This page was exported from Exam for engine [ http://blog.test4engine.com ]

Export date:Mon Nov 18 3:37:26 2024 / +0000 GMT

___________________________________________________


Title: Verified HPE6-A85 dumps Q&As - 2023 Latest HPE6-A85 Download [Q37-Q58]

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



 Verified HPE6-A85 dumps Q&As - 2023 Latest HPE6-A85 Download
Dumps Questions [2023] Pass for HPE6-A85 Exam


The Aruba Campus Access Associate certification exam is an excellent opportunity for those who want to enhance their career in the wireless networking industry. Aruba Campus Access Associate Exam certification is recognized globally and is a valuable addition to the candidate's resume. Aruba Campus Access Associate Exam certification also helps the candidate to demonstrate their skills and knowledge in the field of wireless networking and provides them with a competitive edge over their peers.

HP HPE6-A85 (Aruba Campus Access Associate) Certification Exam is a highly sought-after certification exam in the IT industry. It is specifically designed for IT professionals who are looking to enhance their skills and knowledge in implementing and managing Aruba wireless networks. Aruba Campus Access Associate Exam certification exam is ideal for network administrators, systems engineers, and technicians who have experience in implementing and managing Aruba wireless networks.
 


NO.37 A customer has just implemented user and device certificates via a company-wide Group Based Policy (GPO) Which EAP method requires client certificates when authenticating to the network?
 EAP-TTLS
 EAP-TLS
 EAP-TEAP
 PEAP
ExplanationEAP-TLS is an authentication method that requires client certificates when authenticating to the network. It provides mutual authentication between the client and the server using public key cryptography and digital certificates.References:https://www.arubanetworks.com/techdocs/ClearPass/6.9/Guest/Content/CPPM_UserGuide/EAP-TLSNO.38 You have been asked to onboard a new Aruba 6300M in a customer deployment You are working remotely rather than on-site You have a colleague installing the switch The colleague has provided you with a remote console session to configure the edge switch You have been asked to configure a link aggregation going back to the cores using interfaces 1/1/51 and 1/1/52 The Senior Engineer of the project has asked you to configure the switch and 1Q uplink with these guidelines1. Add VLAN 20 to the local VLAN database with name Mgmt2. Add L3 SVl on VLAN 20 for Management using address 10 in the 10.1.1 0/24 subnet 3. Add LAG 1 using LACP mode active for the uplink4 use vlan 20 as the native vlan on the LAG 5. Make sure the interfaces are all ON.Which configuration script will achieve the task?
 Edge1# conf t vlan 20 name Mgmt interface vlan 20 ip address 10.1.1.10/24 no shut interface lag 1 shut vlan access 20 lacp mode active Int 1/1/51.1/1/52 shut no routing lag 1 interface lag 1 no shut
 Edgel# conf t vlan 20 name Mgmt interface vlan 20 ip address 10 1.1 10/24 no shut interface1/1/51.1/1/52 shut vlan trunk native 20 vlan trunk allowed all lag 1 lacp mode active interface 1/1/51.1/1/52 no shut
 Edgel# conf t vlan 20 name Mgmt interface vlan 20 ip address 10 1 1 10/24 no shut interface lag 1 shut vlan trunk native 20 vlan trunk allowed all lacp mode active Int 1/1/51.1/1/52 shut no routing lag 1 interface lag 1 no shut interface 1/1/51.1/1/52 no shut
 conf t vlan 20 name Mgmt ip address 10 1 1.10/24 no shut interface lag 1 shut vlan trunk native 1 vlan trunk allowed all lacp mode active int 1/1/51.1/1/52 shut no routing interface lag 1 no shut interface1/1/51.1/1/52 no shut
ExplanationThis configuration script will achieve the task as it follows the guidelines given by the Senior Engineer. It creates VLAN 20 with name Mgmt, adds L3 SVI on VLAN 20 with IP address 10.1.1.10/24, creates LAG 1 with LACP mode active for the uplink, uses VLAN 20 as the native VLAN on the LAG, and ensures that the interfaces are all ON.References:https://www.arubanetworks.com/techdocs/AOS-CX/10.04/HTML/5200-6790/GUID-8F0E7E8B-0F4NO.39 A hospital uses a lot of mobile equipment for the diagnosis and documentation of patient data What Is the ideal access switch for this large hospital with distribution racks of over 400 ports in a single VSF stack?
 CX 6300
 OCX 6400
 OCX 6200
 OCX 6100
ExplanationThe ideal access switch for a large hospital with distribution racks of over 400 ports in a single VSF stack is the CX 6300. This switch provides the following benefits:The CX 6300 supports up to 48 ports per switch and up to 10 switches per VSF stack, allowing for a total of 480 ports in a single stack. This meets the requirement of having over 400 ports in a single VSF stack.The CX 6300 supports high-performance switching with up to 960 Gbps of switching capacity and up to714 Mpps of forwarding rate. This meets therequirement of having high throughput and low latency for mobile equipment and patient data.The CX 6300 supports advanced features such as dynamic segmentation, policy-based routing, and role-based access control. These features enhance the security and flexibility of the network by applying different policies and roles to different types of devices and users.The CX 6300 supports Aruba NetEdit, a network configuration and orchestration tool that simplifies the management and automation of the network. This reduces the complexity and human errors involved in network configuration and maintenance.The other options are not ideal because:OCX 6400: This switch is designed for data center applications and does not support VSF stacking. It also does not support dynamic segmentation or policy-based routing, which are useful for network security and flexibility.OCX 6200: This switch is designed for small to medium-sized businesses and does not support VSF stacking. It also has lower switching capacity and forwarding rate than the CX 6300, which may affect the performance of the network.OCX 6100: This switch is designed for edge applications and does not support VSF stacking. It also has lower switching capacity and forwarding rate than the CX 6300, which may affect the performance of the network.References: https://www.arubanetworks.com/assets/ds/DS_CX6300Series.pdfhttps://www.arubanetworks.com/assets/ds/DS_OC6400Series.pdfhttps://www.arubanetworks.com/assets/ds/DS_OC6200Series.pdfhttps://www.arubanetworks.com/assets/ds/DS_OC6100Series.pdfNO.40 Based on the given topology, what is the requirement on an Aruba switch to enable LLDP messages to be received by Switch 1 port 1/1/24. when Router 1 is enabled with LLDP?
 LLDP is enabled by default
 global configuration lldp enable
 int 1/1/24, lldp receive
 int 1/1/24, no cdp
ExplanationLLDP Link Layer Discovery Protocol. LLDP is a vendor-neutral link layer protocol used by network devices for advertising their identity, capabilities, and neighbors on a local area network. is enabled by default on Aruba switches, but it can be disabled on a per-port basis using the no lldp command. To enable LLDP messages to be received by Switch 1 port 1/1/24, you need to enter the interface configuration mode for that port and use the lldp receive command.References:https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/lldp/lNO.41 Which device configuration group types can a user define in Aruba Central during group creation? (Select two.)
 Security group
 Template group
 Default group
 Ul group
 ESP group
ExplanationAruba 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.htmhttps://www.arubanetworks.com/techdocs/Central/latest/content/nms/template-groups.htmhttps://www.arubanetworks.com/techdocs/Central/latest/content/nms/default-group.htmNO.42 Which Protocol Data Unit (PDU) represents the data link layer PDU?
 PDU1 – Signal
 PDU2 – Frame
 PDU3 – Packet
 PDU4 – Segment
ExplanationA frame is the data link layer PDU that encapsulates the network layer PDU (packet) with a header and a trailer that contain information such as source and destination MAC addresses, frame type, error detection, etc.A frame is transmitted over a physical medium such asEthernet, Wi-Fi, etc.References:https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/1-oveNO.43 A network technician is using Aruba Central to troubleshoot network issues Which dashboard can be used to view and acknowledge issues when beginning the troubleshooting process?
 the Alerts and Events dashboard
 the Audit Trail dashboard
 the Reports dashboard
 the Tools dashboard
ExplanationThe Alerts and Events dashboard displays all types of alerts and events generated for events pertaining to device provisioning, configuration, and user management. You can use the Config icon to configure alerts and notifications for different alert categories and severities . You can also view the alerts and events in the List view and Summary view2. References:https://www.arubanetworks.com/techdocs/central/latest/content/nms/alerts/configuring-alerts.htm 2https://www.arubanetworks.com/techdocs/central/latest/content/nms/alerts/viewing-alerts.htmNO.44 What happens when the signal from an AP weakens by being absorbed as it moves through an object?
 APs will use bonded channels to decrease latency to clients
 Signal to Noise Ratio (SNR) increases
 Signal to Noise Ratio (SNR) decreases
 Aruba Central dynamically moves clients to neighboring APs
ExplanationSignal to noise ratio (SNR) is a measure that compares the level of a desired signal to the level of background noise. SNR is defined as the ratio of signal power to the noise power, often expressed in decibels (dB). A high SNR means that the signal is clear and easy to detect or interpret, while a low SNR means that the signal is corrupted or obscured by noise and may be difficult to distinguish or recover1. When the signal from an AP Access Point. AP is a device that allows wireless devices to connect to a wired network using Wi-Fi, or related standards. weakens by being absorbed as it moves through an object, such as a wall or a furniture, the signal power decreases. This reduces the SNR and affects the quality of the wireless connection. The noise power may also increase due to interference from other sources, such as other APs or devices operating in the same frequency band2. Therefore, the correct answer is that SNR decreases when the signal from an AP weakens by being absorbed as it moves through an object. References: 1https://en.wikipedia.org/wiki/Signal-to-noise_ratio 2https://documentation.meraki.com/MR/Wi-Fi_Basics_and_Best_Practices/Signal-to-Noise_Ratio_%28SNR%29NO.45 Review the configuration below.Why would you configure OSPF to use the IP address 10.1.200.1 as the router ID?
 The IP address associated with the loopback interface is non-routable and prevents loops
 The loopback interface state is dependent on the management interface state and reduces routing updates.
 The IP address associated with the loopback interface is routable and prevents loops
 The loopback interface state Is independent of any physical interface and reduces routing updates.
ExplanationThe 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, longNO.46 What can be done to dynamically set the PoE Priority on a switch port when deploying IP cameras APs. and other PoE devices?
 Enable Quick PoE on the switch modules
 Enable profiling for device provisioning
 Configure PoE power management to Class-based Mode
 Configure PoE power management to Dynamic Mode
ExplanationProfiling is a feature that allows Aruba switches to automatically identify and classify devices connected to them based on various attributes such as MAC address, DHCP options, LLDP information, etc. Profiling can be used to dynamically set the PoE priority on a switch port based on the device type and power requirements.For example, an IP camera may have a higher PoE priority than a printer or a PC. Profiling can also be used to apply other configuration settings such as VLANs, ACLs, QoS, etc. based on the device profile.References:https://www.arubanetworks.com/techdocs/ArubaOS_86_Web_Help/Content/arubaos-solutions/1-oveNO.47 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?
 iP default-gateway 10.4.5.1
 ip route 0 0 0.070 10.4 5.1 vrf mgmt
 ip route 0.0 0 0/0 10.4.5.1
 default-gateway 10.4.5.1
ExplanationThe 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 ithttps://www.arubanetworks.com/techdocs/AOS-CX/10_08/HTML/ip_route_4100i-6000-6100-6200/Content/Ch2https://www.arubanetworks.com/techdocs/AOS-CX/10_08/HTML/ip_route_4100i-6000-6100-6200/Content/ChNO.48 Which statement is correct when comparing 5 GHz and 6 GHz channels with identical channel widths?
 5 GHz channels travel the same distances and provide different throughputs to clients compared to 6 GHz channels
 5 GHz channels travel different distances and provide different throughputs to clients compared to 6 GHz channels
 5 GHz channels travel the same distances and provide the same throughputs to clients compared to 6 GHz channels
 5 GHz channels travel different distances and provide the same throughputs to clients compared to 6 GHz channels
ExplanationThe correct statement when comparing 5 GHz and 6 GHz channels with identical channel widths is that 5 GHz channels travel different distances and provide different throughputs to clients compared to 6 GHz channels.This statement reflects the fact that higher frequency signals tend to have higher attenuation Attenuation is a general term that refers to any reduction in signal strength during transmission over distance or through an object or medium . Higher attenuation means that higher frequency signals have shorter range and lower throughput than lower frequency signals. Some facts about this statement are:5 GHz channels have lower frequency than 6 GHz channels, which means they have lower attenuation than 6 GHz channels.Lower attenuation means that 5 GHz channels can travel longer distances and provide higher throughputs to clients than 6 GHz channels with identical channel widths.However, the difference in distance and throughput between 5 GHz and 6 GHz channels may not be significant in indoor environments where there are many obstacles and reflections that affect signal propagation.The advantage of using 6 GHz channels over 5 GHz channels is that they offer more spectrum availability, less interference, and more non-overlapping channels than 5 GHz channels.The other options are not correct because:5 GHz channels travel the same distances and provide different throughputs to clients compared to 6 GHz channels: This option is false because 5 GHz channels do not travel the same distances as 6 GHz channels due to higher attenuation of higher frequency signals.5 GHz channels travel the same distances and provide the same throughputs to clients compared to 6 GHz channels: This option is false because 5 GHz channels do not travel the same distances or provide the same throughputs as 6 GHz channels due to higher attenuation of higher frequency signals.5 GHz channels travel different distances and provide the same throughputs to clients compared to 6 GHz channels: This option is false because 5 GHz channels do not provide the same throughputs as6 GHz channels due to higher attenuation of higher frequency signals.References: https://www.wi-fi.org/discover-wi-fi/wi-fi-certified-6ehttps://www.wi-fi.org/file/wi-fi-alliance-spectrum-needs-studyhttps://www.cisco.com/c/en/us/support/docs/wireless-mobility/wireless-lan-wlan/82068-power-levels.htmlhttps://www.cisco.com/c/en/us/products/collateral/wireless/spectrum-expert-wi-fi/prod_white_paper0900aecd80NO.49 When using an Aruba standalone AP you select “Native VLAN” for the Client VLAN Assignment In which subnet will the client IPs reside?
 The same subnet as the mobility controller
 The same subnet as the Aruba ESP gateway
 The same subnet as the mobility conductor
 The same subnet as the access point
ExplanationWhen using an Aruba standalone AP, selecting “Native VLAN” for the Client VLAN Assignment means that the clients will get their IP addresses from the same subnet as the access point’s IP address. This is because the access point acts as a DHCP server for the clients in this mode.References:https://www.arubanetworks.com/techdocs/Instant_86_WebHelp/Content/instant-ug/iap-dhcp/iap-dhcNO.50 Based on the “snow ip route” output on an AruDaCX 8400. what type of route is “10.1 20 0/24, vrf default via10.1.12.2. [1/0]”?
 local
 static
 OSPF
 connected
ExplanationA static route is a route that is manually configured on a router or switch and does not change unless it is modified by an administrator. Static routes are used to specify how traffic should reach specific destinations that are not directly connected to the device or that are not reachable by dynamic routing protocols. In Aruba CX switches, static routes can be configured using the ip route command in global configuration mode. Based on the “show ip route” output on an Aruba CX 8400 switch, the route “10.1 20 0/24, vrf default via 10.1.12.2,[1/0]” is a static route because it has an administrative distance of 1 and a metric of 0, which are typical values for static routes. References: https://en.wikipedia.org/wiki/Static_routinghttps://www.arubanetworks.com/techdocs/AOS-CX_10_04/NOSCG/Content/cx-noscg/ip-routing/static-routes.hNO.51 When performing live firmware upgrades on Aruba APs. which technology partitions all the APs based on RF neighborhood data minimizing the impact on clients?
 Aruba ClientMatch
 Aruba Ai insights
 Aruba AirMatch
 Aruba ESP
ExplanationAruba AirMatch is a feature that optimizes RF Radio Frequency. RF is any frequency within the electromagnetic spectrum associated with radio wave propagation. When an RF current is supplied to an antenna, an electromagnetic field is created that then is able to propagate through space. performance and user experience by using machine learning algorithms and historical data to dynamically adjust AP power levels, channel assignments, and channel width. AirMatch performs live firmware upgrades on Aruba APs by partitioning all the APs based on RFneighborhood data and minimizing the impact on clients. AirMatch uses a rolling upgrade process that upgrades one partition at a time while ensuring that adjacent partitions are not upgraded simultaneously. References:https://www.arubanetworks.com/assets/ds/DS_AirMatch.pdfhttps://www.arubanetworks.com/techdocs/ArubaOSNO.52 Describe the purpose of the administrative distance
 Routes teamed via external BGP have a higher administrative distance than routes learned via OSPF
 The administrative distance is used as a trust rating tor route entries
 The administrative distance for a static route is 10
 The higher administrative distance is preferred
NO.53 What is the ideal Aruba access switch for a cost-effective connection to 200-380 clients, printers and APs per distribution rack?
 Aruba CX 6400
 Aruba CX 6200
 Aruba CX 6300
 Aruba CX 6000
ExplanationThe ideal Aruba access switch for a cost-effective connection to 200-380 clients, printers and APs per distribution rack is the Aruba CX 6200. This switch series is a cloud-manageable, stackable access switch series that is ideal for enterprise branch offices and campus networks, as well as SMBs. The CX 6200 series offers the following benefits:Enterprise-class connectivity: The CX 6200 series supports ACLs, robust QoS, and common protocols such as static and Access OSPF routing.Power and speed for users and IoT: The CX 6200 series provides built-in 1/10GbE uplinks and 30W to60W of Class 4 to Class 6 PoE for powering devices such as APs and cameras.Scalable growth made simple: The CX 6200 series supports Aruba Virtual Switching Framework (VSF) that allows you to quickly grow your network to eight members in a single stack using high-performance built-in 10G SFP ports.Management flexibility: The CX 6200 series supports a choice of management, including cloud-based and on-prem Central, CLI, switch Web GUI and programmability with AOS-CX operating system, and REST APIs.The other options are not ideal because:Aruba CX 6400: This switch series is a high-availability modular switch series that is ideal for versatile edge access to data center deployments. It offers more performance, scalability, and modularity than the CX 6200 series, but it is also more expensive and complex to deploy and manage. It may not be cost-effective for connecting 200-380 clients per distribution rack.Aruba CX 6300: This switch series is a layer 3 stackable access and aggregation switch series that offers Smart Rate and High Power PoE. It offers more features and performance than the CX 6200 series, but it is also more expensive and may not be necessary for connecting 200-380 clients per distribution rack.Aruba CX 6000: This switch series is a layer 2 access switch series that offers PoE. It offers less features and performance than the CX 6200 series, and it does not support VSF stacking or routing protocols. It may not be sufficient for connecting 200-380 clients per distribution rack.References: https://www.arubanetworks.com/products/switches/access/https://www.arubanetworks.com/products/switches/access/6200-series/https://www.arubanetworks.com/products/switches/access/6400-series/https://www.arubanetworks.com/products/switches/access/6300-series/https://www.arubanetworks.com/products/switches/access/6000-series/NO.54 After having configured the edge switch uplink as requested your colleague says that they have failed to ping the core You ask your colleague to verify the connection is plugged in and the switch is powered on They confirm that both are correct You attempt to ping the core switch and confirm that the ping is failing.Knowing the nature of this deployment, what commands might you use to troubleshoot this issued
 Ping 10.11 1 – ping the core to attempt to verify connectivity Show trunk – to verify if the LAG interface was correctly added to the switch Show spanning tree – to check for spanning-tree blocked states Show port-access clients interface all – to view any port-access blocking states or failed authentication attempts on all interfaces Show run interface vlan20 – to double check the layer 3 svi configuration is correct for l_3 connectivity Show lldp neighors – to verify whether you are able to see the Core as an L2 neighbor to verify if the correct links are plugged in to the correct ports
 diagnostic diag cable-diag 1/1/51 diag cable-diag 1/1/52 – to view diagnostic information for the physical link to get a status on any interruptions to Layer 1 connectivity, show ip route – to verify that the default gateway is present in the routing table show ip ospf – to check whether there is a layer 3 routing protocol enabled show ip dns – to view whether there is a valid dns source
 Ping 10.1.1.1 – ping the core to attempt to verify connectivity show lacp agg – to verify which link aggregations are currently configured using which physical ports show lacp int – to verify the LACP status and whether any links are blocking in your topology show lldp neighors – to verify whether you are able to see the Core as an L2 neighbor to verify if the correct links are plugged in to the correct ports show run interface 1/1/51.1/1/52-to ensure the physical interfaces are no-shut and members of the lag show run interface lag 1 – to ensure the correct vlan trunking configuration is applied to the logical interface show run int vlan 20 – to ensure you have the L3 SVI no shut and configured in the correct subnet
 Show run – to view the running configuration of the switch Show run | begin 20 “vlan 20” – to ensure VLAN 20 was correctly added to the database show run | begin 20 ‘interface vlan 20’ – to view the L3 SVI configuration Show run interface 1/1/51.1/1/52 – to ensure the physical interfaces are no shut and were added as members of LAG 1 Show run int lag 1 – to verify LACP mode active was configured to eliminate LACP blocking states
ExplanationThese commands might help troubleshoot this issue as they check various aspects of the connectivity between the edge switch and the core switch, such as Layer 3 reachability, Layer 2 adjacency, LACP configuration and status, VLAN trunking configuration, and interface status.References:https://www.arubanetworks.com/techdocs/AOS-CX_10_04/CLI/GUID-8F0E7E8B-0F4B-4A3C-AE7NO.55 A network administrator with existing IAP-315 access points is interested in Aruba Central and needs to know which license is required for specific features Please match the required license per feature (Matches may be used more than once.)
Explanationa) Alerts on config changes via email – Foundation b) Group-based firmware compliance – Foundation c) Heat maps of deployed APs – Advanced d) Live upgrades of an AOS10 cluster – Advanced According to the Aruba Central Licensing Guide1, the Foundation License provides basic device management features such as configuration, monitoring, alerts, reports, firmware management, etc. The Advanced License provides additional features such as AI insights, WLAN services, NetConductor Fabric, heat maps, live upgrades, etc.https://www.arubanetworks.com/techdocs/central/2.5.3/content/pdfs/licensing-guide.pdfNO.56 Which statement about manual switch provisioning with Aruba Central is correct?
 Manual provisioning does not require DHCP and requires DNS
 Manual provisioning does not require DHCP and does not require DNS
 Manual provisioning requires DHCP and does not require DNS
 Manual provisioning requires DHCP and requires DNS
ExplanationManual provisioning is a method to add switches to Aruba Central without using DHCP or DNS. It requires the user to enter the switch serial number, MAC address, and activation code in Aruba Central, and then configure the switch with the same activation code and Aruba Central’s IP address.References:https://help.central.arubanetworks.com/latest/documentation/online_help/content/devices/switches/prNO.57 Match the appropriate QoS concept with its definition.
ExplanationQoS Quality of Service (QoS) is a set of techniques that manage network resources and provide different levels of service to different types of traffic based on their requirements. QoS can improve network performance, reduce latency, increase throughput, and prevent congestion. concept and its definition. Here is my answer:QoS Concept:Best Effort ServiceClass of ServiceDifferentiated ServicesWMM ====================== Definition:d) A method where traffic is treated equally in a first-come, first-served manner a) A method for classifying network traffic at Layer 2 by marking 802.1Q VLAN Ethernet frames with one of eight service classes b) A method for classifying network traffic at Layer 3 by marking packets with one of 64 different service classes c) A method for classifying network traffic using access categories based on the IEEE 802.11e QoS standard Short But Comprehensive Explanation of Correct Answer Only: The correct match between QoS concept and its definition is as follows:Best Effort Service: This is a method where traffic is treated equally in a first-come, first-served manner without any prioritization or differentiation. This is the default service level for most networks and applications that do not have specific QoS requirements or guarantees. Best Effort Service does not provide any assurance of bandwidth, delay, jitter, or packet loss.Class of Service: This is a method for classifying network traffic at Layer 2 by marking 802.1Q VLAN Ethernet frames with one of eight service classes (0 to 7). These service classes are also known as IEEE802.1p priority values or PCP Priority Code Point (PCP) is a 3-bit field in the 802.1Q VLAN tag that indicates the priority level of an Ethernet frame . Class of Service allows network devices to identify and handle different types of traffic based on their priority levels. Class of Service is typically used in LAN Local Area Network (LAN) is a network that connects devices within a limited geographic area, such as a home, office, or building environments where Layer 2 switching is predominant.Differentiated Services: This is a method for classifying network traffic at Layer 3 by marking packets with one of 64 different service classes (0 to 63). These service classes are also known as DiffServ Code Points (DSCP) DiffServ Code Point (DSCP) is a 6-bit field in the IP header that indicates the service class of a packet . Differentiated Services allows network devices to identify and handle different types of traffic based on their service classes. Differentiated Services is typically used in WAN Wide Area Network (WAN) is a network that connects devices across a large geographic area, such as a country or continent environments where Layer 3 routing is predominant.WMM: This is a method for classifying network traffic using access categories based on the IEEE802.11e QoS standard. WMM stands for Wi-Fi Multimedia and it is a certification program developed by the Wi-Fi Alliance to enhance QoS for wireless networks. WMM defines four access categories (AC): Voice, Video, Best Effort, and Background. These access categories correspond to different priority levels and contention parameters for wireless traffic. WMM allows wireless devices to identify and handle different types of traffic based on their access categories.References: https://en.wikipedia.org/wiki/Quality_of_servicehttps://www.cisco.com/c/en/us/td/docs/ios-xml/ios/qos_dfsrv/configuration/xe-16/qos-dfsrv-xe-16-book/qos-dfsrhttps://www.cisco.com/c/en/us/support/docs/wireless-mobility/wireless-lan-wlan/81831-qos-wlan.htmlhttps://www.wi-fi.org/discover-wi-fi/wi-fi-certified-wmmNO.58 Which feature can network administrators use to centralized RF planning and optimization service when using an Aruba mobility master architecture?
 Airwave
 Client Match
 AirMatch
 Client Wave
ExplanationAirMatch is a feature that provides centralized RF planning and optimization service for Aruba wireless networks. It uses cloud-based algorithms and machine learning to optimize the RF performance and user experience. References:https://www.arubanetworks.com/assets/ds/DS_AirMatch.pdf Loading …






	
	

Updated HP Study Guide HPE6-A85 Dumps Questions: https://www.test4engine.com/HPE6-A85_exam-latest-braindumps.html


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


Images: https://blog.test4engine.com/wp-content/plugins/watu/loading.gif
https://blog.test4engine.com/wp-content/plugins/watu/loading.gif


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




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


Post date: 2023-11-08 15:50:10

Post date GMT: 2023-11-08 15:50:10

Post modified date: 2023-11-08 15:50:10

Post modified date GMT: 2023-11-08 15:50:10