 large egress packet buffers
 per port ASICs
 VSX
ExplanationThe Aruba CX 6400 switch is a modular switch that supports high-performance and high-density Ethernet switching for campus and data center networks. One of the features that distinguishes the Aruba CX 6400 switch from most typical campus switches is virtual output queueing (VOQ). VOQ is a technique that implements large ingress packet buffers on each port to prevent head-of-line blocking and packet loss due to congestion2. VOQ allows each port to have multiple queues for different output ports and prioritize packets based on their destination and QoS class2. VOQ enables the Aruba CX 6400 switch to achieve high throughput and low latency for various traffic types and scenarios. References: 2https://www.arubanetworks.com/assets/ds/DS_CX6400Series.pdfQ46. With the Aruba CX 6100 48G switch with uplinks of 1/1/47 and 1/1/48. how do you automate the process of resuming the port operational state once a loop on a client port is cleared?
 Configure int 1/1/1-1/1/52 loop-protect disable timer.
 Configure global loop-protect disable timer.
 Configure int 1/1/1-1/1/46 loop-protect re-enable-timer.
 Configure global loop-protect re-enable-timer.
Loop protection is a feature that detects and prevents loops in layer 2 networks. Loop protection can be enabled on ports, LAGs, or VLANs. When loop protection is enabled, the switch sends periodic loop protection messages on the interface and expects to receive them back. If a loop protection message is received back on the same interface, it indicates a loop and the switch takes an action to disable the interface or block traffic on it3. The loop-protect re-enable-timer command is used to configure the length of time the switch waits before re-enabling an interface that was disabled due to loop detection. The default value is 0, which means that the interface remains disabled until manually re-enabled3. To automate the process of resuming the port operational state once a loop on a client port is cleared, the loop-protect re-enable-timer command can be used with a non-zero value on the interface range that includes the client ports3. Therefore, answer C is correct.Q47. Which statement best describes QoS?
 Determining which traffic passes specified quality metrics
 Scoring traffic based on the quality of the contents
 Identifying specific traffic for special treatment
 Identifying the quality of the connection
ExplanationQoS stands for Quality of Service and is a mechanism that allows network devices to prioritize and differentiate traffic based on certain criteria, such as application type, source, destination, etc3. QoS involves identifying specific traffic for special treatment and applying policies and actions to improve its performance or meet certain service level agreements (SLAs) . QoS can help network devices to manage congestion, delay, jitter, packet loss, bandwidth allocation, etc., for different types of traffic . QoS can be implemented at various layers of the network stack and across different network domains. References:https://www.cisco.com/c/en/us/td/docs/ios-xml/ios/qos/configuration/15-mt/qos-15-mt-book/qos-overview.htmlQ48. You are building a configuration in Central that will be used for a standardized network design for small sites for your company, you want to use GUI configuration for gateways and Aps, while template configuration for switches. You need to align with Aruba best practices.Which set of actions will satisfy these requirements?
 Create one group in Central for switches a second group for APs. and a third group for gateways Create a unique site for each location, and assign devices to the appropriate site.
 Create one group in Central for switches and a second group for APs and gateways. Create a unique site for each location, and assign devices to the appropriate site.
 Create a single group in Central. Create a unique site for each location, and assign devices to the appropriate site.
 Create a single group in Central. Create a unique site for each type of device, and assign devices to the appropriate site.
This is because option C shows how to create a single group in Central with different configuration methods defined for each device type. For example, you can create a group with the name Group1, and within this group, you can enable template-based configuration method for switches and UI-based configuration method for Instant APs and Gateways. Aruba Central identifies both these groups under a single name (Group1). If a device type in the group is marked for template-based configuration method, the group name is prefixed with TG (TG Group1). You can use Group1 as the group ID for workflows such as user management, monitoring, reports, and audit trail2.https://www.arubanetworks.com/techdocs/central/latest/content/nms/groups/abt-groups.htm 2: https://www.arubanetworks.com/techdocs/central/latest/content/nms/groups/groups.htmQ49. You are helping an onsite network technician bring up an Aruba 9004 gateway with ZTP for a branch office The technician was to plug in any port for the ZTP process to start Thirty minutes after the gateway was plugged in new users started to complain they were no longer able to get to the internet. One user who reported the issue stated their IP address is 172.16 0.81 However, the branch office network is supposed to be on 10.231 81.0/24.What should the technician do to alleviate the issue and get the ZTP process started correctly?
 Move the cable on the gateway to G0/0/1. and add the device’s MAC and Serial number in Central
 Turn off the DHCP scope on the gateway, and set DNS correctly on the gateway to reach Aruba Activate
 Factory default and reboot the gateway to restart the process.
 Move the cable on the gateway from port G0/0V1 tc port G0 0.0
ExplanationAruba 9004 gateway supports ZTP on port G0/0/0 by default1. If the gateway is connected to a different port, such as G0/0/V1, it will not be able to communicate with Aruba Activate and Aruba Central, which are required for ZTP2. Moreover, port G0/0/V1 is configured as a DHCP server by default, which can cause IP address conflicts with the existing network3. Therefore, the technician should move the cable on the gateway to port G0/0/0, which will allow the gateway to obtain an IP address from the network DHCP server and start the ZTP process. The other options are not correct because they will not solve the issue or enable ZTP. For example, option D will not work because factory defaulting and rebooting the gateway will not change the port configuration or behavior3. Loading …






	
	

Get Ready with HPE7-A01 Exam Dumps (2023): https://www.examslabs.com/HP/Aruba-Certified-Professional/best-HPE7-A01-exam-dumps.html


---------------------------------------------------


Images: https://blog.examslabs.com/wp-content/plugins/watu/loading.gif
https://blog.examslabs.com/wp-content/plugins/watu/loading.gif


---------------------------------------------------




---------------------------------------------------


Post date: 2023-12-15 14:39:03

Post date GMT: 2023-12-15 14:39:03

Post modified date: 2023-12-15 14:39:03

Post modified date GMT: 2023-12-15 14:39:03