Switch Configuration for IP Surveillance. Application Notes

Switch Configuration for IP Surveillance Application Notes

Table of Contents Concepts... Transmission Modes... Video Compression... How to Use this Document... Reference Configurations and Assumptions... Configuration for the -Camera Solution... Assumptions for the -Camera Solution... Global Configuration Notes... Sample Configuration Values... CLI Configuration Steps: -Camera Solution... Web GUI Configuration Steps: -Camera Solution... Configuration for the 0-Camera Solution... Assumptions for the 0-Camera Solution... Global Configuration Notes... Sample Configuration Values... CLI Configuration Steps: 0-Camera Solution... Web GUI Configuration Steps: 0-Camera Solution... Configuration for the 00-Camera Solution... Assumptions for the 00-Camera Solution... Global Configuration Notes... Sample Configuration Values... CLI Configuration Steps: 00-Camera Solution... Switch XSMS... Switch M00-G... Switch M00-G-POE+... Web GUI Configuration Steps: 00-Camera Solution... Switch XSMS... Switch M00-G... Switch M00-G-POE+... Page

Concepts Video surveillance based on digital IP technology is revolutionizing the physical security industry. The network is a crucial element in any surveillance installation because it enables all the other surveillance functions transmitting video streams so they can be viewed and stored, and carrying power to the cameras themselves using Power over Ethernet (PoE). An IP surveillance system always includes one or more of the following components: IP cameras Video servers to record, aggregate, process, and broadcast video streams Clients (monitoring stations), which are typically PCs equipped with dedicated surveillance software to enable real-time viewing and review of stored video Network Attached Storage (NAS) devices to store the video Switches with the appropriate feature set and bandwidth capacity to manage network traffic required for the entire surveillance network to function properly CATE or better cabling, for adequate performance Operation involves transmission (streaming) of video information from the cameras to a video server, where it is aggregated, processed, stored, and distributed to the monitoring stations and storage devices. Factors such as transmission modes and video compression modes can have a significant effect on bandwidth requirements, storage requirements and cost. Transmission Modes There are two basic transmission modes: unicast and multicast. Most cameras can be set to transmit in either mode. Unicast mode is a direct, one-to-one means of transmitting a video stream, such as from a camera to a video server, or from a video server to a client. For example, if a video server needs to transmit to four clients, it must send the same transmission four times. In a system with dozens of camera streams and numerous clients, unicasting can easily overwhelm the bandwidth capacity of the network switches. Multicast mode is a one-to-many mode where servers publish a video stream and clients subscribe. In multicast mode, video streams, identified by an IP address, are broadcast across the network, and any client on that network has the potential to access them. Access to any given stream is controlled by the Internet group management Protocol (IGMP). Under this protocol, clients are divided into groups based on which streams they are authorized to access. The following switch components are required to manage this process: An IGMP Querier that generates query messages to determine which clients belong to various groups An IGMP Snooper that listens to the various ports on the client hardware to determine which ports are interested in the stream and then sends data only to those ports. In networks that have been upgraded to the IPv standard, the IGMP Querier is replaced by a multicast listener discovery (MLD) Querier and an MLD Snooper. Most IP surveillance networks combine these unicast and multicast modes, using unicast to transmit from the cameras to the video server, and multicast to transmit to the clients. Page

M0-0-POE PoE SPD Power 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M RPS Max Link/ACT mode: PoE Off=No link Green=Link Blinking=ACT USB 0 0 T 0T F 0F PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT Power RPS Max PoE USB M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M Link/ACT mode: Off=No link Green=Link Blinking=ACT 0 0 T 0T F 0F PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT Video Compression All video data captured by the camera is compressed prior to transmission, and the mathematical algorithm used for this has important effects on both the end user and the network itself. The compression algorithm can affect image quality, latency, bandwidth requirements, and storage requirements. The most popular video compression standards (with dates of introduction) are MJPEG (mid-0s), MPEG (), AND H. (0). In addition, some major IP camera vendors use proprietary standards. How to Use this Document The Networking Solutions for IP Surveillance Solution Guide provides technical guidance and details about reference designs for installations with, 0 and 00 cameras. Use the Solution Guide to plan your solution architecture and determine the needed equipment. Clients (Receivers, viewers) Rest of the network This Application Note is a companion document to the Solution Guide. After you have planned and have the equipment for your network, use this guide to configure your video surveillance solution. Example configurations are provided for -camera, 0-camera, and 00-camera deployments. Reference Configurations and Assumptions The following figures show reference configurations M0-0-P for OE-camera, 0-camera, and 00-camera solutions. Clients (Receivers, viewers) Media Server (Gigabit) Rest of the network IP Cameras M 0 0-0 -P O E Copper, Gigabit RJ Copper, /0 RJ PoE Media Server (Gigabit) Copper, /0 RJ IP Cameras Copper, Gigabit RJ Copper, /0 RJ PoE Copper, /0 RJ Figure. Sample Solution Cameras Page

Stack ID Power Stack ID Power S P D S P D ACT ACT RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT Power RPS Max PoE USB 0 0 0 SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act Green=G Link Y ellow=g B link=a CT PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT 0 0 0 0 T T T T T T T T F F 0 F F F F F F F F 0 F 0F M00-G M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M 0 SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act Green=G Link Y ellow=g B link=a CT 0 T T T T T T T T F F F F F F Power RPS Max PoE F F USB F F 0 F 0F M00-G T T T T 0 T 0T 0 T 0T SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT T 0T F 0F Link/ACT mode: Off=No link Green=Link Blinking=ACT Stack ID PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT Power 0 RJ ACT Mode: Green = Link Blink = ACT RJ SPD mode: Green = Link at G Yellow = Link at /0M M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = ACT 0 SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT Power RPS Max PoE USB T 0T F 0F Link/ACT mode: Off=No link Green=Link Blinking=ACT F F F F F F F F T T PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT T T T T T T F F M00-GF F T T F T T Green=G Link Y ellow=g B link=a CT M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M 0 0 SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT T 0T Power RPS Max PoE F USB 0F Stack ID Power Link/ACT mode: Off=No link Green=Link Blinking=ACT PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT RJ ACT Mode: Green = Link Blink = ACT RJ SPD mode: Green = Link at G Yellow = Link at /0M SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = ACT M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M 0 0 F F F F F F T F F T T SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT Power RPS Max PoE USB 0T F T T 0F T T T T Link/ACT mode: Off=No link Green=Link Blinking=ACT F F M00-GF F T T F T T Green=G Link Y ellow=g B link=a CT M0-0-POE PoE SPD 0 0 T 0T F 0F SPD Link/ACT Ports T, 0T SPD: Green=G Yellow=/0M PoE (Max.W per port): Off = no PD Green = PoE Powered Yellow = PoE f ault RJ SPD mode: Green = Link at 0M Yellow=Link at M Blink = ACT 0 0 SFP SPD/Link/ACT mode: Green=Link at G Yellow=Link at 0M Blink=ACT T 0T F 0F Link/ACT mode: Off=No link Green=Link Blinking=ACT Rest of the network M 0 0 - G Media Servers (Gigabit) Clients (Receivers, viewers) M 0 0 - G F M 0 0-0 -P O E 0 IP Cameras ( switches) Fiber, 00SX multimode Copper, Gigabit RJ Copper, /0 RJ PoE Copper, Gigabit Stacking Copper, GBASE-T RJ Figure. Sample Solution 0 Cameras Page

h switc s per a r e m ca tches ras i w came s, = x M 0 0 - G -P O E + M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT r dia Se Me = x t) igabi ( G M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT vers M00-G-POE+ M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T SP D ACT 0 0 T T T T F F F F F 0 F T 0 T 0 T Power Power Stack ID Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T ACT 0 0 T T T T 0T RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT Green=G Link Yellow=G Blink=ACT M00-G-POE+ M00-G-POE+ SP D F F F F F 0 F T SP D ACT 0 0 T T T T F F F F F 0 F T 0 T 0 T Stack ID Power Power Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T XSMS US B F F F F M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T 0 0 T T T T F F F F F 0 F T T T Right side LED: Blink=Act Of f =No Link Y ellow=link at /0M 0 T Power Power US B F F F F T T T T Right side LED: Blink=Act Of f =No Link Y ellow=link at /0M 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T 0 0 T T T T 0 0 T T T T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT F F F F F 0 F T ACT 0 0 T T T T F F F F F 0 F T 0 T RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D XSMS ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power F F F F T T T T Right side LED: Blink=Act Of f =No Link Y ellow=link at /0M Power Power US B Lef t side LED: Blink=Act Of f =No Link Green=Link at G Y ellow=link at G Console 00,N., F F F F T T T T Right side LED: Blink=Act Of f =No Link Y ellow=link at /0M RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT Console 00,N., M00-G-POE+ M00-G-POE+ Power Power US B ACT M00-G-POE+ Port T-T Stack Master Lef t side LED: Blink=Act Of f =No Link Green=Link at G Y ellow=link at G Power 0T Green=G Link Yellow=G Blink=ACT SP D Console 00,N., ID Port T-T Stack Master SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act Stack ID XSMS ID XSMS Power Stack ID Lef t side LED: Blink=Act Of f =No Link Green=Link at G Y ellow=link at G Console 00,N., SP D 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ ACT T X S MS 0 T Power SP D T Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT Port T-T Stack Master Lef t side LED: Blink=Act Of f =No Link Green=Link at G Y ellow=link at G Power Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT ID Port T-T Stack Master RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT Green=G Link Yellow=G Blink=ACT ID 0T SP D ACT 0 0 T T T T F F F F F 0 F T 0 T 0 T Stack ID Power Power Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T ACT 0 0 T T T T 0T RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT Green=G Link Yellow=G Blink=ACT M00-G-POE+ M00-G-POE+ SP D F F F F F 0 F T SP D ACT 0 0 T T T T F F F F F 0 F T 0 T 0 T Stack ID Power Power Stack ID 0 0 T T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act F F F F 0F F T ACT RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T T T F M 0 0 - G M00-G-POE+ SP D 0T Green=G Link Yellow=G Blink=ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power M00-G RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T SP D 0T ACT 0 0 T T T T F F F F F 0 F T 0 T Green=G Link Yellow=G Blink=ACT ACT 0 0 T T T T F F F F F 0 F T Power 0 T Power Stack ID M00-G-POE+ SP D Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T RJ SPD Mode: Green = Link at G Yellow = Link at /0MRJACTmode:Green=LinkBlink=ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0MBlink =Act T F F F F F 0F T 0T Green=G Link Y ellow=g B l i nk=a CT Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Stack ID Power M00-G RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T SP D 0T ACT 0 0 T T T T F F F F F 0 F T 0 T Green=G Link Yellow=G Blink=ACT Stack ID M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T Power 0 T Stack ID Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T ACT 0 0 T T T T F F F F F 0 F T 0 T RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T T T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT M00-G-POE+ SP D ACT 0 0 T T T T F F F F F 0 F T 0 T Power RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT 0 0 T SFP SPD mode: Green = Link at G Yellow = Link at 0M Blink = Act T T T SFP SPD mode: Green = Link at G Yellow = Link at 0MBlink =Act 0 0 T T T T F F F F F 0F T 0T Green=G Link Y ellow=g B l i nk=a CT ork netw e h t f o Rest M00-G-POE+ SP D Power Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0MRJACTmode:Green=LinkBlink=ACT 0T Green=G Link Yellow=G Blink=ACT Stack ID RJ SPD Mode: Green = Link at G Yellow = Link at /0M RJ ACT mode: Green = Link Blink = ACT F F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT ts Clien rs, ive (Rece rs) viewe Fiber, 00SX multimode Copper, Gigabit RJ Copper, /0/00 RJ PoE Copper, 0 Gigabit Stacking Copper, Gigabit Stacking Copper, GBASE-T RJ Fiber, GBASE-LR single mode Fiber, GSFP+ CU DAC Figure. Sample Solution 00 Cameras Page F F F F 0F T 0T Green=G Link Yellow=G Blink=ACT

Configuration for the -Camera Solution You can use the CLI or Web GUI for configuration. Assumptions for the -Camera Solution A DHCP server has already been configured for the VLAN 0 subnet. You are able to configure VLAN interfaces if necessary (steps to configure the interfaces are not included). The video server is configured to broadcast UDP mulitcast packets @... over port 00. There is only one multicast source. The surveillance network is a dedicated, isolated network architecture with a single uplink to the the customer s enterprise network. Client protection will be managed by security measures local to the client viewing station. Global Configuration Notes Be sure to save your configuration using the write memory CLI command. Alternatively, choose Maintenance > Save Config in the GUI. Select the box, and click APPLY. You can configure the default IGMP querier in the global configuration as the default for all VLANs Sample Configuration Values The following values are used in the sample configuration: Primary VLAN: 0 Camera VLAN: Client VLAN: Querier IP address:... Port in promiscous mode: Camera ports: - Client ports: - Page

CLI Configuration Steps: -Camera Solution These steps provide an example CLI configuration for the -camera solution. To use the Web GUI for configuration, see Web GUI Configuration Steps: -Camera Solution on page.. Create VLANs in the database for the single switch (Switch), as shown in Figure. Private VLANs (PVLANs) are used as secondary VLANs to logically segment the different endpoints. Secondary VLANs inherit most network configuration settings from the associated primary VLAN. (Switch) #vlan database (Switch) (Vlan)#vlan 0 (Switch) (Vlan)#vlan name 0 PrimaryVlan (Switch) (Vlan)#vlan (Switch) (Vlan)#vlan name CameraVlan (Switch) (Vlan)#vlan (Switch) (Vlan)#vlan name ClientVlan (Switch) (Vlan)#exit. After configuring the VLAN 0 subnet on its interface, set the private VLAN designation to each VLAN and associate the secondary VLANs to the primary VLAN. (Switch) #configure (Switch) (Config)#vlan (Switch) (Config)(Vlan )#private-vlan isolated (Switch) (Config)(Vlan )#exit (Switch) (Config)#vlan (Switch) (Config)(Vlan )#private-vlan community (Switch) (Config)(Vlan )#exit (Switch) (Config)#vlan 0 (Switch) (Config)(Vlan 0)#private-vlan primary (Switch) (Config)(Vlan 0)#private-vlan association - (Switch) (Config)(Vlan 0)#exit. Configure the querier for primary Vlan 0 and enable the fast-leave feature for clients subscribing to the multicast source content. (Switch) #vlan database (Switch) (Vlan)#set igmp 0 (Switch) (Vlan)#set igmp querier 0 address... (Switch) (Vlan)#set igmp fast-leave 0 (Switch) (Vlan)#end Page

. For IGMP snooping to work with VLANs, enable the capability globally. (Switch) #configure (Switch) (Config)#set igmp interfacemode (Switch) (Config)#end. Configure the video server port as a promiscuous port to allow all private VLANs to speak to it. (Switch) #configure (Switch) (Config)#interface 0/ (Switch) (Interface 0/)#switchport mode private-vlan promiscuous (Switch) (Interface 0/)#switchport private-vlan mapping 0 - (Switch) (Interface 0/)#no shut (Switch) (Interface 0/)#end. Configure camera ports on the isolated VLAN. (Switch) #configure (Switch) (Config)#interface 0/-0/ (Switch) (Interface 0/-0/)#vlan participation exclude (Switch) (Interface 0/-0/)#vlan participation include 0- (Switch) (Interface 0/-0/)#vlan pvid (Switch) (Interface 0/-0/)#no shut (Switch) (Interface 0/-0/)#end. Configure client ports on the community VLAN. (Switch) #configure (Switch) (Config)#interface 0/-0/ (Switch) (Interface 0/-0/)#vlan participation exclude (Switch) (Interface 0/-0/)#vlan participation include 0, (Switch) (Interface 0/-0/)#vlan pvid (Switch) (Interface 0/-0/)#no shut (Switch) (Interface 0/-0/)#end Page

Web GUI Configuration Steps: -Camera Solution These steps provide an example Web GUI configuration for the -camera solution. To use the CLI for configuration, see CLI Configuration Steps: -Camera Solution on page.. Create VLANs in the database for the single switch (Switch), as shown in Figure. Private VLANs (PVLANs) are used as secondary VLANs to logically segment the different endpoints. Secondary VLANs inherit most network configuration settings from the associated primary VLAN. In this scenario, VLAN 0 is the primary Vlan, VLAN is the isolated VLAN for the cameras, and VLAN is the community VLAN for clients. Choose Switching > VLAN > Advanced > VLAN Configuration. Enter each VLAN ID and name, and click ADD to add the VLAN. Page

. Choose Security > Traffic Control > Private VLAN > Private VLAN Type Configuration. Assign the appropriate VLAN type to each VLAN ID. Click APPLY after each entry. Page

. Choose Security > Traffic Control > Private Vlan > Private Vlan Association Configuration. Set VLAN 0 as the primary VLAN and - as the secondary VLANs. Click APPLY. Page

. Choose Switching > Multicast > IGMP Snooping > IGMP Vlan Configuration. Enable Admin Mode and Fast-Leave Admin Mode on VLAN 0, and click ADD. Page

. Choose Switching > Multicast > IGMP Snooping > Configuration. Enable Admin Mode to enable IGMP snooping globally and verify that VLAN 0 is listed as under VLAN IDs Enabled for IGMP Snooping. Click APPLY. Page

. Choose Switching > Multicast > IGMP Snooping > Querier VLAN Configuration. Set the querier address of... for VLAN 0, and click ADD. Page

. Choose Security > Traffic Control > Private Vlan > Private Vlan Promiscuous Interface Configuration. Configure source port 0/ as a promiscuous port with primary VLAN 0 and secondary VLAN -. Click APPLY. Page

. Choose Switching > VLAN > Advanced > VLAN Membership. For each of the VLANs, add the appropriate ports as untagged. Click APPLY. Page

. Choose Switching > VLAN > Advanced > Port PVID Configuration. Assign the PVID to camera and client ports accordingly. Click APPLY. Page

Configuration for the 0-Camera Solution You can use the CLI or Web GUI for configuration. Refer to Figure. Assumptions for the 0-Camera Solution A pre-existing DHCP server will be used to dynamically assign IPs to cameras and clients. Routing protocols and proper default routes are in place for existing and new subnets (in this case,...0/ for VLAN 0 and...0/ for VLAN 0). The video servers are configured to broadcast UDP multicast packets @...-... over port 00. There only five multicast sources. Best practices are used to design and implement switch stacking and redundancy/failover. Global Configuration Notes Be sure to save your configuration using the write memory CLI command. Alternatively, choose Maintenance > Save Config in the GUI. Select the box, and click APPLY. You can configure a maximum of multicast sources with the MVR feature. Sample Configuration Values The following values are used in the sample configuration: Primary VLAN (private): 0 Camera VLAN (private): Client VLAN: 0 Querier IP address:... MVR addresses:... -... Camera switch uplink port: Camera ports: -0 Page

CLI Configuration Steps: 0-Camera Solution These steps provide an example CLI configuration for the 0-camera solution. For the Web GUI configuration, see Web GUI Configuration Steps: 0-Camera Solution on page.. Configure VLANs 0 and as private VLANs, and configure VLAN 0 on all switches in the surveillance network. (Switch) #vlan database (Switch) (Vlan)#vlan 0 (Switch) (Vlan)#vlan name 0 PrimaryVlan (Switch) (Vlan)#vlan (Switch) (Vlan)#vlan name CameraVlan (Switch) (Vlan)#vlan 0 (Switch) (Vlan)#vlan name 0 ClientVlan (Switch) (Vlan)#exit (Switch) #configure (Switch) (Config)#vlan (Switch) (Config)(Vlan )#private-vlan isolated (Switch) (Config)(Vlan )#exit (Switch) (Config)#vlan 0 (Switch) (Config)(Vlan 0)#private-vlan primary (Switch) (Config)(Vlan 0)#private-vlan association (Switch) (Config)(Vlan 0)#exit. Configure the IGMP querier for primary VLAN 0 and enable the fast-leave feature for clients who subscribe to the multicast source content. (Switch) #vlan database (Switch) (Vlan)#set igmp 0 (Switch) (Vlan)#set igmp querier 0 address... (Switch) (Vlan)#set igmp fast-leave 0 (Switch) (Vlan)#end. for IGMP snooping to work with VLANs, enable the capability globally. (Switch) #configure (Switch) (Config)#set igmp interfacemode (Switch) (Config)#end. Configure MVR over VLAN 0 and set the MVR address with a contiguous count of sources (M00-GF-) #configure (M00-GF-) (Config)#mvr (M00-GF-) (Config)#mvr vlan 0 (M00-GF-) (Config)#mvr group... (M00-GF-) (Config)#end Page

. when configuring uplinks between the media server switches (M00-GF) and the client switches (M00- G), it is necessary to configure the uplink as an MVR source. The MVR source port automatically adds all globally configured MVR groups. (M00-G) #configure (M00-G) (Config)#interface /0/ (M00-G) (Interface /0/)#vlan participation exclude (M00-G) (Interface /0/)#vlan participation include 0 (M00-G) (Interface /0/)#mvr (M00-G) (Interface /0/)#mvr type source (M00-G) (Interface /0/)#vlan participation include,0 (M00-G) (Interface /0/)#vlan tagging 0-,0 (M00-G) (Interface /0/)#exit. on the other side of the uplink, configure the port as an MVR receiver. Take special note how to add each multicast source as an MVR group on the receiver ports. (M00-GF-) #configure (M00-GF-) (Config)#interface /0/ (M00-GF-) (Interface /0/)#vlan participation exclude (M00-GF-) (Interface /0/)#vlan participation include 0 (M00-GF-) (Interface /0/)#mvr (M00-GF-) (Interface /0/)#mvr type receiver (M00-GF-) (Interface /0/)#mvr immediate (M00-GF-) (Interface /0/)#mvr vlan 0 group... (M00-GF-) (Interface /0/)#mvr vlan 0 group... (M00-GF-) (Interface /0/)#mvr vlan 0 group... (M00-GF-) (Interface /0/)#mvr vlan 0 group... (M00-GF-) (Interface /0/)#mvr vlan 0 group... (M00-GF-) (Interface /0/)#vlan participation include,0 (M00-GF-) (Interface /0/)#vlan tagging 0-,0 (M00-GF-) (Interface /0/)#exit. Configure the camera switch (M0-0G-POE) uplinks. This configuration is simpler, as the uplinks do not include any MVR commands and the same configuration is used on the media server switch (M00-GF) as well. (M0-POE-) #configure (M0-POE-) (Config)#interface 0/ (M0-POE-) (Interface 0/)#vlan participation exclude (M0-POE-) (Interface 0/)#vlan participation include 0- (M0-POE-) (Interface 0/)#vlan tagging 0- (M0-POE-) (Interface 0/)#exit Page

. Configure each camera port on the camera switches. (M0-POE-) #configure (M0-POE-) (Config)#interface 0/-0/0 (M0-POE-) (Interface 0/-0/0)#switchport mode private-vlan host (M0-POE-) (Interface 0/-0/0)#switchport private-vlan host-association 0 (M0-POE-) (Interface 0/-0/0)#exit. on the video server switches, configure ports as promiscuous MVR sources. (M00-GF-) (Config)#interface /0/ (M00-GF-) (Interface /0/)#switchport mode private-vlan promiscuous (M00-GF-) (Interface /0/)#switchport private-vlan mapping 0 (M00-GF-) (Interface /0/)#mvr (M00-GF-) (Interface /0/)#mvr type source (M00-GF-) (Interface /0/)#exit. On the client switches, configure the ports as MVR receivers. Multicast sources as MVR groups must be explicitly listed on the port to be able to subscribe to the stream. (M00-G) #configure (M00-G) (Config)#interface /0/ (M00-G) (Interface /0/)#vlan pvid 0 (M00-G) (Interface /0/)#vlan participation exclude (M00-G) (Interface /0/)#vlan participation include 0 (M00-G) (Interface /0/)#mvr (M00-G) (Interface /0/)#mvr type receiver (M00-G) (Interface /0/)#mvr vlan 0 group... (M00-G) (Interface /0/)#mvr vlan 0 group... (M00-G) (Interface /0/)#mvr vlan 0 group... (M00-G) (Interface /0/)#mvr vlan 0 group... (M00-G) (Interface /0/)#mvr vlan 0 group... (M00-G) (Interface /0/)#exit Page

Web GUI Configuration Steps: 0-Camera Solution These steps provide an example Web GUI configuration for the 0-camera solution. To use the CLI for configuration, see CLI Configuration Steps: 0-Camera Solution on page.. VLAN 0 will be the primary VLAN, with secondary VLAN for camera (isolated) and VLAN 0 for client (community). Choose Switching > VLAN > Advanced > VLAN Configuration. Enter each VLAN ID, its name, and click ADD to add the VLAN to the configuration. Page

. Choose Security > Traffic Control > Private VLAN > Private VLAN Type Configuration. Assign the appropriate VLAN type to each VLAN ID. Click APPLY after each entry. By default, unconfigured VLANs are community VLANs. Page

. Choose Security > Traffic Control > Private Vlan > Private Vlan Association Configuration. Set VLAN 0 as the primary VLAN and - as the secondary VLANs. Click APPLY. Page

. Choose Switching > Multicast > IGMP Snooping > IGMP Vlan Configuration. Enable Admin Mode and Fast-Leave Admin Mode on VLAN 0, and click ADD. Page

. Choose Switching > Multicast > IGMP Snooping > Configuration. Enable Admin Mode to enable IGMP snooping globally and verify that VLAN 0 is listed as under VLAN IDs Enabled for IGMP Snooping. Click APPLY. Page

. Choose Switching > Multicast > IGMP Snooping > Querier VLAN Configuration. Set the querier address of... for VLAN 0, and click ADD. Page

. Choose Switching > MVR > Advanced > MVR Configuration. Enable MVR Running and set VLAN 0 as MVR Multicast VLAN. Click APPLY.. Choose Switching > MVR > Advanced > MVR Group Configuration. Enter the group IP addresses (multicast addresses)......, and click ADD. Page

. Choose Switching > MVR > Advanced > MVR Interface Configuration. Configure source ports (all video servers ports) and receiver ports (all client ports) with immediate leave on non-camera switches. Also remember that downstream uplink ports must be set as receiver ports and upstream uplink ports must be set as source ports. Page 0

. To configure video server and camera ports, choose Security > Traffic Control > Private Vlan > Private Vlan Port Mode Configuration. Select corresponding camera ports and select Host from the Port Vlan Mode drop-down menu. Click APPLY to commit changes. Use the appropriate options for any video server ports, and click APPLY. Page

. To associate VLANs with camera ports, choose Security > Traffic Control > Private Vlan > Private Vlan Host Interface Configuration. Select the camera interfaces and set Host Primary VLAN to 0 and Host Secondary VLAN to. Click APPLY. Page

. To associate VLANs with video server ports, choose Security > Traffic Control > Private Vlan > Private Vlan Promiscuous Interface Configuration. Select the video server interfaces and set Promiscuous Primary VLAN to 0 and Promiscuous Secondary VLAN to. Click APPLY. Page

. Choose Switching > VLAN > Advanced > VLAN Membership. Select the VLAN ID to configure from the dropdown menu. Because all camera and video server ports are configured, it is necessary only to configure client ports and uplink ports. Expand the port list for each unit displayed. Select T (tagged) for VLANs 0,, and 0 on uplink ports. Select U (untagged) for VLAN 0 on client ports. For added security, you can select Remove All for Group Operation for the default VLAN to help prevent unwanted traffic if the default VLAN is not also your management Vlan. Page

. For client ports, choose Switching > VLAN > Advanced > Port PVID Configuration. Select the client ports and enter VLAN 0 as Configured PVID. Click APPLY. Page

. To give clients access to MVR streams, choose Switching > MVR > MVR Group Membership. For each group IP address, select the ports to allow to subscribe to the stream. Click APPLY after selecting ports for each IP address. Page

Configuration for the 00-Camera Solution You can use the CLI or Web GUI for configuration. The configuration involves the following switches: XSMS M00-G M00-G-POE+ Assumptions for the 00-Camera Solution Layer licenses have been installed on XSMS and M00-G-POE+ switches, as they are natively Layer switches. No additional license is needed for the M00-G switches because they are native Layer switches. An existing DHCP server will be used to dynamically assign IP addresses to cameras and clients. Video servers are configured to broadcast UDP multicast packets using...0/ addresses. Best practices are used to design and implement switch stacking and redundancy/failover. Global Configuration Notes Be sure to save your configuration using the write memory CLI command. Alternatively, choose Maintenance > Save Config in the GUI. Select the box, and click APPLY. Each router ID must be unique to each stack. For each M00-G-POE+ stack, the subnet and VLAN ID for the camera VLAN will be unique since Layer- spanning-tree protocol (STP) is not being used and will allow for easier network segmenting. While the OSPF area feature was set to a single area in this sample configuration, it is possible to create smaller network areas for access control granularity. Refer to the included documentation and support.netgear.com for more information. ACLs can be used to further limit network access, including multicast subnets. You can limit camera communication to only video servers, restrict multicast streams to certain users, or apply ACLs for other reason appropriate for your deployment. Refer to the included documentation and support.netgear.com for more information. Page

Sample Configuration Values The following values are used in the sample configuration: Switch XSMS Video VLAN: 0 Video VLAN subnet:...0/ Mulicast sources:...0/ Video server interfaces: /0/-/0/ Uplink port IP addresses for M00-G-POE+ stacks:.0.x. Uplink port IP addresses for M00-G stacks:.0.x. Switch M00-G Client VLAN: 0 Client VLAN subnet:...0/ Client interfaces: /0/-/0/ Uplink port IP addresses for XSMS stack:.0.x. Multicast source:...0/ Switch M00-G-POE+ Camera VLAN: Camera VLAN subnet:...0/ Camera interfaces: /0/-/0/ Uplink port IP addresses for XSMS stack:.0.x. Page

CLI Configuration Steps: 00-Camera Solution These steps provide an example CLI configuration for the 00-camera solution. For the Web GUI configuration, see Web GUI Configuration Steps: 00-Camera Solution on page. Switch XSMS. Configure the OSPF interface on the switch, Assign a unique router ID for the distributed networks to recognize this switch and elect to distribute any connected networks to the neighboring switches. (XSMS) (Config)#router ospf (XSMS) (Config-router)#router-id 0.0.0. (XSMS) (Config-router)#redistribute connected (XSMS) (Config-router)#exit. Configure multicast settings. Start by enabling multicast routing, IGMP, and PIM sparse mode globally. (XSMS) (Config)#ip igmp (XSMS) (Config)#ip multicast (XSMS) (Config)#ip pim sparse (XSMS) (Config)#exit. Configure video VLAN 0 with subnet...0/ and enable routing on it. Make sure to enable PIM and IGMP on the interface and configure the correct OSPF area. (XSMS) #vlan database (XSMS) (Vlan)#vlan 0 (XSMS) (Vlan)#vlan routing 0 (XSMS) (Vlan)#exit (XSMS) #configure (XSMS) (Config)#interface vlan 0 (XSMS) (Interface-vlan 0)#routing (XSMS) (Interface-vlan 0)#ip address......0 (XSMS) (Interface-vlan 0)#ip pim (XSMS) (Interface-vlan 0)#ip igmp (XSMS) (Interface-vlan 0)#ip ospf area 0.0.0.0 (XSMS) (Interface-vlan 0)#exit. Configure VLAN 0 to be the default interface for multicast sources (...0/). (XSMS) (Config)#ip pim rp-candidate interface vlan 0...0...0 (XSMS) (Config)#ip pim bsr-candidate interface vlan 0 0 Page

. Configure the video server ports and place them on VLAN 0. Use the port range function (interface /0/- /0/) to configure a series of ports. Make sure to enable PIM and IGMP on the interfaces. (XSMS) (Config)#interface /0/ (XSMS) (Interface /0/)#vlan participation exclude (XSMS) (Interface /0/)#vlan participation include 0 (XSMS) (Interface /0/)#vlan pvid 0 (XSMS) (Interface /0/)#ip pim (XSMS) (Interface /0/)#ip igmp (XSMS) (Interface /0/)#ip ospf area 0.0.0.0 (XSMS) (Interface /0/)#exit. Configure the uplink ports to the M00-G-POE+ stacks using.0.x. addresses for the uplinks. For each uplink, increment the third segment of the IP address accordingly. For example, the first uplink has an IP address of.0.., the second uplink has an IP address of.0.., and so on. (XSMS) (Config)#interface /0/ (XSMS) (Interface /0/)#routing (XSMS) (Interface /0/)#ip address.0.....0 (XSMS) (Interface /0/)#ip igmp (XSMS) (Interface /0/)#ip pim (XSMS) (Interface /0/)#ip ospf area 0.0.0.0 (XSMS) (Interface /0/)#exit. Configure the uplink ports to the M00-G stacks using.0.x. addresses. For each uplink, increment the third segment of the IP address accordingly. For example, the first uplink has an IP address of.0.., the second uplink has an IP address of.0.., and so on. (XSMS) (Config)#interface /0/ (XSMS) (Interface /0/)#routing (XSMS) (Interface /0/)#ip address.0.....0 (XSMS) (Interface /0/)#ip igmp (XSMS) (Interface /0/)#ip pim (XSMS) (Interface /0/)#ip ospf area 0.0.0.0 (XSMS) (Interface /0/)#exit Page 0

Switch M00-G. Configure the OSPF interface on the switch. Assign a unique router ID for the distributed networks to recognize this switch and elect to distribute any connected networks to the neighboring switches. (M00-G) (Config)#router ospf (M00-G) (Config-router)#router-id 0.0.0. (M00-G) (Config-router)#redistribute connected (M00-G) (Config-router)#exit. enable multicast routing, IGMP, and PIM sparse mode globally. (M00-G) (Config)#ip igmp (M00-G) (Config)#ip multicast (M00-G) (Config)#ip pim sparse (M00-G) (Config)#exit. Configure client VLAN 0 with subnet...0/. Enable PIM on the interface and configure the correct OSPF area. (M00-G) #vlan database (M00-G) (Vlan)#vlan 0 (M00-G) (Vlan)#vlan routing 0 (M00-G) (Vlan)#exit (M00-G) #configure (M00-G) (Config)#interface vlan 0 (M00-G) (Interface-vlan 0)#routing (M00-G) (Interface-vlan 0)#ip address......0 (M00-G) (Interface-vlan 0)#ip pim (M00-G) (Interface-vlan 0)#ip igmp (M00-G) (Interface-vlan 0)#ip ospf area 0.0.0.0 (M00-G) (Interface-vlan 0)#exit. Configure client ports and place them on VLAN 0. Use the port range function (interface /0/-/0/) to configure a series of ports. Make sure to enable PIM and IGMP on the ports. (M00-G) (Config)#interface /0/ (M00-G) (Interface /0/)#vlan participation exclude (M00-G) (Interface /0/)#vlan participation include 0 (M00-G) (Interface /0/)#vlan pvid 0 (M00-G) (Interface /0/)#ip pim (M00-G) (Interface /0/)#ip igmp (M00-G) (Interface /0/)#ip ospf area 0.0.0.0 (M00-G) (Interface /0/)#exit Page

. Configure the uplink port to XSMS stack using.0.x. addresses for the uplinks (the next available address in the subnet that was configured on the XSMS side of the link). For each uplink, increment the third segment of the IP address accordingly. For example, the first uplink has an IP address of.0.., the second uplink has an IP address of.0.., and so on. (M00-G) (Config)#interface /0/ (M00-G) (Interface /0/)#routing (M00-G) (Interface /0/)#ip address.0.....0 (M00-G) (Interface /0/)#ip igmp (M00-G) (Interface /0/)#ip pim (M00-G) (Interface /0/)#ip ospf area 0.0.0.0 (M00-G) (Interface /0/)#exit. Configure uplink port to be the default interface for multicast sources (...0/). (M00-G) (Config)#ip pim rp-candidate interface /0/...0...0 Switch M00-G-POE+. Configure the OSPF interface on the switch. Assign a unique router ID for the distributed networks to recognize this switch and elect to distribute any connected networks to the neighboring switches. (M00-G-POE) (Config)#router ospf (M00-G-POE) (Config-router)#router-id 0.0.0. (M00-G-POE) (Config-router)#redistribute connected (M00-G-POE) (Config-router)#exit. Configure camera VLAN with subnet...0/ and enable routing on its interface. Make sure to configure the correct OSPF area. Remember that the camera VLAN ID and subnet are unique to each M00-G-POE+ stack. (M00-G-POE) #vlan database (M00-G-POE) (Vlan)#vlan (M00-G-POE) (Vlan)#vlan routing (M00-G-POE) (Vlan)#exit (M00-G-POE) #configure (M00-G-POE) (Config)#interface vlan (M00-G-POE) (Interface-vlan )#routing (M00-G-POE) (Interface-vlan )#ip address...0...0 (M00-G-POE) (Interface-vlan )#ip ospf area 0.0.0.0 (M00-G-POE) (Interface-vlan )#exit Page

. Configure camera ports and place them on VLAN. Use the port range function (interface /0/-/0/) to configure a series of ports. (M00-G-POE) (Config)#interface /0/ (M00-G-POE) (Interface /0/)#vlan participation exclude (M00-G-POE) (Interface /0/)#vlan participation include (M00-G-POE) (Interface /0/)#vlan pvid (M00-G-POE) (Interface /0/)#ip ospf area 0.0.0.0 (M00-G-POE) (Interface /0/)#exit. Configure the uplink port to the XSMS stack using.0.x. addresses for the uplinks (the next available address in the subnet that was configured on the XSMS side of link). For each uplink, increment the third segment of the IP address accordingly. For example, the first uplink has an IP address of.0.., the second uplink has an IP address of.0.., and so on. (M00-G-POE) (Config)#interface /0/ (M00-G-POE) (Interface /0/)#routing (M00-G-POE) (Interface /0/)#ip address.0.....0 (M00-G-POE) (Interface /0/)#ip ospf area 0.0.0.0 (M00-G-POE) (Interface /0/)#exit Page

Web GUI Configuration Steps: 00-Camera Solution These steps provide an example CLI configuration for the 00-camera solution. For the Web GUI configuration, see CLI Configuration Steps: 00-Camera Solution on page. Switch XSMS. Choose Switching > VLAN > Advanced > VLAN Configuration. Specify 0 for the video server VLAN ID, its name, and click ADD to add the VLAN to the configuration. Page

. Choose Switching > VLAN > Advanced > Vlan Membership. Select Vlan 0 from the VLAN ID drop-down menu. For all ports that will have video servers connected to them, untag the VLAN on the port by clicking associated box, and cycle through options until you get to U. Click APPLY after all ports have been configured on the VLAN. Page

. Choose Switching > VLAN > Advanced > Port PVID Configuration. For all the ports configured for video servers, select the associated box and enter 0 for the Configured PVID. When finished, click APPLY. Page

. Configure the VLAN 0 interface for the subnet (...0/) and enable VLAN routing. Choose Routing > VLAN > VLAN Routing. Select the VLAN ID and assign IP address... with subnet mask...0. Click ADD. Page

. Choose Routing > IP > Basic > IP Configuration. Enable Routing Mode and click APPLY.. Choose Routing > IP > Advanced > IP Interface Configuration. Assign the IP address for each interface that will act as an uplink to each M00-G and M00-G-POE+ stack. For each M00-G uplink, use consecutive.0.x./ subnets. For each M00-G-POE+ uplink, use consecutive.0.x./ subnets. For each interface, set IP Address Configuration Method to Manual and enter the IP address and subnet mask. Enable Routing Mode and Admin Mode. Click APPLY after configuring each interface. Page

. Choose Routing > Multicast > Global Configuration. Enable Admin Mode and click APPLY.. Choose Routing > Multicast > IGMP > Global Configuration. Enable Admin Mode and click APPLY. Page

. Choose Routing > Multicast > IGMP > Routing Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Click APPLY. Page 0

. Choose Routing > Multicast > PIM > Global Configuration. Set PIM Protocol Type to PIM-SM for sparse mode and enable Admin Mode. Click APPLY. Page

. Choose Routing > Multicast > PIM > Candidate RP Configuration. Select VLAN 0 as the PIM interface and assign...0/ as the group address/mask. Adjust the multicast address range as needed. Click ADD. Page

. Choose Routing > Multicast > PIM > BSR Candidate Configuration. Select VLAN 0 as the interface, and set Hash Mask Length to 0 and Priority to. Click APPLY. Page

. Choose Routing > Multicast > PIM > Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Click APPLY. Page

. Choose Routing > OSPF > Basic > OSPF Configuration. Select Enable and set the router ID to 0.0.0.. Click APPLY. Remember that the router ID must be unique to each stack in your LAN network. Page

. Choose Routing > OSPF > Advanced > Route Redistribution. Select Connected and enable Redistribution Option. Click APPLY. Page

. Choose Routing > OSPF > Advanced > Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Enable Admin Mode and click APPLY. Page

Switch M00-G. Choose Switching > VLAN > Basic > VLAN Configuration. Specify 0 for the VLAN ID and click ADD to add the VLAN to the configuration. Page

. Choose Switching > VLAN > Advanced > Vlan Membership. Select Vlan 0 from the VLAN ID drop-down menu. For all ports that will have clients connected to them, untag the VLAN on the port by clicking associated box, and cycle through options until you get to U. Click APPLY after all ports have been configured on the VLAN. Page

. Choose Switching > VLAN > Advanced > Port PVID Configuration. For all the ports configured for clients, select the associated box and enter 0 for the Configured PVID. When finished, click APPLY. Page 0

. Configure the VLAN 0 interface for the subnet (...0/) and enable VLAN routing. Choose Routing > VLAN > VLAN Routing. Select the VLAN ID and assign IP address... with subnet mask...0. Click ADD. Page

. Choose Routing > IP > Basic > IP Configuration. Enable Routing Mode and click APPLY.. Choose Routing > IP > Advanced > IP Interface Configuration. Assign the IP address for each interface that will act as an uplink to the XSMS stack. For each uplink, use consecutive.0.x./ subnets. For each interface, set the IP address configuration method to Manual and enter the IP address and subnet mask. Enable Routing Mode and Admin Mode. Click APPLY after configuring each interface. Page

. Choose Routing > Multicast > Global Configuration. Enable Admin mode and click APPLY.. Choose Routing > Multicast > IGMP > Global Configuration. Enable Admin Mode, and click APPLY. Page

. Choose Routing > Multicast > IGMP > Routing Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Enable Admin Mode and click APPLY. Page

. Choose Routing > Multicast > PIM > Global Configuration. Set the PIM protocol type to PIM-SM for sparse mode and enable Admin Mode. Click APPLY. Page

. Choose Routing > Multicast > PIM > Candidate RP Configuration. Select the uplink interface to the XSMS stack as the PIM interface and assign...0/ as the group address/mask. Adjust the multicast address range as needed. Click ADD. Page

. Choose Routing > Multicast > PIM > Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Enable Admin Mode and click APPLY. Page

. Choose Routing > OSPF > Basic > OSPF Configuration. Select Enable and set the router ID to 0.0.0.. Click APPLY. Remember that the router ID must be unique to each stack in your LAN network. Page

. Choose Routing > OSPF > Advanced > Route Redistribution. Select Connected, and select Enable for Redistribution Option. Click APPLY. Page

. Choose Routing > OSPF > Advanced > Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Enable Admin Mode and click APPLY. Page 0

Switch M00-G-POE+. Choose Switching > VLAN > Basic > VLAN Configuration. Specify for the camera VLAN ID and click ADD to add the VLAN to the configuration. Remember that the camera VLAN ID is unique to each M00-G-POE+ stack. Page

. Choose Switching > VLAN > Advanced > Vlan Membership. Select Vlan from the VLAN ID drop-down menu. For all ports that will have cameras connected to them, untag the VLAN on the port by clicking associated box, and cycle through options until you get to U. Click APPLY after all ports have been configured on the VLAN. Remember that the camera VLAN subnet is unique to each M00-G-POE+ stack. Page

. Choose Switching > VLAN > Advanced > Port PVID Configuration. For all the ports configured for cameras, select the associated box and enter for the Configured PVID. Click APPLY. Page

. Configure the VLAN interface for the subnet (...0/) and enable VLAN routing. Choose Routing > VLAN > VLAN Routing. Select the VLAN ID and assign IP address... with subnet mask...0. Click ADD. Page

. Choose Routing > IP > Basic > IP Configuration. Select Enable for Routing Mode to enable IP routing globally, and click APPLY.. Choose Routing > IP > Advanced > IP Interface Configuration. Assign the IP address for each interface that will act as an uplink to the XSMS stack. For each uplink, use consecutive.0.x./ subnets. For each interface, set the IP address configuration method to Manual and enter the IP address and subnet mask. Enable Routing Mode and Admin Mode. Click APPLY after configuring each interface. Page

. Choose Routing > OSPF > Basic > OSPF Configuration. Select Enable and set the router ID to 0.0.0.. Click APPLY. Remember that the router ID must be unique to each stack in your LAN network Page

. Choose Routing > OSPF > Advanced > Route Redistribution. Select Connected and enable Redistribution Option. Click APPLY. Page

. Choose Routing > OSPF > Advanced > Interface Configuration. Click All above the column headings to list physical and VLAN interfaces. Select all entries by clicking the checkbox in the column header. Enable admin mode and click APPLY. NETGEAR and the NETGEAR logo are trademarks and/or registered trademarks of NETGEAR, Inc. and/or its subsidiaries in the United States and/or other countries. Other brand names mentioned herein are for identification purposes only and may be trademarks of their respective holder(s). Information is subject to change without notice. NETGEAR, Inc. All rights reserved. Page