Chapter 1) Implementing Routing in the Data Center

Question 1

Describe the role of OSPF Hello-Packets

Answer 1

Hello packets are sent out on each OSPF-enabled interface to discover other OSPF neighbor routers. In addition, OSPF uses hello packets for keepalive and bidirectional traffic.

Question 2

What are the default OSPF Hello & Dead intervals?

Answer 2

Default Hello interval is 10 seconds

Default Dead interval is 4 times the hello interval (40 seconds)

Question 3

What algorithm is used by routers in OSPF to built a routing table?

Answer 3

Dijkstra’s Shortest Path First (SPF) algorithm

Question 4

What are the multicast addresses used in OSPF versions 2 & 3 for sending Hello messages to adjacent routers?

Answer 4

OSPF Version 2 (IPv4): 224.0.0.5

OSPF Version 3 (IPv6): FF02::05

Question 5

What are addresses and subnet masks referred to as in OSPF version 3

Answer 5

Prefix, and Prefix Length respectively

Question 6

Which version of OSPF supports BFD? (Bidirectional Forwarding Detection)

Answer 6

OSPF version 2 only

Question 7

How often are OSPF LSAs flooded by default?

Answer 7

LSAs are flooded based on the link-state refresh time (every 30 minutes by default).

Question 8

Define OSPF Opaque LSAs and the 3 LSA types that fall under this category

Answer 8

Opaque LSAs consist of a standard LSA header followed by application-specific information.

LSA type 9: Flooded to the local network.
LSA type 10: Flooded to the local area.
LSA type 11: Flooded to the local autonomous system

Question 9

Define a Type 1 LSA in OSPF versions 2 & 3

Answer 9

Type 1 LSAs are referred to as Router LSAs in OSPF versions 2 & 3

• Sent from all OSPF-enabled routers and flooded into the local OSPF area
• Contains the costs of all links and a list of OSPF neighbors on the link

Question 10

Define a Type 2 LSA in OSPF versions 2 & 3

Answer 10

Type 2 LSAs are referred to as Network LSAs in OSPF versions 2 & 3

• Sent only by the DR and flooded to all other routers in the local OSPF area
• Lists all routers in the multi-access network

Question 11

Define a Type 3 LSA in OSPF version 2 & 3

Answer 11

Type 3 LSAs are referred to as Network Summary LSAs in OSPF version 2
Type 3 LSAs are referred to as Inter-Area Prefix LSAs in OSPF version 3
- LSA sent by the Area Border Router (ABR) to an external area
- Includes the link cost from the Area Border Router (ABR) to the local destination

Question 12

Define a Type 4 LSA in OSPF versions 2 & 3

Answer 12

Type 4 LSAs are referred to as ASBR Summary LSAs in OSPF version 2
Type 4 LSAs are referred to as Inter-Area Router LSAs in OSPF version 3
- Sent by the Area Border Router (ABR) to an external area.
- This LSA advertises the link cost to the ASBR only.

Question 13

Define a Type 5 LSA in OSPF versions 2 & 3

Answer 13

Type 5 LSAs are referred to as AS External LSAs in OSPF versions 2 & 3

• Generated by the ASBR.
• Includes the link cost to an external autonomous system.
• AS External LSAs are flooded throughout the autonomous system.

Question 14

Define a Type 7 LSA in OSPF versions 2 & 3

Answer 14

Type 7 LSAs are referred to as NSSA External LSAs in OSPF versions 2 & 3

• Generated by the ASBR within a not-so-stubby area (NSSA)
• Includes the link cost to an external autonomous system destination.
• NSSA External LSAs are flooded only within the local NSSA.

Question 15

Describe the LSA group pacing feature

Answer 15

Used to reduce high CPU or buffer usage. This feature groups LSAs with similar link-state refresh times and packs multiple LSAs into a single OSPF update message.

Question 16

Describe the OSPF Max Age Timer

Answer 16

The Max Age timer represents the maximum interval that an LSA can remain in the LSDB without being updated via an OSPF UPDATE message. When the Max Age timer expires for an LSA, it is removed from the LSDB.

Question 17

Describe an OSPF Area

Answer 17

A logical division of routers and links within an OSPF domain that creates separate subdomains.
- LSDB flooding is contained within an area

Question 18

Define the term AS and the role of an ASBR

Answer 18

An Autonomous System (AS) is a a network controlled by a single organization or administrative entity. An Autonomous Systems Boundary Router (ASBR) is used to connects an OSPF area to a different Autonomous System (AS).

Question 19

Describe the function of an OSPF Stub Area & TSA

Answer 19

A stub area is an area that does not allow AS External (type 5) LSAs and does not contain or connect to an ASBR (Autonomous System Boundary Router). A regular stub area receives summarized routes for areas outside of the stubby area. A TSA (Totally-Stubby-Area) will only receive a default summary route of 0.0.0.0 /24 for all areas outside of the TSA.

Question 20

Describe the function of an OSPF NSSA & TNSSA

Answer 20

A Not-So-Stubby-Area (NSSA) is typically used to redistribute routes from other routing protocols such as RIP or BGP via the ASBR. A NSSA filters LSA types 4 & 5, whereas the Totally NSSA area filters types 3, 4, & 5.

Question 21

Describe an OSPF Virtual Link

Answer 21

All OSPF areas must have a direct connection back to the backbone area (Area 0). However, in some topologies, a direct physical connection to the backbone may not be available. An OSPF virtual link can be used to connect a distant area to the backbone through another area.

Question 22

What 2 authentication methods are supported by OSPF?

Answer 22

1) Simple password authentication

2) MD5 authentication digest

Question 23

What routing algorithm is used by Border Gateway Protocol (BGP)?

Answer 23

A path-vector routing algorithm to exchange routing information between BGP speakers.

Question 24

Describe BGP path selection

Answer 24

A single best-path is selected for a remote host or network. Each best-path carries well-known mandatory, well-known discretionary, and optional transitive attributes that are used in BGP best-path analysis.

Question 25

Describe the function of BGP ECMP.

Answer 25

Equal-Cost Multipath is a load-balancing feature where traffic can be carried over multiple “best-paths” that tie for top place in routing metric calculations. This offers better bandwidth utilization.

Question 26

What version of BGP is supported by Cisco NX-OS. What port and transport mechanism is utilized by BGP to establish BGP sessions?

Answer 26

Cisco NX-OS supports BGP version 4. BGP uses port 179 over TCP for establishing BGP sessions with peers.

Question 27

What size Autonomous System numbers are supported by BGP?

Answer 27

16-bit and 32-bit.

Question 28

What BGP peering types are supported by NX-OS?

Answer 28

BGP peers are not discovered automatically, they must be manually configured using one of the following:

1) Individual IPv4 or IPv4 address
2) IPv4 or IPv6 prefix peers for a single AS number
3) Dynamic AS number prefix peers

Question 29

What size is a BGP router-ID and what is the order for how it is chosen?

Answer 29

Router-IDs are 32-bit values represented as an IPv4 address, but are not used in any routing. Cisco NX-OS chooses a router ID in the following order:

1) A manually configured router ID is chosen first.
2) The loopback interface is chosen as the router ID.
3) The highest IP address associated with a physical interface is then chosen.

Question 30

What is the 1st step in the BGP Sequence for comparison of paths? (Assuming the path is valid)

Answer 30

Cisco NX-OS chooses the path with the highest WEIGHT.

Question 31

What is the 2nd step in the BGP Sequence for comparison of paths?

Answer 31

Cisco NX-OS chooses the path with the highest local preference (LOCAL_PREF).

Question 32

What is the 3rd step in the BGP Sequence for comparison of paths?

Answer 32

Cisco NX-OS chooses the path that is locally originated (LOCAL_PATH).

Question 33

What is the 4th step in the BGP Sequence for comparison of paths?

Answer 33

Cisco NX-OS chooses the shorter AS_PATH.

Question 34

What is the 5th step in the BGP Sequence for comparison of paths?

Answer 34

Cisco NX-OS chooses the path with the lowest origin type. IGP is preferable to EGP.

Question 35

What is the 6th step in the BGP Sequence for comparison of paths?

Answer 35

Cisco NX-OS chooses the path with the lower multi-exit discriminator (MED).

Question 36

What is the 7th step in the BGP Sequence for comparison of paths?

Answer 36

NX-OS chooses the path from the external peer over the internal peer. EGP is preferable to IGP.

Question 37

What is the 8th step in the BGP Sequence for comparison of paths?

Answer 37

Cisco NX-OS chooses the path with the lower IGP metric.

Question 38

What is the 9th step in the BGP Sequence for comparison of paths?

Answer 38

Cisco NX-OS uses the path that was selected by the best-path algorithm the last time that it was run.

Question 39

What is the 10th step in the BGP Sequence for comparison of paths?

Answer 39

Cisco NX-OS selects the path with the shorter cluster length.

Question 40

What is the 11th step in the BGP Sequence for comparison of paths?

Answer 40

Cisco NX-OS chooses the path received from the peer with the lower IP address.

Question 41

What is the 1st step in the BGP Sequence for determining the order of path comparisons?

Answer 41

Cisco NX-OS partitions the paths into groups. Within each group, Cisco NX-OS compares the MED among all paths.

Question 42

What is the 2nd step in the BGP Sequence for determining the order of path comparisons?

Answer 42

Cisco NX-OS determines the best path in each group by iterating through all paths in
the group and keeping track of the best one so far. A new best-path is chosen if it is better than the current best-path.

Question 43

What is the 3rd step in the BGP Sequence for determining the order of path comparisons?

Answer 43

Cisco NX-OS forms a set of paths that contain the best path selected from each group
in step 2. Cisco NX-OS selects the overall best path from this set of paths by going
through them as in step 2.

Question 44

What advantage is offered by Multiprotocol BGP (MBGP)?

Answer 44

Multiprotocol BGP (MBGP) can carry different sets of routes depending on the address family. For example, BGP can carry one set of routes for IPv4 unicast routing, one set of routes for IPv4 multicast routing, and one set of routes for IPv6 multicast routing.

Question 45

What is the default BGP Keepalive interval and hold timer?

Answer 45

Cisco NX-OS uses the following by default:

Keepalive interval: 60 seconds.
Hold timer: 180 seconds.

Question 46

Describe BFD and the operating mode supported by Cisco NX-OS?

Answer 46

Bidirectional Forwarding Detection (BFD) is a detection protocol designed to provide fast forwarding–path failure detection times for media types, encapsulations, topologies, and routing protocols.

Cisco NX-OS supports the BFD asynchronous mode, which sends BFD control packets between two adjacent devices to activate and maintain BFD neighbor sessions between the devices.

Question 47

What are the 3 session parameters supported by BFD in Cisco NX-OS?

Answer 47

Desired minimum transmit interval: The interval at which this device wants to send BFD hello messages.

Required minimum receive interval: The minimum interval at which this device can accept BFD hello messages from another BFD device.

Detect multiplier: The number of missing BFD hello messages from another BFD device before this local device detects a fault in the forwarding path.

Question 48

What is the definition and purpose of a multicast group?

Answer 48

A multicast IP address is referred to as a group. End devices subscribe to multicast groups to receive data.

Question 49

Describe the purpose of a multicast channel.

Answer 49

A channel is a multicast IP address that includes the multicast group and the source of the multicast transmission.

Question 50

What is the IANA (Internet Assigned Naming Authority) range of multicast messages for both IPv4 & IPv6?

Answer 50

The Internet Assigned Numbers Authority (IANA) has assigned:

224.0.0.0 through 239.255.255.255 as IPv4 multicast addresses.
IPv6 multicast addresses begin with 0xFF.

Question 51

Describe the function of IGMP.

Answer 51

The Internet Group Management Protocol (IGMP) is used by hosts that want to receive
multicast data to request membership in multicast groups. Once the group membership
is established, multicast data for the group is directed to the LAN segment of the
requesting host.

Question 52

What version(s) of IP (Internet Protocol) is supported by IGMP

Answer 52

IGMP only supports IPv4

Question 53

What is the default version of IGMP used when Cisco NX-OS enables the IGMP process?

Answer 53

By default, IGMPv2 is the version used. IGMPv3 must be enabled manually on the interfaces where its functionality wants to be used.

Question 54

What are the main key differences between IGMPv2 & IGMPv3?

Answer 54

IGMPv3 supports the following additional features:

• support for SSM (Source Specific Multicast) which can be used to build shortest path trees from receiver to source.
• hosts no longer perform report suppression, which means that hosts always send
  IGMP membership reports when an IGMP query message is received.

Question 55

What is the purpose of the IGMP designated querier?

Answer 55

An IGMP querier sends query messages to the all-hosts multicast group periodically to discover whether any hosts want to receive multicast data.

Question 56

What IP address is used for the all-hosts multicast IP group?

Answer 56

The all-hosts multicast IP (group) is 224.0.0.1.

Question 57

How is the IGMP querier for a multicast group elected?

Answer 57

The software elects an IGMP as the designated querier on the subnet if it has the lowest IP address. A router will drop its role as the querier if it receives a host query message from a router with a lower IP address.

Question 58

What is the function of IGMPv2 membership report suppression?

Answer 58

Only one membership report per group needs to be sent to the router. As such, other hosts suppress their reports to reduce network traffic.

Question 59

What is the TTL of a IGMP or MLD multicast message sent by a designated querier for a subnet?

Answer 59

The TTL (Time To Live) of this type of message is 1.

Question 60

What type of message is sent by an IGMP host that no longer wishes to subscribe to a multicast group?

Answer 60

A host running IGMPv2 or later will send an IGMP LEAVE message to the designated querier.

Question 61

What process occurs after a designated querier receives an IGMP LEAVE message from a host?

Answer 61

The designated querier will send out a query message to check if this is the last host that is subscribed to the multicast group. If a report is not received by a certain interval, then it is assumed that no other hosts are subscribed the group, and as such, the multicast group state is removed.

The configurable interval for the querier is referred to as the last member query response interval.

Question 61

What process occurs after a designated querier receives an IGMP LEAVE message from a host?

Answer 61

The designated querier will send out a query message to check if this is the last host that is subscribed to the multicast group. If a report is not received by a certain interval, then it is assumed that no other hosts are subscribed the group, and as such, the multicast group state is removed.

The configurable interval for the querier is referred to as the last member query response interval.

Question 62

Describe the purpose and function of Switch IGMP Snooping.

Answer 62

Switch IGMP Snooping is used to limit the amount of IGMP traffic being carried over a VLAN. The software listens for IGMP messages to determine which ports are multicast sources and receives. The software can then limit the amount of IGMP flooding to ports that are known IGMP hosts.

IGMP Snooping is enabled by default in Cisco NX-OS.

Question 63

What version(s) of IP are supported by MLD?

Answer 63

MLD (Multicast Listener Discovery) only supports IPv6.

Question 64

What protocol is MLD derived from?

Answer 64

MLDv1 is derived from IGMPv2

MLDv2 is derived from IGMPv3

Question 65

What IP protocol message types are supported by IGMP and MLD?

Answer 65

IGMP supports IP protocol 2 message types.

MLD supports IP protocol 58 message types.

Question 66

How is the MLD process started on a device?

Answer 66

The MLD process is started automatically on the device. You cannot enable MLD manually on an interface. MLD is enabled automatically when you perform one of the following configuration tasks on an interface:

• Enable PIM6.
• Statically bind a local multicast group.
• Enable link-local group reports.

Question 67

What is the default version of MLD used when the process first starts?

Answer 67

By default, the software enables MLDv2 when it starts the MLD process. You can enable MLDv1 on interfaces where you want only its capabilities.

Question 68

What are the main key differences between MLDv1 and MLDv2?

Answer 68

MLDv2 supports the following additional features:

• support for SSM (Source Specific Multicast) which can be used to build shortest path trees from receiver to source.
• hosts no longer perform report suppression, which means that hosts always send
  MLD listener reports when an MLD query message is received.

Question 69

What IP address range is reserved by the IANA for MLD multicast messages?

Answer 69

MLD utilizes link-local addresses in the range FF02::0/16.

Question 70

Define the function of an MDT.

Answer 70

A Multicast Distribution Tree is used to represent the path that multicast data takes between the routers that connect sources and receivers.

Question 71

Describe the function of a MDT source tree.

Answer 71

A MDT source tree is also referred to as a Shortest Path Tree (SPT). A source tree represents the shortest path that the multicast traffic takes through the network from source to receiver.

Question 71

Define the function of a MDT source tree?

Answer 71

A MDT source tree is also referred to as a Shortest Path Tree (SPT). A source tree represents the shortest path that the multicast traffic takes through the network from source to receiver.

Question 72

Describe the function of a MDT shared tree.

Answer 72

A MDT shared tree is also referred to as a RP Tree (RPT). A shared tree represents the
shared distribution path that the multicast traffic takes through the network from a shared root or rendezvous point (RP) to each receiver

Question 73

Describe the function of a MDT bidirectional shared tree.

Answer 73

A bidirectional shared tree represents the shared distribution path that the multicast traffic directly takes through the network from each source to each receiver.

Question 74

What is the key difference between a MDT shared tree and a bidirectional shared tree?

Answer 74

With a shared tree, multicast data must pass through the RP (Rendezvous Point) before reaching the receiver. Bidirectional shared trees allow data to be directly sent from source to receiver without having to first pass through the RP.

Question 74

What is the key difference between a MDT shared tree and a bidirectional shared tree?

Answer 74

With a shared tree, multicast data must pass through the RP (Rendezvous Point) before reaching the receiver. Bidirectional shared trees allow data to be directly sent from source to receiver without having to first pass through the RP.

Question 75

What is the version(s) of IP supported by PIM

Answer 75

Protocol Independent Multicast (PIM) supports the following:

• IPv4 for PIMv2
• IPv6 for PIMv6

Question 76

Describe the difference between PIM sparse mode and dense mode.

Answer 76

PIM sparse mode: this is a “pull” model where we only forward multicast traffic when requested.

PIM dense mode: this is a “push” model where we flood multicast traffic everywhere and then prune it when it’s not needed.

Question 77

What PIM mode is supported by Cisco NX-OS?

Answer 77

Only PIM sparse mode is supported by Cisco NX-OS. PIM dense mode is not available on Cisco NX-OS.

Question 78

What multicast protocols are enabled by default on the Cisco NX-OS system?

Answer 78

Internet Group Management Protocol (IGMP) and Multicast Listener Discovery (MLD) are enabled by default on Cisco NX-OS. The PIM sparse mode feature must be enabled manually before configuring multicast.

Question 79

Describe the role of MSDP in regards to PIM.

Answer 79

Multicast Source Discovery Protocol (MSDP) is used to allow for the discovery of multicast sources in other PIM domains.

Question 80

Describe the role of the DR in regards to PIM.

Answer 80

Designated Routers (DRs) are used to forward multicast traffic onto a LAN segment. When 2 or more routers are connected to the same segment, a single DR is elected between them.

Question 81

What version of IP is supported for MSDP?

Answer 81

Only IPv4 is supported for Multicast Source Discovery Protocol.

Question 82

How can sources be configured as peers if the reside in two separate PIM6 domains?

Answer 82

Multicast Source Discovery Protocol (MSDP) does not support IPv6 (PIM6). However, IPv6 peers can be configured using source-specific multicast (SSM) and multiprotocol BGP (MBGP). This will allow multicast forwarding between multiple PIM6 domains.

Question 83

What is the default mode of multicast groups for Cisco NX-OS?

Answer 83

By default, Cisco NX-OS uses ASM (Any Source Multicast) as its Multicast Distribution Tree (MDT).

Question 84

What PIM tree building mode(s) are supported by ASM?

Answer 84

Any Source Multicast (ASM) supports both shared and source trees. Protocol Independent Multicast (PIM) uses:

• shared trees to discover sources and receivers
• source trees to building the shortest path from source to receiver

Question 85

What PIM tree building mode(s) are supported by Bidir

Answer 85

Bidirectional Shared Trees (Bidir) only supports shared trees.

Question 86

Define a DF in regards to PIM Bidir.

Answer 86

The Designated Forwarder (DF) is the router that is connected to the receiver on the same LAN segment

Question 87

What PIM tree building mode(s) are supported by SSM

Answer 87

Source Specific Multicast (SSM) only supports source trees.

Question 88

What PIM tree building mode(s) require the configuration or discovery of a RP?

Answer 88

Any Source Multicast (ASM) and Bidirectional Shared Trees (Bidir) require the initial configuration of a Rendezvous Point (RP). However, Birdir can continue to carry multicast traffic whether or not the RP is active or connected.

Source Specific Multicast (SSM) does not require the configuration or discovery of an RP.

Question 89

Describe the function of the PIM hello message and define the following:

1) The multicast group associated with a PIM hello message.
2) The default hello interval.
3) The default hold-time value.

Answer 89

PIM hello messages are used to establish adjacencies and elect a designated router (DR) for the LAN segment.

1) The multicast group (IP) associated with PIM hello messages is 224.0.0.13.
2) The default hello interval is 30 seconds.
3) The default hold-time value is typically 3.5 times the hello interval.

Question 90

What is the process for electing a DR in PIM?

Answer 90

PIM begins by sending hellos containing information about the router.

1) The highest priority value is considered first.
2) If not, the router with the highest IP address is chosen.

Question 91

Describe the function of the PIM Join-Prune message are where they are sent to.

Answer 91

Protocol Independent Multicast (PIM) join-prune messages are used by the designated router (DR) to create a tree that connects the source to the receiver. The DR sends the join-prune messages to the RP in the PIM domain if ASM or Bidir are being used. Otherwise, if SSM is the mode being used, the join-prune message will be sent to the source directly.

Question 92

Describe the function of the PIM register message.

Answer 92

PIM register messages are unicast to the RP by designated routers that are directly connected to multicast sources. The PIM register message has the following functions:

• To notify the RP that a source is actively sending to a multicast group.
• To deliver multicast packets sent by the source to the RP for delivery down the shared tree.

Question 93

Describe the role of a PIM RP.

Answer 93

A rendezvous point (RP) is a router that you select in a multicast network domain that acts as a shared root for a multicast shared tree.

Question 93

Describe the role of a PIM RP.

Answer 93

A rendezvous point (RP) is a router that you select in a multicast network domain that acts as a shared root for a multicast shared tree.

Question 94

What are the 4 types of PIM Rendezvous Points that can exist in a multicast network domain?

Answer 94

You can configure as many RPs as you like, and you can configure them to cover different group ranges:

1) Static RP: manually configured for a multicast group range
2) BSR (Bootstrap Router): ensures that all RPs in the multicast domain have the same cache
3) Auto RP: Cisco proprietary protocol
4) Anycast RP: used for creating redundant and load-balanced RPs using MSDP or PIM

Question 95

Describe the process behind how multicast forwarding works.

Answer 95

Multicast forwarding uses the Reverse Path Forwarding (RPF) algorithm to determine how to forward traffic from source to receiver. When a receiver joins the multicast group, a path is built from the receiver to the source or the RP (SSM or ASM/Birdir respectively). The path from a source to receiver flows in the reverse direction from the path that was created when the receiver joined the group.

If the packet arrives on the interface leading to the source, the packet is forwarded out each interface in the outgoing interface (OIF) list for the group. Otherwise, the router drops the packet.

Question 96

What is the default version of HSRP supported by Cisco NX-OS

Answer 96

By default, Cisco NX-OS uses HSRP by default, but an interface can be configured to use HSRP version 2.

Question 97

What group ranges are supported by HSRP version 1 & version 2 respectively

Answer 97

HSRP version 1 supports group ranges 0 to 255

HSRP version 2 supports group ranges 0 to 4095

Question 98

What multicast IP address is used by HSRP version 1 to send hello packets?

Answer 98

HSRP version 1 uses multicast IP 224.0.0.2.

Question 99

What multicast IP address is used by HSRP version 1 to send hello packets?

Answer 99

HSRP version 1 uses multicast IP 224.0.0.2.

Question 100

What multicast IP address is used by HSRP version 2 to send hello packets?

Answer 100

HSRP version 1 uses multicast IP 224.0.0.102.

Question 101

What is the purpose of HSRP message digest 5 (MD5) algorithm authentication?

Answer 101

Protects against HSRP-spoofing software.

Question 102

What port and transport protocol are used by HSRP to send and receive hello packets?

Answer 102

Port 1985 over UDP.

Question 103

What MAC address range is used by HSRP version 1 for the virtual interface?

Answer 103

0000.0C07.ACxy, where xy is the HSRP group number in hexadecimal format.

Question 104

What MAC address range is used by HSRP version 2 for the virtual interface?

Answer 104

0000.0C9F.Fxyz, where is the HSRP group number in hexadecimal format.

Question 105

What is the purpose of the HSRP coup message?

Answer 105

Used by the standby router to take over the role as the active router.

Question 106

What is the purpose of the HSRP resign message?

Answer 106

Sent by the active router, signifies that the standby router will be taking over responsibilities as the active router. Also sent by the active router when it is shut down.

Question 107

What many VRRP groups are supported on a single router?

Answer 107

A single router can be joined to 255 VRRP groups?

Question 108

What is the multicast address used for VRRP advertisements

Answer 108

VRRP uses address 224.0.0.18 for advertisements.

Question 109

What IP protocol number was assigned by the IANA for VRRP messages?

Answer 109

112

Question 110

What is the priority of the VRRP master for the group?

Answer 110

255

Question 111

What is the default priority for a VRRP router?

Answer 111

100

Question 112

What modes of authentication are supported for VRRP?

Answer 112

No authentication, or plain-text authentication.

Question 113

What the options for VRRP tracking?

Answer 113

Object tracking, and native interface tracking.