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1×8 Evenly distributed rack type splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×32 Evenly distributed rack type splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×16 Evenly split plug-in splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×32 Evenly split plug-in splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×4 Evenly split plug-in splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1 × 2 Evenly split plug-in splitter
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×32 Fiber optical fast connector
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
1×16 Fiber optical fast connector
The optical splitter is a component of the EPON/GPON network. It is a passive device that connects the OLT and the ONU. Its function is to distribute the downstream data and centralize the upstream data. The optical splitter has one uplink optical interface and several downlink optical interfaces. The optical signals from the uplink optical interface are allocated to all downlink optical interfaces, and the optical signals from the downlink optical interface are allocated to the only uplink optical interface. When an optical signal is transferred from the uplink optical interface to the downlink optical interface, the optical power decreases. The same is true when the optical signal is transferred from the downlink optical interface to the uplink optical interface. The optical signal strength of each downlink optical interface can be the same or different. The optical splitter is centrally installed in the optical splitter box (indoor or outdoor type); When the ONU distribution is more dispersed or the number of fiber cores in the resident network is insufficient, the two-stage and multistage splitting methods can be used. The optical shunt ratio should be selected by considering the transmission distance of the EPON system, the number of users on the ONU band, and the bandwidth allocation in the PON system. In general, when FTTH mode and FTTB+LAN mode are used, the optical shunt ratio should be designed according to 1x32.
HiOSO Technology Co., Ltd
4/F, Building 10, Nangang Second Industrial Zone, 1026 Songbai Road, Xili Street, Nanshan District, Shenzhen
0755-83151488
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