A. It will flood it out of all interfaces, except for the ingress interface.
B. It will flood it out of all interfaces, except for the directly connected VLAN.
C. It will flood it out of all interfaces, except for the next-hop interface.
D. It will flood it out of all interfaces.
A. Excessive broadcast traffic
B. Mismatched VLAN configurations
C. Identical IP addresses on all LAG interfaces
D. Overutilization of CPU resources
A. To provide a gateway for VLAN traffic.
B. To prioritize VLAN traffic.
C. To filter VLAN traffic based on MAC addresses.
D. To encrypt VLAN traffic.
A. 2
B. 6
C. 5
D. 3
A. By providing a backup path for data in case of link failure.
B. By enabling the identification and separation of traffic belonging to different VLANs.
C. By encrypting data traffic between VLANs.
D. By ensuring the same IP address range can be used in different VLANs.
A. Each device in an EBGP fabric will be configured in its own unique private AS.
B. An EBGP fabric relies on an IGP to advertise loopback IPs.
C. An EBGP fabric does not require an IGP to advertise loopback IPs.
D. Each device in an EBGP fabric will be configured to be part of the same private AS.
A. Default-Free Zone
B. Virtual Link Area
C. Stub Area
D. Not-So-Stubby Area (NSSA)
A. To dynamically manage the bundling of several physical ports
B. To provide a method for encrypting data packets
C. To increase the error rate in data transmission
D. To reduce the speed of data transfer
A. Reduce the overall size of the routing table.
B. Summarize external routes into the network.
C. Manually configure specific network routes.
D. Automatically create a route when a specified condition is met.
A. BGP
B. OSPF
C. IS-IS
D. PIM
