Lab – Testing Network Connectivity with Ping
and Traceroute
Topology
Addressing Table
|
Device
|
Interface
|
IP Address
|
Subnet Mask
|
Default Gateway
|
|
LOCAL
|
G0/1
|
192.168.1.1
|
255.255.255.0
|
N/A
|
|
|
S0/0/0 (DCE)
|
10.1.1.1
|
255.255.255.252
|
N/A
|
|
ISP
|
S0/0/0
|
10.1.1.2
|
255.255.255.252
|
N/A
|
|
|
S0/0/1 (DCE)
|
10.2.2.2
|
255.255.255.252
|
N/A
|
|
REMOTE
|
G0/1
|
192.168.3.1
|
255.255.255.0
|
N/A
|
|
|
S0/0/1
|
10.2.2.1
|
255.255.255.252
|
N/A
|
|
S1
|
VLAN 1
|
192.168.1.11
|
255.255.255.0
|
192.168.1.1
|
|
S3
|
VLAN 1
|
192.168.3.11
|
255.255.255.0
|
192.168.3.1
|
|
PC-A
|
NIC
|
192.168.1.3
|
255.255.255.0
|
192.168.1.1
|
|
PC-C
|
NIC
|
192.168.3.3
|
255.255.255.0
|
192.168.3.1
|
Objectives
Part 1: Build and Configure the Network
Part 2: Use Ping Command for Basic Network
Testing
Part 3: Use Tracert and Traceroute
Commands for Basic
Network Testing
Part 4: Troubleshoot the Topology
Background / Scenario
Ping and traceroute are two tools that
are indispensable when testing TCP/IP network connectivity. Ping is a network
administration utility used to test the reachability of a device on an IP
network. This utility also measures the round-trip time for messages sent from
the originating host to a destination computer. The ping utility is available
on Windows, Unix-like operating systems (OS), and the Cisco Internetwork
Operating System (IOS).
The traceroute utility is a network
diagnostic tool for displaying the route and measuring the transit delays of
packets travelling an IP network. The tracert utility is available on Windows,
and a similar utility, traceroute, is available on Unix-like OS and Cisco IOS.
In this lab, the ping and traceroute
commands are examined and command options are explored to modify the command
behavior. Cisco devices and PCs are used in this lab for command exploration.
Cisco routers will use Enhanced Interior Gateway Routing Protocol (EIGRP) to route
packets between networks. The necessary Cisco device configurations are provided
in this lab.
Note: The routers used with CCNA hands-on labs
are Cisco 1941 Integrated Services Routers (ISRs) with Cisco IOS Release 15.2(4)M3
(universalk9 image). The switches used are Cisco Catalyst 2960s with Cisco IOS Release
15.0(2) (lanbasek9 image). Other routers, switches and Cisco IOS versions can
be used. Depending on the model and Cisco IOS version, the commands available
and output produced might vary from what is shown in the labs. Refer to the
Router Interface Summary Table at the end of this lab for the correct interface
identifiers.
Note: Make sure that the routers and switches have been erased and have
no startup configurations. If you are unsure, contact your instructor.
Required Resources
·
3 Routers (Cisco 1941 with
Cisco IOS Release 15.2(4)M3 universal image or comparable)
·
2 Switches (Cisco 2960 with
Cisco IOS Release 15.0(2) lanbasek9 image or comparable)
·
2 PCs (Windows 7 or 8 with
terminal emulation program, such as Tera Term)
·
Console cables to configure the
Cisco IOS devices via the console ports
·
Ethernet and serial cables as
shown in the topology
Part 1:
Build and Configure the Network
In Part 1, you will set up the network in
the topology and configure the PCs and Cisco devices. The initial
configurations for the routers and switches are provided for your reference. In
this topology, EIGRP is used to route packets between networks.
Step 1:
Cable the network as shown in
the topology.
Step 2:
Erase the configurations on the
routers and switches, and reload the devices.
Step 3:
Configure PC IP addresses and
default gateways according to the Addressing Table.
Step 4:
Configure the LOCAL, ISP, and
REMOTE routers using the initial configurations provided below.
At the switch or router global config
mode prompt, copy and paste the configuration for each device. Save the
configuration to startup-config.
Initial
configurations for the LOCAL router:
hostname LOCAL
no ip domain-lookup
interface s0/0/0
ip address
10.1.1.1 255.255.255.252
clock rate
56000
no
shutdown
interface g0/1
ip add
192.168.1.1 255.255.255.0
no
shutdown
router eigrp 1
network
10.1.1.0 0.0.0.3
network
192.168.1.0 0.0.0.255
no
auto-summary
Initial
configurations for ISP:
hostname ISP
no ip domain-lookup
interface s0/0/0
ip address
10.1.1.2 255.255.255.252
no
shutdown
interface s0/0/1
ip add
10.2.2.2 255.255.255.252
clock rate
56000
no
shutdown
router eigrp 1
network
10.1.1.0 0.0.0.3
network
10.2.2.0 0.0.0.3
no
auto-summary
end
Initial
configurations for REMOTE:
hostname REMOTE
no ip domain-lookup
interface s0/0/1
ip address
10.2.2.1 255.255.255.252
no
shutdown
interface g0/1
ip add
192.168.3.1 255.255.255.0
no
shutdown
router eigrp 1
network
10.2.2.0 0.0.0.3
network 192.168.3.0 0.0.0.255
no
auto-summary
end
Step 5:
Configure the S1 and S3 switches
with the initial configurations.
Initial
configurations for S1:
hostname S1
no ip domain-lookup
interface vlan 1
ip add
192.168.1.11 255.255.255.0
no
shutdown
exit
ip default-gateway 192.168.1.1
end
Initial
configurations for S3:
hostname S3
no ip domain-lookup
interface vlan 1
ip add
192.168.3.11 255.255.255.0
no
shutdown
exit
ip default-gateway 192.168.3.1
end
Step 6:
Configure an IP host table on the
LOCAL router.
The IP host table allows you to use a
hostname to connect to a remote device rather than an IP address. The host
table provides name resolution for the device with the following
configurations. Copy and paste the following configurations for the LOCAL router.
The configurations will allow you to use the hostnames for ping and traceroute
commands on the LOCAL router.
ip host REMOTE 10.2.2.1 192.168.3.1
ip host ISP 10.1.1.2 10.2.2.2
ip host LOCAL 192.168.1.1 10.1.1.1
ip host PC-C 192.168.3.3
ip host PC-A 192.168.1.3
ip host S1 192.168.1.11
ip host S3 192.168.3.11
end
Part 2:
Use Ping Command for Basic Network
Testing
In Part 2 of this lab, use the ping command to verify end-to-end
connectivity. Ping operates by sending Internet Control Message Protocol (ICMP)
echo request packets to the target host and then waiting for an ICMP response.
It can record the round trip time and any packet loss.
You will examine the results with the ping command and the additional ping options
that are available on Windows-based PCs and Cisco devices.
Step 1:
Test network connectivity from the
LOCAL network using PC-A.
All the pings from PC-A to other devices
in the topology should be successful. If they are not, check the topology and
the cabling, as well as the configuration of the Cisco devices and the PCs.
a.
Ping from PC-A to its default
gateway (LOCAL’s GigabitEthernet 0/1 interface).
C:\Users\User1> ping 192.168.1.1
Pinging 192.168.1.1 with 32 bytes of
data:
Reply from 192.168.1.1: bytes=32
time<1ms TTL=255
Reply from 192.168.1.1: bytes=32
time<1ms TTL=255
Reply from 192.168.1.1: bytes=32
time<1ms TTL=255
Reply from 192.168.1.1: bytes=32
time<1ms TTL=255
Ping statistics for 192.168.1.1:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
Approximate round trip times in milli-seconds:
Minimum = 0ms, Maximum = 0ms,
Average = 0ms
In this example, four (4) ICMP requests, 32
bytes each, were sent and the responses were received in less than one
millisecond with no packet loss. The transmission and reply time increases as
the ICMP requests and responses are processed by more devices during the
journey to and from the final destination.
b.
From PC-A, ping the addresses
listed in the following table and record the average round trip time and Time
to Live (TTL).
|
Destination
|
Average Round Trip Time (ms)
|
TTL
|
|
192.168.1.1 (LOCAL)
|
0
|
255
|
|
192.168.1.11 (S1)
|
0
|
255
|
|
10.1.1.1 (LOCAL)
|
0
|
255
|
|
10.1.1.2 (ISP)
|
2
|
254
|
|
10.2.2.2 (ISP)
|
1
|
254
|
|
10.2.2.1 (REMOTE)
|
3
|
253
|
|
192.168.3.1 (REMOTE)
|
3
|
253
|
|
192.168.3.11 (S3)
|
2
|
252
|
|
192.168.3.3 (PC-C)
|
2
|
125
|
Notice the average round trip time to
192.168.3.3 (PC-C). The time increased because the ICMP requests were processed
by three routers before PC-A received the reply from PC-C.
C:\Users\User1> ping 192.168.3.3
Pinging 192.168.3.3 with 32 bytes of
data:
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Reply from 192.168.3.3: bytes=32 time=40ms
TTL=125
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Ping statistics for 192.168.3.3:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
Approximate round trip times in
milli-seconds:
Minimum = 40ms,
Maximum = 41ms, Average = 40ms
Step 2:
Use extended ping commands on a
PC.
The default ping command sends four requests at 32 bytes each. It waits 4,000
milliseconds (4 seconds) for each response to be returned before displaying the
“Request timed out” message. The ping
command can be fine tuned for troubleshooting a network.
a.
At the command prompt, type ping and press Enter.
C:\Users\User1> ping
Usage: ping [-t] [-a] [-n count] [-l
size] [-f] [-i TTL] [-v TOS]
[-r count] [-s count] [[-j
host-list] | [-k host-list]]
[-w timeout] [-R] [-S srcaddr] [-4]
[-6] target_name
Options:
-t Ping the specified
host until stopped.
To see statistics and
continue - type Control-Break;
To stop - type Control-C.
-a Resolve addresses
to hostnames.
-n count Number of echo
requests to send.
-l size Send buffer size.
-f Set Don't Fragment
flag in packet (IPv4-only).
-i TTL Time To Live.
-v TOS Type Of Service
(IPv4-only. This setting has been deprecated
and has no effect on the
type of service field in the IP Header).
-r count Record route for
count hops (IPv4-only).
-s count Timestamp for count
hops (IPv4-only).
-j host-list Loose source route
along host-list (IPv4-only).
-k host-list Strict source route
along host-list (IPv4-only).
-w timeout Timeout in milliseconds to wait for each
reply.
-R Use routing header
to test reverse route also (IPv6-only).
-S srcaddr Source address to
use.
-4 Force using IPv4.
-6 Force using IPv6.
b.
Using the –t option, ping PC-C to verify that PC-C is reachable.
C:\Users\User1> ping –t 192.168.3.3
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Reply from 192.168.3.3: bytes=32 time=40ms
TTL=125
To illustrate the results when a host is
unreachable, disconnect the cable between the REMOTE router and the S3 switch, or
shut down the GigabitEthernet 0/1 interface on the REMOTE router.
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Reply from 192.168.1.3: Destination host
unreachable.
Reply from 192.168.1.3: Destination host
unreachable.
While the network is functioning
correctly, the ping command can
determine whether the destination responded and how long it took to receive a
reply from the destination. If a network connectivity problem exists, the ping command displays an error message.
c.
Reconnect the Ethernet cable or
enable the GigabitEthernet interface on the REMOTE router (using the no shutdown command) before moving onto
the next step. After about 30 seconds, the ping should be successful again.
Request timed out.
Request timed out.
Request timed out.
Request timed out.
Reply from 192.168.3.3: bytes=32 time=41ms
TTL=125
Reply from 192.168.3.3: bytes=32 time=40ms
TTL=125
d.
Press Ctrl+C to stop the ping
command.
Step 3:
Test network connectivity from the
LOCAL network using Cisco devices.
The ping command is also available on Cisco
devices. In this step, the ping
command is examined using the LOCAL router and the S1 switch.
a.
Ping PC-C on the REMOTE network
using the IP address of 192.168.3.3 from the LOCAL router.
LOCAL# ping
192.168.3.3
Type escape sequence to abort.
Sending 5, 100-byte ICMP Echos to
192.168.3.3, timeout is 2 seconds:
!!!!!
Success rate is 100 percent (5/5), round-trip
min/avg/max = 60/64/68 ms
The exclamation point (!) indicates that
the ping was successful from the LOCAL router to PC-C. The round trip takes an
average of 64 ms with no packet loss, as indicated by a 100% success rate.
b.
Because a local host table was
configured on the LOCAL router, you can ping PC-C on the REMOTE network using
the hostname configured from the LOCAL router.
LOCAL# ping
PC-C
Type escape sequence to abort.
Sending 5, 100-byte ICMP Echos to
192.168.3.3, timeout is 2 seconds:
!!!!!
Success rate is 100 percent (5/5),
round-trip min/avg/max = 60/63/64 ms
c.
There are more options
available for the ping command. At
the CLI, type ping and press Enter.
Input 192.168.3.3 or PC-C for the Target IP address. Press Enter
to accept the default value for other options.
LOCAL# ping
Protocol [ip]:
Target IP address: PC-C
Repeat count [5]:
Datagram size [100]:
Timeout in seconds [2]:
Extended commands [n]:
Sweep range of sizes [n]:
Type escape sequence to abort.
Sending 5, 100-byte ICMP Echos to
192.168.3.3, timeout is 2 seconds:
!!!!!
Success rate is 100 percent (5/5),
round-trip min/avg/max = 60/63/64 ms
d.
You can use an extended ping to
observe when there is a network issue. Start the ping command to 192.168.3.3 with a repeat a count of 500. Then, disconnect
the cable between the REMOTE router and the S3 switch or shut down the GigabitEthernet
0/1 interface on the REMOTE router.
Reconnect the Ethernet cable or enable
the GigabitEthernet interface on the REMOTE router after the exclamation points
(!) have replaced by the letter U and periods (.). After about 30 seconds, the
ping should be successful again. Press Ctrl+Shift+6 to stop the ping
command if desired.
LOCAL# ping
Protocol [ip]:
Target IP address: 192.168.3.3
Repeat count [5]: 500
Datagram size [100]:
Timeout in seconds [2]:
Extended commands [n]:
Sweep range of sizes [n]:
Type escape sequence to abort.
Sending 500, 100-byte ICMP Echos to
192.168.3.3, timeout is 2 seconds:
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!U................
....!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!!!!!!!!
Success rate is 95 percent (479/500),
round-trip min/avg/max = 60/63/72 ms
The letter U in the results indicates
that a destination is unreachable. An error protocol data unit (PDU) was
received by the LOCAL router. Each period (.) in the output indicates that the ping
timed out while waiting for a reply from PC-C. In this example, 5% of the
packets were lost during the simulated network outage.
Note: You can also use the following command for the same results:
LOCAL# ping
192.168.3.3 repeat 500
or
LOCAL# ping
PC-C repeat 500
e.
You can also test network connectivity
with a switch. In this example, the S1 switch pings the S3 switch on the REMOTE
network.
S1# ping
192.168.3.11
Type escape sequence to abort.
Sending 5, 100-byte ICMP Echos to
192.168.3.11, timeout is 2 seconds:
!!!!!
Success rate is 100 percent (5/5),
round-trip min/avg/max = 67/67/68 ms
The ping
command is extremely useful when troubleshooting network connectivity. However,
ping cannot indicate the location of problem when a ping is not successful. The
tracert (or traceroute) command can display network latency and path
information.
Part 3:
Use Tracert and Traceroute
Commands for Basic Network Testing
The commands
for tracing routes can be found on PCs and network devices. For a Windows-based
PC, the tracert command uses ICMP messages
to trace the path to the final destination. The traceroute command utilizes the User Datagram Protocol (UDP)
datagrams for tracing routes to the final destination for Cisco devices and
other Unix-like PCs.
In Part 3, you
will examine the traceroute commands and determine the path that a packet
travels to its final destination. You will use the tracert command from the Windows PCs and the traceroute command from the Cisco devices. You will also examine the
options that are available for fine tuning the traceroute results.
Step 1:
Use the tracert command from
PC-A to PC-C.
a.
At the command prompt, type tracert 192.168.3.3.
C:\Users\User1> tracert 192.168.3.3
Tracing route to PC-C [192.168.3.3]
Over a maximum of 30 hops:
1 <1 ms <1 ms
<1 ms 192.168.1.1
2 24 ms 24 ms
24 ms 10.1.1.2
3 48 ms 48 ms
48 ms 10.2.2.1
4 59 ms 59 ms
59 ms PC-C [192.168.3.3]
Trace complete.
The tracert results indicates the path
from PC-A to PC-C is from PC-A to LOCAL to ISP to REMOTE to PC-C. The path to
PC-C traveled through three router hops to the final destination of PC-C.
Step 2:
Explore additional options for the
tracert command.
a.
At the command prompt, type tracert and press Enter.
C:\Users\User1> tracert
Usage: tracert [-d] [-h maximum_hops]
[-j host-list] [-w timeout]
[-R] [-S srcaddr] [-4] [-6]
target_name
Options:
-d Do not resolve
addresses to hostnames.
-h maximum_hops Maximum number
of hops to search for target.
-j host-list Loose source
route along host-list (IPv4-only).
-w timeout Wait timeout
milliseconds for each reply.
-R Trace
round-trip path (IPv6-only).
-S srcaddr Source address
to use (IPv6-only).
-4 Force using
IPv4.
-6 Force using
IPv6.
b.
Use the -d option. Notice that the IP address of 192.168.3.3 is not
resolved as PC-C.
C:\Users\User1> tracert –d 192.168.3.3
Tracing route to 192.168.3.3 over a maximum of 30 hops:
1 <1 ms <1 ms
<1 ms 192.168.1.1
2 24 ms 24 ms
24 ms 10.1.1.2
3 48 ms 48 ms
48 ms 10.2.2.1
4 59 ms 59 ms
59 ms 192.168.3.3
Trace complete.
Step 3:
Use the traceroute command from
the LOCAL router to PC-C.
a.
At the command prompt, type traceroute 192.168.3.3 or traceroute PC-C on the LOCAL router.
The hostnames are resolved because a local IP host table was configured on the
LOCAL router.
LOCAL# traceroute
192.168.3.3
Type escape sequence to abort.
Tracing the route to PC-C (192.168.3.3)
VRF info: (vrf in name/id, vrf out
name/id)
1 ISP (10.1.1.2) 16 msec 16 msec 16 msec
2 REMOTE (10.2.2.1) 28 msec 32 msec 28 msec
3 PC-C (192.168.3.3) 32 msec 28 msec 32 msec
LOCAL# traceroute
PC-C
Type escape sequence to abort.
Tracing the route to PC-C (192.168.3.3)
VRF info: (vrf in name/id, vrf out
name/id)
1 ISP (10.1.1.2) 16 msec 16 msec 16 msec
2 REMOTE (10.2.2.1) 28 msec 32 msec 28 msec
3 PC-C (192.168.3.3) 32 msec 32 msec 28 msec
Step 4:
Use the traceroute command from
the S1 switch to PC-C.
a.
On the S1 switch, type traceroute 192.168.3.3. The hostnames
are not displayed in the traceroute results because a local IP host table was not
configured on this switch.
S1# traceroute
192.168.3.3
Type escape sequence to abort.
Tracing the route to 192.168.3.3
VRF info: (vrf in name/id, vrf out
name/id)
1 192.168.1.1 1007 msec 0 msec 0 msec
2 10.1.1.2 17 msec 17 msec 16 msec
3 10.2.2.1 34 msec 33 msec 26 msec
4 192.168.3.3 33 msec 34 msec 33 msec
The traceroute
command has additional options. You can use the ? or just press Enter after typing traceroute at the prompt to explore these options.
The following link provides more
information regarding the ping and traceroute commands for a Cisco device:
Part 4:
Troubleshoot the Topology
Step 1:
Erase the configurations on the
REMOTE router.
Step 2:
Reload the REMOTE router.
Step 3:
Copy and paste the following
configuration into the REMOTE router.
hostname REMOTE
no ip domain-lookup
interface s0/0/1
ip address
10.2.2.1 255.255.255.252
no
shutdown
interface g0/1
ip add
192.168.8.1 255.255.255.0
no
shutdown
router eigrp 1
network
10.2.2.0 0.0.0.3
network
192.168.3.0 0.0.0.255
no
auto-summary
end
Step 4:
From the LOCAL network, use ping
and tracert or traceroute commands to troubleshoot and correct the problem on
the REMOTE network.
a.
Use the ping and tracert
commands from PC-A.
You can use the tracert command to determine end-to-end network connectivity. This
tracert result indicates that PC-A can reach its default gateway of 192.168.1.1,
but PC-A does not have network connectivity with PC-C.
C:\Users\User1> tracert 192.168.3.3
Tracing route to 192.168.3.3 over a
maximum of 30 hops
1 <1 ms <1 ms
<1 ms 192.168.1.1
2 192.168.1.1 reports: Destination host unreachable.
Trace complete.
One way to locate the network issue is to
ping each hop in the network to PC-C. First determine if PC-A can reach the ISP
router Serial 0/0/1 interface with an IP address of 10.2.2.2.
C:\Users\Utraser1> ping 10.2.2.2
Pinging 10.2.2.2 with 32 bytes of data:
Reply from 10.2.2.2: bytes=32 time=41ms
TTL=254
Reply from 10.2.2.2: bytes=32 time=41ms
TTL=254
Reply from 10.2.2.2: bytes=32 time=41ms
TTL=254
Reply from 10.2.2.2: bytes=32 time=41ms
TTL=254
Ping statistics for 10.2.2.2:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
Approximate round trip times in
milli-seconds:
Minimum = 20ms, Maximum = 21ms, Average = 20ms
The ping was successful to the ISP
router. The next hop in the network is the REMOTE router. Ping the REMOTE
router Serial 0/0/1 interface with an IP address of 10.2.2.1.
C:\Users\User1> ping 10.2.2.1
Pinging 10.2.2.1 with 32 bytes of data:
Reply from 10.2.2.1: bytes=32 time=41ms
TTL=253
Reply from 10.2.2.1: bytes=32 time=41ms
TTL=253
Reply from 10.2.2.1: bytes=32 time=41ms
TTL=253
Reply from 10.2.2.1: bytes=32 time=41ms
TTL=253
Ping statistics for 10.2.2.1:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
Approximate round trip times in
milli-seconds:
Minimum = 40ms, Maximum = 41ms, Average = 40ms
PC-A can reach the REMOTE router. Based
on the successful ping results from PC-A to the REMOTE router, the network
connectivity issue is with 192.168.3.0/24 network. Ping the default gateway to
PC-C, which is the GigabitEthernet 0/1 interface of the REMOTE router.
C:\Users\User1> ping 192.168.3.1
Pinging 192.168.3.1 with 32 bytes of
data:
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Ping statistics for 192.168.3.1:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
PC-A cannot reach the GigabitEthernet 0/1
interface of the REMOTE router, as displayed by the results from the ping command.
The S3 switch can also be pinged from
PC-A to verify the location of the networking connectivity issue by typing ping 192.168.3.11 at the command
prompt. Because PC-A cannot reach GigabitEthernet 0/1 of the REMOTE router,
PC-A probably cannot ping the S3 switch successfully, as indicated by the
results below.
C:\Users\User1> ping 192.168.3.11
Pinging 192.168.3.11 with 32 bytes of
data:
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Reply from 192.168.1.1: Destination host
unreachable.
Ping statistics for 192.168.3.11:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
The tracert and ping results conclude
that PC-A can reach the LOCAL, ISP, and REMOTE routers, but not PC-C or the S3
switch, nor the default gateway for PC-C.
b.
Use the show commands to examine the running configurations for the the
REMOTE router.
REMOTE# show
ip interface brief
Interface IP-Address OK? Method Status Protocol
Embedded-Service-Engine0/0
unassigned YES unset administratively down down
GigabitEthernet0/0 unassigned YES unset
administratively down down
GigabitEthernet0/1
192.168.8.1 YES manual up up
Serial0/0/0 unassigned YES unset
administratively down down
Serial0/0/1 10.2.2.1 YES manual up up
REMOTE# show
run
<output omitted>
interface GigabitEthernet0/0
no ip address
shutdown
duplex auto
speed auto
!
interface GigabitEthernet0/1
ip address 192.168.8.1
255.255.255.0
duplex auto
speed auto
!
interface Serial0/0/0
no ip address
shutdown
clock rate 2000000
!
interface Serial0/0/1
ip address 10.2.2.1 255.255.255.252
<output omitted>
The outputs of the show run and show ip
interface brief commands indicate that the GigabitEthernet 0/1 interface is
up/up, but was configured with an incorrect IP address.
c.
Correct the IP address for GigabitEthernet
0/1.
REMOTE# configure
terminal
Enter configuration commands, one per
line. End with CNTL/Z.
REMOTE(config)# interface GigabitEthernet 0/1
REMOTE(config-if)# ip address 192.168.3.1 255.255.255.0
d.
Verify that PC-A can ping and
tracert to PC-C.
C:\Users\User1> ping 192.168.3.3
Pinging 192.168.3.3 with 32 bytes of
data:
Reply from 192.168.3.3: bytes=32 time=44ms
TTL=125
Reply from 192.168.3.3: bytes=32
time=41ms TTL=125
Reply from 192.168.3.3: bytes=32
time=40ms TTL=125
Reply from 192.168.3.3: bytes=32
time=41ms TTL=125
Ping statistics for 192.168.3.3:
Packets: Sent = 4, Received = 4, Lost = 0 (0% loss),
Approximate round trip times in
milli-seconds:
Minimum = 40ms, Maximum = 44ms, Average = 41ms
C:\Users\User1> tracert 192.168.3.3
Tracing route to PC-C [192.168.3.3]
Over a maximum of 30 hops:
1 <1 ms <1 ms
<1 ms 192.168.1.1
2 24 ms 24 ms
24 ms 10.1.1.2
3 48 ms 48 ms
48 ms 10.2.2.1
4 59 ms 59 ms
59 ms PC-C [192.168.3.3]
Trace complete.
Note: This can also be accomplished using ping and traceroute
commands from the CLI on the the LOCAL router and the S1 switch after verifying
that there are no network connectivity issues on the 192.168.1.0/24 network.
Reflection
1.
What could prevent ping or
traceroute responses from reaching the originating device beside network
connectivity issues?
______________Firewall on the PC’s, access lists command,
routing issues, interface is down, network delay, network firewalls and other
issues._________________________________________________________________________
_______________________________________________________________________________________
2.
If you ping a non-existent
address on the remote network, such as 192.168.3.4, what is the message
displayed by the ping command? What
does this mean? If you ping a valid host address and receive this response, what
should you check?
__Request time out _____________________________________________________________________________________
_______________________________________________________________________________________
3.
If you ping an address that
does not exist in any network in your topology, such as 192.168.5.3, from a
Windows-based PC, what is the message displayed by the ping command? What does this message indicate?
___________Destinstion host unreachable ____________________________________________________________________________
_______________________________________________________________________________________
Router Interface Summary Table
|
Router Interface Summary
|
||||
|
Router Model
|
Ethernet Interface #1
|
Ethernet Interface #2
|
Serial Interface #1
|
Serial Interface #2
|
|
1800
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
|
1900
|
Gigabit Ethernet 0/0 (G0/0)
|
Gigabit Ethernet 0/1 (G0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
|
2801
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/1/0 (S0/1/0)
|
Serial 0/1/1 (S0/1/1)
|
|
2811
|
Fast Ethernet 0/0 (F0/0)
|
Fast Ethernet 0/1 (F0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
|
2900
|
Gigabit Ethernet 0/0 (G0/0)
|
Gigabit Ethernet 0/1 (G0/1)
|
Serial 0/0/0 (S0/0/0)
|
Serial 0/0/1 (S0/0/1)
|
|
Note: To find out how the router is configured, look at the interfaces
to identify the type of router and how many interfaces the router has. There
is no way to effectively list all the combinations of configurations for each
router class. This table includes identifiers for the possible combinations
of Ethernet and Serial interfaces in the device. The table does not include
any other type of interface, even though a specific router may contain one.
An example of this might be an ISDN BRI interface. The string in parenthesis
is the legal abbreviation that can be used in Cisco IOS commands to represent
the interface.
|
||||
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