Table of Contents

Chapter 1 NTP Configuration. 1-1

1.1 NTP Overview. 1-1

1.1.1 Applications of NTP. 1-1

1.1.2 How NTP Works. 1-2

1.1.3 NTP Message Format 1-4

1.1.4 Operation Modes of NTP. 1-5

1.2 NTP Configuration Task list 1-8

1.3 Configuring the Operation Modes of NTP. 1-8

1.3.1 Configuring NTP Server/Client Mode. 1-9

1.3.2 Configuring the NTP Symmetric Mode. 1-9

1.3.3 Configuring NTP Broadcast Mode. 1-10

1.3.4 Configuring NTP Multicast Mode. 1-11

1.4 Configuring Optional Parameters of NTP. 1-12

1.4.1 Configuring the Interface to Send NTP Messages. 1-12

1.4.2 Disabling an Interface from Receiving NTP Messages. 1-13

1.4.3 Configuring the Maximum Number of Dynamic Sessions Allowed. 1-13

1.5 Configuring Access-Control Rights. 1-13

1.5.1 Configuration Prerequisites. 1-14

1.5.2 Configuration Procedure. 1-14

1.6 Configuring NTP Authentication. 1-15

1.6.1 Configuration Prerequisites. 1-15

1.6.2 Configuration Procedure. 1-15

1.7 Displaying and Maintaining NTP. 1-17

1.8 NTP Configuration Examples. 1-18

1.8.1 Configuring NTP Server/Client Mode. 1-18

1.8.2 Configuring the NTP Symmetric Mode. 1-19

1.8.3 Configuring NTP Broadcast Mode. 1-21

1.8.4 Configuring NTP Multicast Mode. 1-23

1.8.5 Configuring NTP Server/Client Mode with Authentication. 1-26

1.8.6 Configuring NTP Broadcast Mode with Authentication. 1-28

 

Chapter 1  NTP Configuration

 

 

When configuring NTP, go to these sections for information you are interested in:

l           NTP Overview

l           NTP Configuration Task list

l           Configuring the Operation Modes of NTP

l           Configuring Optional Parameters of NTP

l           Configuring Access-Control Rights

l           Configuring NTP Authentication

l           Displaying and Maintaining NTP

l           NTP Configuration Examples

1.1  NTP Overview

Defined in RFC 1305, the Network Time Protocol (NTP) synchronizes timekeeping among distributed time servers and clients. NTP runs over the User Datagram Protocol (UDP), using UDP port 123.

The purpose of using NTP is to keep consistent timekeeping among all clock-dependent devices within the network so that the devices can provide diverse applications based on the consistent time.

For a local system running NTP, its time can be synchronized by other reference sources and can be used as a reference source to synchronize other clocks.

1.1.1  Applications of NTP

An administrator can by no means keep synchronized time among all the devices within a network by changing the system clock on each station, because this is a huge amount of workload and cannot guarantee the clock precision. NTP, however, allows quick clock synchronization within the entire network while it ensures a high clock precision.

NTP is used when all devices within the network must be consistent in timekeeping, for example:

l           In analysis of the log information and debugging information collected from different devices in network management, time must be used as reference basis.

l           All devices must use the same reference clock in a charging system.

l           To implement certain functions, such as scheduled restart of all devices within the network, all devices must be consistent in timekeeping.

l           When multiple systems process a complex event in cooperation, these systems must use that same reference clock to ensure the correct execution sequence.

l           For increment backup between a backup server and clients, timekeeping must be synchronized between the backup server and all the clients.

Advantages of NTP:

l           NTP uses a stratum to describe the clock precision, and is able to synchronize time among all devices within the network.

l           NTP supports access control and MD5 authentication.

l           NTP can unicast, multicast or broadcast protocol messages.

1.1.2  How NTP Works

Figure 1-1 shows the basic work flow of NTP. Switch A and Switch B are interconnected over a network. They have their own independent system clocks, which need to be automatically synchronized through NTP. For an easy understanding, we assume that:

l           Prior to system clock synchronization between Switch A and Switch B, the clock of Switch A is set to 10:00:00 am while that of Switch B is set to 11:00:00 am.

l           Switch B is used as the NTP time server, namely Switch A synchronizes its clock to that of Switch B.

l           It takes 1 second for an NTP message to travel from one switch to the other.

Figure 1-1 Basic work flow of NTP

The process of system clock synchronization is as follows:

l           Switch A sends Switch B an NTP message, which is timestamped when it leaves Switch A. The time stamp is 10:00:00 am (T1).

l           When this NTP message arrives at Switch B, it is timestamped by Switch B. The timestamp is 11:00:01 am (T2).

l           When the NTP message leaves Switch B, Switch B timestamps it. The timestamp is 11:00:02 am (T3).

l           When Switch A receives the NTP message, the local time of Switch A is 10:00:03 am (T4).

Up to now, Switch A has sufficient information to calculate the following two important parameters:

l           The roundtrip delay of NTP message: Delay = (T₄–T₁) – (T₃-T₂) = 2 seconds.

l           Time difference between Switch A and Switch B: Offset = ((T₂-T₁) + (T₃-T₄))/2 = 1 hour.

Based on these parameters, Switch A can synchronize its own clock to the clock of Switch B.

This is only a rough description of the work mechanism of NTP. For details, refer to RFC 1305.

1.1.3  NTP Message Format

NTP uses two types of messages, clock synchronization message and NTP control message. An NTP control message is used in environments where network management is needed. As it is not a must for clock synchronization, it will not be discussed in this document.

 

 

A clock synchronization message is encapsulated in a UDP message, in the format shown in Figure 1-2.

Figure 1-2 Clock synchronization message format

Main fields are described as follows:

l           LI: 2-bit leap indicator. When set to 11, it warns of an alarm condition (clock unsynchronized); when set to any other value, it is not to be processed by NTP.

l           VN: 3-bit version number, indicating the version of NTP. The latest version is version 3.

l           Mode: a 3-bit code indicating the work mode of NTP. This field can be set to these values: 0 – reserved; 1 – symmetric active; 2 – symmetric passive; 3 – client; 4 – server; 5 – broadcast or multicast; 6 – NTP control message; 7 – reserved for private use.

l           Stratum: an 8-bit integer indicating the stratum level of the local clock, with the value ranging from 1 to 16. The clock precision decreases from stratum 1 through stratum 16. A stratum 1 clock has the highest precision, and a stratum 16 clock is not synchronized and cannot be used as a reference clock.

l           Poll: 8-bit signed integer indicating the poll interval, namely the maximum interval between successive messages.

l           Precision: an 8-bit signed integer indicating the precision of the local clock.

l           Root Delay: roundtrip delay to the primary reference source.

l           Root Dispersion: the maximum error of the local clock relative to the primary reference source.

l           Reference Identifier: Identifier of the particular reference source.

l           Reference Timestamp: the local time at which the local clock was last set or corrected.

l           Originate Timestamp: the local time at which the request departed the client for the service host.

l           Receive Timestamp: the local time at which the request arrived at the service host.

l           Transmit Timestamp: the local time at which the reply departed the service host for the client.

l           Authenticator: authentication information.

1.1.4  Operation Modes of NTP

Switches running NTP can implement clock synchronization in one of the following modes:

I. Server/client mode

Figure 1-3 Server/client mode

When working in the server/client mode, a client sends a clock synchronization message to servers, with the Mode field in the message set to 3 (client mode). Upon receiving the message, the servers automatically work in the server mode and send a reply, with the Mode field in the messages set to 4 (server mode). Upon receiving the replies from the servers, the client performs clock filtering and selection, and synchronizes its local clock to that of the optimal reference source.

In this mode, a client can be synchronized to a server, but not vice versa.

II. Symmetric peers mode

Figure 1-4 Symmetric peers mode

A switch working in the symmetric active mode periodically sends clock synchronization messages, with the Mode field in the message set to 1 (symmetric active); the switch that receives this message automatically enters the symmetric passive mode and sends a reply, with the Mode field in the message set to 2 (symmetric passive). By exchanging messages, the symmetric peers mode is established between the two switches. Then, the two switches can synchronize, or be synchronized by, each other. If the clocks of both switches have been already synchronized, the switch whose local clock has a lower stratum level will synchronize the clock of the other switch.

III. Broadcast mode

Figure 1-5 Broadcast mode

In the broadcast mode, a server periodically sends clock synchronization messages to the broadcast address 255.255.255.255, with the Mode field in the messages set to 5 (broadcast mode). Clients listen to the broadcast messages from servers. After a client receives the first broadcast message, the client and the server start to exchange messages, with the Mode field set to 3 (client mode) and 4 (server mode) to calculate the network delay between client and the server. Then, the client enters the broadcast client mode and continues listening to broadcast messages, and synchronizes its local clock based on the received broadcast messages.

IV. Multicast mode

Figure 1-6 Multicast mode

In the multicast mode, a server periodically sends clock synchronization messages to the user-configured multicast address, or, if no multicast address is configured, to the default NTP multicast address 224.0.1.1, with the Mode field in the messages set to 5 (multicast mode). Clients listen to the multicast messages from servers. After a client receives the first multicast message, the client and the server start to exchange messages, with the Mode field set to 3 (client mode) and 4 (server mode) to calculate the network delay between client and the server. Then, the client enters the multicast client mode and continues listening to multicast messages, and synchronizes its local clock based on the received multicast messages.

 

 

1.2  NTP Configuration Task list

Complete the following tasks to configure NTP:

Task	Remarks
Configuring the Operation Modes of NTP	Required
Configuring Optional Parameters of NTP	Optional
Configuring Access-Control Rights	Optional
Configuring NTP Authentication	Optional

 

1.3  Configuring the Operation Modes of NTP

Switches can implement clock synchronization in one of the following modes:

l           Server/client mode

l           Symmetric mode

l           Broadcast mode

l           Multicast mode

For the server/client mode or symmetric mode, you need to configure only clients or symmetric-active peers; for the broadcast or multicast mode, you need to configure both servers and clients.

 

 

1.3.1  Configuring NTP Server/Client Mode

For switches working in the server/client mode, you only need to make configurations on the clients, and not on the servers.

Follow these steps to configure an NTP client:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Specify an NTP server for the switch	ntp-service unicast-server { ip-address | server-name } [ authentication-keyid keyid | priority | source-interface interface-type interface-number | version number ] *	Required No NTP server is specified by default.

 

 

1.3.2  Configuring the NTP Symmetric Mode

For switches working in the symmetric mode, you need to specify a symmetric-passive on a symmetric-active peer.

Following these steps to configure a symmetric-active switch:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Specify a symmetric-passive peer for the switch	ntp-service unicast-peer { ip-address | peer-name } [ authentication-keyid keyid | priority | source-interface interface-type interface-number | version number ] *	Required No symmetric-passive peer is specified by default.

 

 

1.3.3  Configuring NTP Broadcast Mode

The broadcast server periodically sends NTP broadcast messages to the broadcast address 255.255.255.255. After receiving the messages, the switch working in NTP broadcast mode sends a reply and synchronizes its local clock.

For switches working in the broadcast mode, you need to configure both the server and clients. Because an interface need to be specified on the broadcast server for sending NTP broadcast messages and an interface also needs to be specified on each broadcast client for receiving broadcast messages, the NTP broadcast mode can be configured only in the specific interface view.

I. Configuring a broadcast client

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter interface view	interface interface-type interface-number	Required Enter the interface used to receive NTP broadcast messages
Configure the switch to work in the NTP broadcast client mode	ntp-service broadcast-client	Required

 

II. Configuring the broadcast server

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter interface view	interface interface-type interface-number	Enter the interface used to send NTP broadcast messages
Configure the switch to work in the NTP broadcast server mode	ntp-service broadcast-server [ authentication-keyid keyid | version number ]*	Required

 

 

1.3.4  Configuring NTP Multicast Mode

The multicast server periodically sends NTP multicast messages to multicast clients, which send replies after receiving the messages and synchronize their local clocks.

For switches working in the multicast mode, you need to configure both the server and clients. The NTP multicast mode must be configured in the specific interface view.

I. Configuring a multicast client

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter interface view	interface interface-type interface-number	Enter the interface used to receive NTP multicast messages
Configure the switch to work in the NTP multicast client mode	ntp-service multicast-client [ ip-address ]	Required

 

II. Configuring the multicast server

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter interface view	interface interface-type interface-number	Enter the interface used to send NTP multicast message
Configure the switch to work in the NTP multicast server mode	ntp-service multicast-server [ ip-address ] [ authentication-keyid keyid | ttl ttl-number | version number ] *	Required

 

 

1.4  Configuring Optional Parameters of NTP

1.4.1  Configuring the Interface to Send NTP Messages

After you specify the interface used to send NTP messages, the source IP address of the NTP message will be configured as the primary IP address of the specified interface.

Following these steps to configure the interface used to send NTP messages:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Configure the interface used to send NTP messages	ntp-service source-interface interface-type interface-number	Required

 

 

1.4.2  Disabling an Interface from Receiving NTP Messages

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter interface view	interface interface-type interface-number	—
Disable the interface from receiving NTP messages	ntp-service in-interface disable	Required An interface is enabled to receive NTP messages by default

 

1.4.3  Configuring the Maximum Number of Dynamic Sessions Allowed

To do…	Use the command…	Remarks
Enter system view	system-view	—
Configure the maximum number of dynamic sessions allowed to be established locally	ntp-service max-dynamic-sessions number	Required 100 by default

 

1.5  Configuring Access-Control Rights

With the following command, you can configure the NTP service access-control right to the local switch. There are four access-control rights, as follows:

l           query: control query permitted. This level of right permits the peer switch to perform control query to the NTP service on the local switch but does not permit the peer switch to synchronize its clock to the local switch. The so-called “control query” refers to query of some states of the NTP service, including alarm information, authentication status, clock source information, and so on.

l           synchronization: server access only. This level of right permits the peer switch to synchronize its clock to the local switch but does not permit the peer switch to perform control query.

l           server: server access and query permitted. This level of right permits the peer switch to perform synchronization and control query to the local switch but does not permit the local switch to synchronize its clock to the peer switch.

l           peer: full access. This level of right permits the peer switch to perform synchronization and control query to the local switch and also permits the local switch to synchronize its clock to the peer switch.

From the highest NTP service access-control right to the lowest one are peer, server, synchronization, and query. When a switch receives an NTP request, it will perform an access-control right match and will use the first matched right.

1.5.1  Configuration Prerequisites

Prior to configuring the NTP service access-control right to the local switch, you need to create and configure an ACL associated with the access-control right. For the configuration of ACL, refer to the ACL part of the manual.

1.5.2  Configuration Procedure

Follow these steps to configure the NTP service access-control right to the local switch:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Configure the NTP service access-control right to the local switch	ntp-service access { peer | query | server | synchronization } acl-number	Required peer by default

 

 

1.6  Configuring NTP Authentication

The NTP authentication feature should be enabled for a system running NTP in a network where there is a high security demand. This feature enhances the network security by means of client-server key authentication, which prohibits a client from synchronizing with a switch that has failed authentication.

1.6.1  Configuration Prerequisites

The configuration NTP authentication involves configuration tasks to be implemented on the client and on the server.

When configuring the NTP authentication feature, pay attention to the following principles:

l           For all synchronization modes, when you enable the NTP authentication feature, you should configure an authentication key and specify it as a trusted key. Namely, the ntp-service authentication enable command must work together with the ntp-service authentication-keyid command and the ntp-service reliable authentication-keyid command. Otherwise, the NTP authentication function cannot be normally enabled.

l           For the server/client mode or symmetric mode, you need to associate the specified authentication key on the client (symmetric-active peer if in the symmetric peer mode) with the corresponding NTP server (symmetric-passive peer if in the symmetric peer mode). Otherwise, the NTP authentication feature cannot be normally enabled.

l           For the broadcast server mode or multicast server mode, you need to associate the specified authentication key on the broadcast server or multicast server with the corresponding NTP server. Otherwise, the NTP authentication feature cannot be normally enabled.

l           For the server/client mode, if the NTP authentication feature has not been enabled for the client, the client can synchronize with the server regardless the NTP authentication feature has been enabled for the server or not.

l           For all synchronization modes, the server side and the client side must be consistently configured.

l           If the NTP authentication is enabled on a client, the client can be synchronized only to a server that can provide a trusted authentication key.

1.6.2  Configuration Procedure

I. Configuring NTP authentication for a client

Follow these steps to configure NTP authentication for a client:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enable NTP authentication	ntp-service authentication enable	Required Disabled by default
Configure an NTP authentication key	ntp-service authentication-keyid keyid authentication-mode md5 value	Required No NTP authentication key by default
Configure the key as a trusted key	ntp-service reliable authentication-keyid keyid	Required No authentication key is configured to be trusted by default
Associate the specified key with an NTP server	Server/client mode: ntp-service unicast-server { ip-address | server-name } authentication-keyid keyid	Required You can associate a non-existing key with an NTP server. To enable NTP authentication, you must configure the key and specify it as a trusted key after associating the key with the NTP server.
	Symmetric peers mode: ntp-service unicast-peer { ip-address | peer-name } authentication-keyid keyid

 

 

II. Configuring NTP authentication for a server

Follow these steps to configure NTP authentication for a server:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enable NTP authentication	ntp-service authentication enable	Required Disabled by default
Configure an NTP authentication key	ntp-service authentication-keyid keyid authentication-mode md5 value	Required No NTP authentication key by default
Configure the key as a trusted key	ntp-service reliable authentication-keyid keyid	Required No authentication key is configured to be trusted by default
Enter interface view	interface interface-type interface-number	—
Associate the specified key with an NTP server	Broadcast server mode: ntp-service broadcast-server authentication-keyid keyid	Required You can associate a non-existing key with an NTP server. To enable NTP authentication, you must configure the key and specify it as a trusted key after associating the key with the NTP server.
	Multicast server mode: ntp-service multicast-server authentication-keyid keyid

 

 

1.7  Displaying and Maintaining NTP

To do…	Use the command…	Remarks
View the information of NTP service status	display ntp-service status	Available in any view
View the information of NTP sessions	display ntp-service sessions [ verbose ]	Available in any view
View the brief information of the NTP servers from the local switch back to the primary reference source	display ntp-service trace	Available in any view

 

1.8  NTP Configuration Examples

1.8.1  Configuring NTP Server/Client Mode

I. Network requirements

l           The local clock of Switch A is to be used as a reference source, with the stratum level of 2.

l           Switch B works in the server/client mode and Switch A is to be used as the NTP server of Switch B.

II. Network diagram

Figure 1-7 Network diagram for NTP server/client mode configuration

III. Configuration procedure

1)         Configuration on Switch A:

# Specify the local clock as the reference source, with the stratum level of 2.

<SwitchA> system-view

[SwitchA] ntp-service refclock-master 2

2)         Configuration on Switch B:

# View the NTP status of Switch B before clock synchronization.

<SwitchB> display ntp-service status

Clock status: unsynchronized

Clock stratum: 16

Reference clock ID: none

Nominal frequency: 100.0000 Hz

Actual frequency: 100.0000 Hz

Clock precision: 2^7

Clock offset: 0.0000 ms

Root delay: 0.00 ms

Root dispersion: 0.00 ms

Peer dispersion: 0.00 ms

Reference time: 00:00:00.000 UTC Jan 1 1900 (00000000.00000000)

# Specify Switch A as the NTP server of Switch B so that Switch B is synchronized to Switch A.

<SwitchB> system-view

[SwitchB] ntp-service unicast-server 1.0.1.11

# View the NTP status of Switch B after clock synchronization.

[SwitchB] display ntp-service status

Clock status: synchronized

Clock stratum: 3

Reference clock ID: 1.0.1.11

Nominal frequency: 100.0000 Hz

Actual frequency: 100.0000 Hz

Clock precision: 2^7

Clock offset: 0.0000 ms

Root delay: 31.00 ms

Root dispersion: 1.05 ms

Peer dispersion: 7.81 ms

Reference time: 14:53:27.371 UTC Apr 20 2007 (C6D94F67.5EF9DB22)

As shown above, Switch B has been synchronized to Switch A, and the clock stratum level of Switch B is 3, while that of Switch A is 2.

# View the NTP session information of Switch B, which shows that an association has been set up between Switch B and Switch A.

[SwitchB] display ntp-service sessions

source      reference   stra  reach  poll  now  offset  delay  disper

**************************************************************************

[12345] 1.0.1.11  127.127.1.0    2    63    64    3    -75.5    31.0  16.5

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1

1.8.2  Configuring the NTP Symmetric Mode

I. Network requirements

l           The local clock of Switch A is to be configured as a reference source, with the stratum level of 2.

l           Switch B works in the client mode and Switch A is to be used as the NTP server of Switch B.

l           Switch C works in the symmetric-active mode and Switch B will act as peer of Switch C. Switch C is the symmetric-active peer while Switch B is the symmetric-passive peer.

II. Network diagram

Figure 1-8 Network diagram for NTP symmetric peers mode configuration

III. Configuration procedure

1)         Configuration on Switch A:

# Specify the local clock as the reference source, with the stratum level of 2.

<SwitchA> system-view

[SwitchA] ntp-service refclock-master 2

2)         Configuration on Switch B:

# Specify Switch A as the NTP server of Switch B.

<SwitchB> system-view

[SwitchB] ntp-service unicast-server 3.0.1.31

3)         Configuration on Switch C (after Switch B is synchronized to Switch A):

# Specify the local clock as the reference source, with the stratum level of 1.

<SwitchC> system-view

[SwitchC] ntp-service refclock-master 1

# Configure Switch B as a symmetric peer after local synchronization.

[SwitchC] ntp-service unicast-peer 3.0.1.32

In the step above, Switch B and Switch C are configured as symmetric peers, with Switch C in the symmetric-active mode and Switch B in the symmetric-passive mode. Because the stratus level of Switch C is 1 while that of Switch B is 3, Switch B is synchronized to Switch C.

# View the NTP status of Switch B after clock synchronization.

[SwitchB] display ntp-service status

Clock status: synchronized

 Clock stratum: 2

 Reference clock ID: 3.0.1.33

 Nominal frequency: 100.0000 Hz

 Actual frequency: 100.0000 Hz

 Clock precision: 2^7

Clock offset: -21.1982 ms

 Root delay: 15.00 ms

 Root dispersion: 775.15 ms

 Peer dispersion: 34.29 ms

 Reference time: 15:22:47.083 UTC Apr 20 2007 (C6D95647.153F7CED)

As shown above, Switch B has been synchronized to Switch C, and the clock stratum level of Switch B is 2, while that of Switch C is 1.

# View the NTP session information of Switch B, which shows that an association has been set up between Switch B and Switch C.

[SwitchB] display ntp-service sessions

       source     reference   stra  reach  poll  now   offset delay  disper

**************************************************************************

[245] 3.0.1.31  127.127.1.0    2    15    64   24   10535.0  19.6   14.5

[1234] 3.0.1.33   LOCL         1    14    64   27    -77.0   16.0   14.8

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  2

1.8.3  Configuring NTP Broadcast Mode

I. Network requirements

l           Switch C’s local clock is to be used as a reference source, with the stratum level of 2.

l           Switch C works in the broadcast server mode and sends out broadcast messages from VLAN-interface 2.

l           Switch D and Switch A work in the broadcast client mode and listen to broadcast messages through their respective VLAN-interface 2.

II. Network diagram

Figure 1-9 Network diagram for NTP broadcast mode configuration

III. Configuration procedure

1)         Configuration on Switch C:

# Specify the local clock as the reference source, with the stratum level of 2.

<SwitchC> system-view

[SwitchC] ntp-service refclock-master 2

# Configure Switch C to work in the broadcast server mode and send broadcast messages through VLAN-interface 2.

[SwitchC] interface vlan-interface 2

[SwitchC-Vlan-interface2] ntp-service broadcast-server

2)         Configuration on Switch D:

# Configure Switch D to work in the broadcast client mode and receive broadcast messages on VLAN-interface 2.

<SwitchD> system-view

[SwitchD] interface vlan-interface 2

[SwitchD-Vlan-interface2] ntp-service broadcast-client

3)         Configuration on Switch A:

# Configure Switch A to work in the broadcast client mode and receive broadcast messages on VLAN-interface 3.

<SwitchA> system-view

[SwitchA] interface vlan-interface 3

[SwitchA-Vlan-interface3] ntp-service broadcast-client

Because Switch A and Switch C are on different subnets, Switch A cannot receive the broadcast messages from Switch C Switch D gets synchronized upon receiving a broadcast message from Switch C.

# View the NTP status of Switch D after clock synchronization.

[SwitchD] display ntp-service status

Clock status: synchronized

 Clock stratum: 3

 Reference clock ID: 3.0.1.31

 Nominal frequency: 100.0000 Hz

 Actual frequency: 100.0000 Hz

 Clock precision: 2^7

 Clock offset: 0.0000 ms

 Root delay: 31.00 ms

 Root dispersion: 8.31 ms

 Peer dispersion: 34.30 ms

 Reference time: 16:01:51.713 UTC Apr 20 2007 (C6D95F6F.B6872B02)

As shown above, Switch D has been synchronized to Switch A, and the clock stratum level of Switch D is 3, while that of Switch C is 2.

# View the NTP session information of Switch D, which shows that an association has been set up between Switch D and Switch C.

[SwitchD] display ntp-service sessions

      source    reference      stra  reach  poll  now    offset delay  disper

**************************************************************************

[1234] 3.0.1.31  127.127.1.0   2   254     64    62   -16.0    32.0   16.6

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1

1.8.4  Configuring NTP Multicast Mode

I. Network requirements

l           Switch C’s local clock is to be used as a reference source, with the stratum level of 2.

l           Switch C works in the multicast server mode and sends out multicast messages from VLAN-interface 2.

l           Switch D and Switch A work in the multicast client mode and receive multicast messages through their respective VLAN-interface 2.

II. Network diagram

Figure 1-10 Network diagram for NTP multicast mode configuration

III. Configuration procedure

1)         Configuration on Switch C:

# Specify the local clock as the reference source, with the stratum level of 2.

<SwitchC> system-view

[SwitchC] ntp-service refclock-master 2

# Configure Switch C to work in the multicast server mode and send multicast messages through VLAN-interface 2.

[SwitchC] interface vlan-interface 2

[SwitchC-Vlan-interface2] ntp-service multicast-server

2)         Configuration on Switch D:

# Configure Switch D to work in the multicast client mode and receive multicast messages on VLAN-interface 2.

<SwitchD> system-view

[SwitchD] interface vlan-interface 2

[SwitchD-Vlan-interface2] ntp-service multicast-client

Because Switch D and Switch C are on the same subnet, Switch D can receive the multicast messages from Switch C without being IGMP-enabled and can be synchronized to Switch C.

# View the NTP status of Switch D after clock synchronization.

[SwitchD] display ntp-service status

Clock status: synchronized

 Clock stratum: 3

 Reference clock ID: 3.0.1.31

 Nominal frequency: 100.0000 Hz

 Actual frequency: 100.0000 Hz

 Clock precision: 2^7

 Clock offset: 0.0000 ms

 Root delay: 31.00 ms

 Root dispersion: 8.31 ms

 Peer dispersion: 34.30 ms

 Reference time: 16:01:51.713 UTC Apr 20 2007 (C6D95F6F.B6872B02)

As shown above, Switch D has been synchronized to Switch C, and the clock stratum level of Switch D is 3, while that of Switch C is 2.

# View the NTP session information of Switch D, which shows that an association has been set up between Switch D and Switch C.

[SwitchD] display ntp-service sessions

      source    reference      stra  reach  poll  now    offset delay  disper

**************************************************************************

[1234] 3.0.1.31  127.127.1.0   2   254     64    62   -16.0    31.0   16.6

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1

3)         Configuration on Switch B:

Because Switch A and Switch C are on different subnets, you must enable IGMP on Switch B before Switch A can receive multicast messages from Switch C.

# Enable IP multicast routing and IGMP.

<SwitchB> system-view

[SwitchB] multicast routing-enable

[SwitchB] interface vlan-interface 2

[SwitchB-Vlan-interface2] pim dm

[SwitchB-Vlan-interface2] quit

[SwitchB] vlan 3

[SwitchB-vlan3] port GigabitEthernet 1/0/1

[SwitchB-vlan3] quit

[SwitchB] interface vlan-interface 3

[SwitchB-Vlan-interface3] igmp enable

[SwitchB-Vlan-interface3] quit

[SwitchB] interface GigabitEthernet 1/0/1

[SwitchB-GigabitEthernet1/0/1] igmp-snooping static-group 224.0.1.1 vlan 3

4)         Configuration on Switch A:

# Enable IP multicast routing and IGMP.

<SwitchA> system-view

[SwitchA] interface vlan-interface 3

# Configure Switch A to work in the multicast client mode and receive multicast messages on VLAN-interface 3.

[SwitchA-Vlan-interface3] ntp-service multicast-client

# View the NTP status of Switch A after clock synchronization.

[SwitchA] display ntp-service status

Clock status: synchronized

 Clock stratum: 3

 Reference clock ID: 3.0.1.31

 Nominal frequency: 100.0000 Hz

 Actual frequency: 100.0000 Hz

 Clock precision: 2^7

 Clock offset: 0.0000 ms

 Root delay: 40.00 ms

 Root dispersion: 10.83 ms

 Peer dispersion: 34.30 ms

 Reference time: 16:02:49.713 UTC Apr 20 2007 (C6D95F6F.B6872B02)

As shown above, Switch A has been synchronized to Switch C, and the clock stratum level of Switch A is 3, while that of Switch C is 2.

# View the NTP session information of Switch A, which shows that an association has been set up between Switch A and Switch C.

[SwitchA] display ntp-service sessions

      source    reference      stra  reach  poll  now    offset delay  disper

**************************************************************************

[1234] 3.0.1.31  127.127.1.0    2   255     64    26   -16.0    40.0   16.6

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1

 

 

1.8.5  Configuring NTP Server/Client Mode with Authentication

I. Network requirements

l           The local clock of Switch A is to be configured as a reference source, with the stratum level of 2.

l           Switch B works in the client mode and Switch A is to be used as the NTP server of Switch B, with Switch B as the client.

l           NTP authentication is to be enabled for Switch A and Switch B at the same time.

II. Network diagram

Figure 1-11 Network diagram for configuration of NTP server/client mode with authentication

III. Configuration procedure

1)         Configuration on Switch A:

# Specify the local clock as the reference source, with the stratum level of 2.

<SwitchA> system-view

[SwitchA] ntp-service refclcok-master 2

2)         Configuration on Switch B:

<SwitchB> system-view

# Enable NTP authentication on Switch B.

[SwitchB] ntp-service authentication enable

# Set an authentication key.

[SwitchB] ntp-service authentication-keyid 42 authentication-mode md5 aNiceKey

# Specify the key as key as a trusted key.

[SwitchB] ntp-service reliable authentication-keyid 42

# Specify Switch A as the NTP server.

[SwitchB] ntp-service unicast-server 1.0.1.11 authentication-keyid 42

Before Switch B can synchronize its clock to that of Switch A, you need to enable NTP authentication for Switch A.

Perform the following configuration on Switch A:

# Enable NTP authentication.

[SwitchA] ntp-service authentication enable

# Set an authentication key.

[SwitchA] ntp-service authentication-keyid 42 authentication-mode md5 aNiceKey

# Specify the key as key as a trusted key.

[SwitchA] ntp-service reliable authentication-keyid 42

# View the NTP status of Switch B after clock synchronization.

[SwitchB] display ntp-service status

Clock status: synchronized

Clock stratum: 3

Reference clock ID: 1.0.1.11

Nominal frequency: 100.0000 Hz

Actual frequency: 100.0000 Hz

Clock precision: 2^7

Clock offset: 0.0000 ms

Root delay: 31.00 ms

Root dispersion: 1.05 ms

Peer dispersion: 7.81 ms

Reference time: 14:53:27.371 UTC Apr 20 2007 (C6D94F67.5EF9DB22)

As shown above, Switch B has been synchronized to Switch A, and the clock stratum level of Switch B is 3, while that of Switch A is 2.

# View the NTP session information of Switch B, which shows that an association has been set up Switch B and Switch A.

[SwitchB] display ntp-service sessions

source      reference   stra  reach  poll  now  offset  delay  disper

**************************************************************************

[12345] 1.0.1.11  127.127.1.0    2    63    64    3    -75.5    31.0  16.5

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1

1.8.6  Configuring NTP Broadcast Mode with Authentication

I. Network requirements

l           Switch C’s local clock is to be used as a reference source, with the stratum level of 3.

l           Switch C works in the broadcast server mode and sends out broadcast messages from VLAN-interface 2.

l           Switch D works in the broadcast client mode and receives broadcast messages through VLAN-interface 2.

l           NTP authentication is enabled on both Switch C and Switch D.

II. Network diagram

Figure 1-12 Network diagram for configuration of NTP broadcast mode with authentication

III. Configuration procedure

1)         Configuration on Switch C:

# Specify the local clock as the reference source, with the stratum level of 3.

<SwitchC> system-view

[SwitchC] ntp-service refclock-master 3

# Configure NTP authentication

[SwitchC] ntp-service authentication enable

[SwitchC] ntp-service authentication-keyid 88 authentication-mode md5 123456

[SwitchC] ntp-service reliable authentication-keyid 88

# Specify Switch C as an NTP broadcast server, and specify an authentication key.

[SwitchC] interface vlan-interface 2

[SwitchC-Vlan-interface2] ntp-service broadcast-server authentication-keyid 88

2)         Configuration on Switch D:

# Configure NTP authentication

<SwitchD> system-view

[SwitchD] ntp-service authentication enable

[SwitchD] ntp-service authentication-keyid 88 authentication-mode md5 123456

[SwitchD] ntp-service reliable authentication-keyid 88

# Configure Switch D to work in the NTP broadcast client mode

[SwitchD] interface vlan-interface 2

[SwitchD-Vlan-interface2] ntp-service broadcast-client

Now, Switch D can receive broadcast messages through VLAN-interface 2, and Switch C can send broadcast messages through VLAN-interface 2. Upon receiving a broadcast message from Switch C, Switch D synchronizes its clock to that of Switch C.

# View the NTP status of Switch D after clock synchronization.

[SwitchD] display ntp-service status

Clock status: synchronized

 Clock stratum: 4

 Reference clock ID: 3.0.1.31

 Nominal frequency: 100.0000 Hz

 Actual frequency: 100.0000 Hz

 Clock precision: 2^7

 Clock offset: 0.0000 ms

 Root delay: 31.00 ms

 Root dispersion: 8.31 ms

 Peer dispersion: 34.30 ms

 Reference time: 16:01:51.713 UTC Apr 20 2007 (C6D95F6F.B6872B02)

As shown above, Switch D has been synchronized to Switch B, and the clock stratum level of Switch D is 3, while that of Switch C is 2.

# View the NTP session information of Switch D, which shows that an association has been set up between Switch D and Switch C.

[SwitchD] display ntp-service sessions

      source    reference      stra  reach  poll  now    offset delay  disper

**************************************************************************

[1234] 3.0.1.31  127.127.1.0   3   254     64    62   -16.0    32.0   16.6

note: 1 source(master),2 source(peer),3 selected,4 candidate,5 configured

Total associations :  1