2025 HP ACCURATE TEST HPE6-A85 LAB QUESTIONS

2025 HP Accurate Test HPE6-A85 Lab Questions

2025 HP Accurate Test HPE6-A85 Lab Questions

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HP HPE6-A85 exam is a multiple-choice exam that consists of 60 questions. HPE6-A85 exam is administered in a computer-based format and has a duration of 90 minutes. HPE6-A85 exam is designed to measure the candidate's knowledge and skills related to Aruba Campus Access solutions. It covers topics such as ArubaOS switches, Aruba access points, WLANs, and security. HPE6-A85 Exam is also designed to test the candidate's ability to troubleshoot and resolve issues related to Aruba Campus Access solutions. Passing HPE6-A85 exam is a requirement for obtaining the Aruba Certified Switching Associate (ACSA) certification.

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HP HPE6-A85 Certification Exam is a comprehensive exam that requires candidates to have a deep understanding of Aruba wireless networks. HPE6-A85 exam consists of 60 multiple-choice questions that must be completed within 90 minutes. To pass the exam, candidates must score a minimum of 70%. Aruba Campus Access Associate Exam certification exam is an excellent way for IT professionals to validate their skills and knowledge in implementing and managing Aruba wireless networks, and it can help them advance their careers in the IT industry.

HP Aruba Campus Access Associate Exam Sample Questions (Q25-Q30):

NEW QUESTION # 25
Which Aruba technology will allow for device-specific passphrases to securely add headless devices to the WLAN?

  • A. Temporal Key Integrity Protocol (TKIP)
  • B. Wired Equivalent Privacy (WEP)
  • C. Multiple Pre-Shared Key (MPSK)
  • D. Opportunistic Wireless Encryption (OWE)

Answer: C

Explanation:
Multiple Pre-Shared Key (MPSK) is a feature that allows device-specific or group-specific passphrases to securely add headless devices to the WLAN Wireless Local Area Network. WLAN is a wireless computer network that links two or more devices using wireless communication to form a local area network (LAN) within a limited area such as a home, school, computer laboratory, campus, or office building. . MPSK enhances the WPA2 PSK Wi-Fi Protected Access 2 Pre-Shared Key. WPA2 PSK is a method of securing your network using WPA2 with the use of the optional Pre-Shared Key (PSK) authentication, which was designed for home users without an enterprise authentication server. mode by allowing different PSKs for different devices on the same SSID Service Set Identifier. SSID is a case-sensitive, 32 alphanumeric character unique identifier attached to the header of packets sent over a wireless local-area network (WLAN). The SSID acts as a password when a mobile device tries to connect to the basic service set (BSS) - a component of the IEEE 802.11 WLAN architecture. . MPSK passwords can be generated or user-created and are managed by ClearPass Policy Manager12. Reference: 1 https://blogs.arubanetworks.com/solutions/simplify-iot-authentication-with-multiple-pre-shared-keys/ 2 https://www.arubanetworks.com/techdocs/ClearPass/6.8/Guest/Content/AdministrationTasks1/Configuring-MPSK.htm


NEW QUESTION # 26
Which device configuration group types can a user define in Aruba Central during group creation? (Select two.)

  • A. ESP group
  • B. Template group
  • C. Ul group
  • D. Default group
  • E. Security group

Answer: B,D

Explanation:
Explanation
Aruba Central allows you to create device configuration groups that define common settings for devices within each group. You can create different types of groupsdepending on your network requirements and management preferences. Two types of groups that you can define in Aruba Central during group creation are:
Template group: A template group allows you to create configuration templates using variables and expressions that can be applied to multiple devices or device groups. Template groups provide flexibility and scalability for managing large-scale deployments with similar configurations.
Default group: A default group is automatically created when you add devices to Aruba Central for the first time. The default group contains basic configuration settings that are applied to all devices that are not assigned to any other group. You can modify or delete the default group as needed.
References: https://www.arubanetworks.com/techdocs/Central/latest/content/nms/device-groups.htm
https://www.arubanetworks.com/techdocs/Central/latest/content/nms/template-groups.htm
https://www.arubanetworks.com/techdocs/Central/latest/content/nms/default-group.htm


NEW QUESTION # 27
The customer requires two Aruba CX 6200F 48G switches to be connected to each other with a distance of
80m/252ft between wiring closets. Switches need to have reservation for VSF expansion with ring topology in each cabinet.
What is a valid configuration for a redundant link-aggregation port configuration?

  • A. Ports 1/1/49 and 1/1/50 with SFP28 for LAG
  • B. Ports 1/1/1 and 1/1/2 for LAG
  • C. Ports 1/1/47 and 1/1/48 for LAG
  • D. Ports 1/1/51 and 1/1/52 with SFP+ for LAG

Answer: D

Explanation:
For an 80m distance between wiring closets, using SFP+ transceivers is appropriate as they can support longer distances than standard copper interfaces. Ports 1/1/51 and 1/1/52 are typically reserved for uplinks on Aruba CX 6200F 48G switches and can support SFP+ transceivers, making them suitable for a redundant link- aggregation port configuration.


NEW QUESTION # 28
Which commands are used to set a default route to 10.4.5.1 on an Aruba CX switch when ln-band management using an SVl is being used?

  • A. iP default-gateway 10.4.5.1
  • B. ip route 0 0 0.070 10.4 5.1 vrf mgmt
  • C. ip route 0.0 0 0/0 10.4.5.1
  • D. default-gateway 10.4.5.1

Answer: C

Explanation:
The command that is used to set a default route to 10.4.5.1 on an Aruba CX switch when in-band management using an SVI is being used is ip route 0.0 0 0/0 10.4.5.1 . This command specifies the destination network address (0.0 0 0) and prefix length (/0) and the next-hop address (10.4.5.1) for reaching any network that is not directly connected to the switch. The default route applies to the default VRF Virtual Routing and Forwarding. VRF is a technology that allows multiple instances of a routing table to co-exist within the same router at the same time. VRFs are typically used to segment network traffic for security, privacy, or administrative purposes. , which is used for in-band management traffic that goes through an SVI Switch Virtual Interface. SVI is a virtual interface on a switch that allows the switch to route packets between different VLANs on the same switch or different switches that are connected by a trunk link. An SVI is associated with a VLAN and has an IP address and subnet mask assigned to it12. Reference: 1 https://www.arubanetworks.com/techdocs/AOS-CX/10_08/HTML/ip_route_4100i-6000-6100-6200/Content/Chp_StatRoute/def-rou.htm 2 https://www.arubanetworks.com/techdocs/AOS-CX/10_08/HTML/ip_route_4100i-6000-6100-6200/Content/Chp_VRF/vrf-overview.htm


NEW QUESTION # 29
Review the configuration below.

Why would you configure OSPF to use the IP address 10.1.200.1 as the router ID?

  • A. The IP address associated with the loopback interface is routable and prevents loops
  • B. The loopback interface state is dependent on the management interface state and reduces routing updates.
  • C. The IP address associated with the loopback interface is non-routable and prevents loops
  • D. The loopback interface state Is independent of any physical interface and reduces routing updates.

Answer: D

Explanation:
The reason why you would configure OSPF Open Shortest Path First (OSPF) is a link-state routing protocol that dynamically calculates the best routes for data transmission within an IP network. OSPF uses a hierarchical structure that divides a network into areas and assigns each router an identifier called router ID (RID). OSPF uses hello packets to discover neighbors and exchange routing information. OSPF uses Dijkstra's algorithm to compute the shortest path tree (SPT) based on link costs and build a routing table based on SPT. OSPF supports multiple equal-cost paths, load balancing, authentication, and various network types such as broadcast, point-to-point, point-to-multipoint, non- broadcast multi-access (NBMA), etc. OSPF is defined in RFC 2328 for IPv4 and RFC 5340 for IPv6. to use the IP address IP address Internet Protocol (IP) address is a numerical label assigned to each device connected to a computer network that uses the Internet Protocol for communication. An IP address serves two main functions: host or network interface identification and location addressing.
There are two versions of IP addresses: IPv4 and IPv6. IPv4 addresses are 32 bits long and written in dotted-decimal notation, such as 192.168.1.1. IPv6 addresses are 128 bits long and written in hexadecimal notation, such as 2001:db8::1. IP addresses can be either static (fixed) or dynamic (assigned by a DHCP server). 10.1.200.1 as the router ID Router ID (RID) Router ID (RID) is a unique identifier assigned to each router in a routing domain or protocol. RIDs are used by routing protocols such as OSPF, IS-IS, EIGRP, BGP, etc., to identify neighbors, exchange routing information, elect designated routers (DRs), etc. RIDs are usually derived from one of the IP addresses configured on the router's interfaces or loopbacks, or manually specified by network administrators. RIDs must be unique within a routing domain or protocol instance. is that the loopback interface state Loopback interface Loopback interface is a virtual interface on a router that does not correspond to any physical port or connection. Loopback interfaces are used for various purposes such as testing network connectivity, providing stable router IDs for routing protocols, providing management access to routers, etc. Loopback interfaces have some advantages over physical interfaces such as being always up unless administratively shut down, being independent of any hardware failures or link failures, being able to assign any IP address regardless of subnetting constraints, etc. Loopback interfaces are usually numbered from zero (e.g., loopback0) upwards on routers. Loopback interfaces can also be created on PCs or servers for testing or configuration purposes using special IP addresses reserved for loopback testing (e.g., 127.x.x.x for IPv4 or ::1 for IPv6). Loopback interfaces are also known as virtual interfaces or dummy interfaces. Loopback interface state Loopback interface state refers to whether a loopback interface is up or down on a router. A loopback interface state can be either administratively controlled (by using commands such as no shutdown or shutdown) or automatically determined by routing protocols (by using commands such as passive-interface or ip ospf network point-to-point ). A loopback interface state affects how routing protocols use the IP address assigned to the loopback interface for neighbor discovery, router ID selection, route advertisement, etc. A loopback interface state can also affect how other devices can access or ping the loopback interface. A loopback interface state can be checked by using commands such as show ip interfacebrief or show ip ospf neighbor. is independent of any physical interface and reduces routing updates.
The loopback interface state is independent of any physical interface because it does not depend on any hardware or link status. This means that the loopback interface state will always be up unless it is manually shut down by an administrator. This also means that the loopback interface state will not change due to any physical failures or link failures that may affect other interfaces on the router.
The loopback interface state reduces routing updates because it provides a stable router ID for OSPF that does not change due to any physical failures or link failures that may affect other interfaces on the router. This means that OSPF will not have to re-elect DRs Designated Routers (DRs) Designated Routers (DRs) are routers that are elected by OSPF routers in a broadcast or non-broadcast multi- access (NBMA) network to act as leaders and coordinators of OSPF operations in that network. DRs are responsible for generating link-state advertisements (LSAs) for the entire network segment, maintaining adjacencies with all other routers in the segment, and exchanging routing information with other DRs in different segments through backup designated routers (BDRs). DRs are elected based on their router priority values and router IDs. The highest priority router becomes the DR and the second highest priority router becomes the BDR. If there is a tie in priority values, then the highest router ID wins. DRs can be manually configured by setting the router priority value to 0 (which means ineligible) or 255 (which means always eligible) on specific interfaces. DRs can also be influenced by using commands such as ip ospf priority, ip ospf dr-delay, ip ospf network point-to-multipoint, etc. DRs can be verified by using commands such as show ip ospf neighbor, show ip ospf interface, show ip ospf database, etc ., recalculate SPT Shortest Path Tree (SPT) Shortest Path Tree (SPT) is a data structure that represents the shortest paths from a source node to all other nodes in a graph or network. SPT is used by link-state routing protocols such as OSPF and IS-IS to compute optimal routes based on link costs. SPT is built using Dijkstra's algorithm, which starts from the source node and iteratively adds nodes with the lowest cost paths to the tree until all nodes are included. SPT can be represented by a set of pointers from each node to its parent node in the tree, or by a set of next-hop addresses from each node to its destination node in the network. SPT can be updated by adding or removing nodes or links, or by changing link costs. SPT can be verified by using commands such as show ip route, show ip ospf database, show clns route, show clns database, etc ., or send LSAs Link-State Advertisements (LSAs) Link-State Advertisements (LSAs) are packets that contain information about the state and cost of links in a network segment. LSAs are generated and flooded by link-state routing protocols such as OSPF and IS-IS to exchange routing information with other routers in the same area or level. LSAs are used to build link- state databases (LSDBs) on each router, which store the complete topology of the network segment.
LSAs are also used to compute shortest path trees (SPTs) on each router, which determine the optimal routes to all destinations in the network. LSAs have different types depending on their origin and scope, such as router LSAs, network LSAs, summary LSAs, external LSAs, etc. LSAs have different formats depending ontheir type and protocol version, but they usually contain fields such as LSA header, LSA type, LSA length, LSA age, LSA sequence number, LSA checksum, LSA body, etc. LSAs can be verified by using commands such as show ip ospf database, show clns database, debug ip ospf hello, debug clns hello, etc. due to changes in router IDs.
The other options are not reasons because:
- The IP address associated with the loopback interface is non-routable and prevents loops: This option is false because the IP address associated with the loopback interface is routable and does not prevent loops. The IP address associated with the loopback interface can be any valid IP address that belongs to an existing subnet or a new subnet created specifically for loopbacks. The IP address associated with the loopback interface does not prevent loops because loops are caused by misconfigurations or failures in routing protocols or devices, not by IP addresses.
- The loopback interface state is dependent on the management interface state and reduces routing updates: This option is false because the loopback interface state is independent of any physical interface state, including the management interface state Management interface Management interface is an interface on a device that provides access to management functions such as configuration, monitoring, troubleshooting, etc. Management interfaces can be physical ports such as console ports, Ethernet ports, USB ports, etc., or virtual ports such as Telnet sessions, SSH sessions, web sessions, etc. Management interfaces can use different protocols such as CLI Command-Line Interface (CLI) Command-Line Interface (CLI) is an interactive text-based user interface that allows users to communicate with devices using commands typed on a keyboard. CLI is one of the methods for accessing management functions on devices such as routers, switches, firewalls, servers, etc. CLI can use different protocols such as console port serial communication protocol Serial communication protocol Serial communication protocol is a method of transmitting data between devices using serial ports and cables. Serial communication protocol uses binary signals that represent bits (0s and 1s) and sends them one after another over a single wire. Serial communication protocol has advantages such as simplicity, low cost, long


NEW QUESTION # 30
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