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Eoptolink Technology Inc., Ltd (SZSE: 300502) has further strengthened its 100Gbps QSFP28 family with the unveiling of its new 100Gbps QSFP28 transceiver modelsfor applications up to 40km. The ER4 Lite supports 100GE without FEC and OTU4 with FEC. The 4WDM-40 supports 100GE with KR4 FEC. transceiver modelsfor applications up to 40km. The ER4 Lite supports 100GE without FEC and OTU4 with FEC. The 4WDM-40 supports 100GE with KR4 FEC. The family consists of:
• EOLQ-161HG-40-L7 : 100G QSFP4WDM-40 40km transceiver, 0 to 70°C
• EOLQ-161HG-30-LA : 100G QSFP ER4Lite 30km transceiver, 0 to 70°C
 
“We are proud to add 30km & 40km capability to our QSFP28 family”, said James Zhang, Eoptolinks Director of Business Development. He adds, “The QSFP28 ER4 Lite supports 100GE and OTU4 applications, while the QSFP28 4WDM-40 variant supports 100GE with KR4 FEC. The addition of these transceivers will provide our customers with much needed choice for longer distance connectivity of their 100G traffic.”

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Eoptolink provides a whole series SMPTE SFP transceiver for Digital Video in 6Gbps and 12Gbps

EOPTOLINK (SZ: 300502) has released Digital Video SMPTE 6G and 12G transceiver series. Fiber Optic Transport of HD/SD-SDI It is becoming increasingly necessary and economically feasible to transport HD/SD-SDI signals over fiber instead of coaxial cable. The reasons are many including increased bandwidth, lower cabling cost, noise immunity and greater transmission distances.

Prior to 2006, several standards were used to define how SDI signals were to be transported over fiber. Now, there is one standard to define the many aspects and parameters of the fiber optic interface for the transmission and reception of SDI over fiber. SMPTE 297-2006: This standard defines the fiber optic interface for the transmission and reception of SDI signals at various data rates: 12G, 6G, SMPTE 259M: 143 through 360 Mbps SMPTE 344M: 540 Mbps SMPTE 292: 1.485 and 1.485/1.001 Gbps SMPTE 424M: 2.97 and 2.97/1.001 Gbps SMPTE 297-2006 defines many parameters of the optical interface for both a transmitting and receiving device with a fiber optic interface.

The input to a fiber Transmitter can be any one of the SMPTE coaxial-based standards indicated above. On the Receiver, the output will be of the same coaxial interface type of the Transmitter. The significance of the new 297 standard is that it allows for interoperability between fiber optic devices from different manufacturers that comply with the standard.

Stand 2K63, Hall 2, MWC2018, Barcelona, Spain – Ethernity Networks (AIM: ENET.L), a leading supplier of data processing technology on programmable logic for high-end carrier grade data processing offload, today demonstrated a scalable Carrier Ethernet aggregation Switch Router platform on a COTS server that utilizes OVS DPDK as a fabric between multiple ENET FPGA SmartNICs hosting multiple 10GE ports.

This unique implementation of the ENET Flow Processor offers cost-efficient Carrier Ethernet functionality in virtualised networks while maintaining the COTS nature of NFV environments. This overcomes the significant challenge that communications service providers (CSPs) face in achieving carrier-grade performance upon virtualisation of their network infrastructures. Ethernity’s solution provides SLA support, OAM, routing, multi-protocol interworking, and security that cannot be deployed efficiently with software-only implementations, while eliminating vendor lock-in.

Once Carrier Ethernet is integrated into the server with the ENET FPGA SmartNIC, the ENET Flow Processor can be used for VNF offloading, including vFW, vRouter, vBRAS, and vEPC, providing further gains in CPU efficiency and lower latency.

“Virtualisation of a network loses its value if the price of virtualisation is the loss of carrier-grade services,” said David Levi, CEO of Ethernity Networks. “At Ethernity, we resolve performance, security, and power consumption issues to provide the best of both telecom worlds – virtualised and traditional – with guaranteed quality of experience.”

Lod, Israel  – Ethernity Networks (AIM: ENET.L), a leading supplier of data processing technology on programmable logic for high-end Carrier Ethernet applications and data processing offload, announced today that its low cost FPGA-based telco edge cloud platform has been selected by Shenzhen TiCOMM, a Chinese SD-WAN solution provider.

The innovative platform will be used as a combined Network Interface Device (NID) and SD-WAN gateway solution. The system-on-chip (SoC), featuring both an array of powerful ARM CPUs and an FPGA in a single, low-cost programmable platform, will be equipped with 10G interfaces, Carrier Ethernet functions, IPSec, and ARM processors for SD-WAN software. The platform can be packaged as a standalone device or can be installed as a SmartNIC on any standard server. The solution supports 10G IPSec and 20G Carrier Ethernet switching and routing throughput.

The solution will be jointly showcased by Ethernity and TiCOMM at the Mobile World Congress in Barcelona between the 26th of February and the 1st of March 2018 at Hall 2 stand 2K63.

“Ethernity’s NIC-in-NID, powered by Ethernity’s ENET flow processing technology, is a natural match with TiCOMM’s SD-WAN solution architecture,” said Mr. Liu Yu, CEO of Shenzhen TiCOMM. “The performance and features fit the requirements of SD-WAN very well. Ethernity’s NIC-in-NID reduces the time-to-market of TiCOMM’s solution and improves our cost efficiency as well. It’s a very powerful solution enabler for TiCOMM.”

TiCOMM’s SD-WAN solution reduces WAN expenditures, improves the quality of interconnections, and extends coverage scope with a secure, simple, fast service. It provides a real-time view of the network, dynamic optimal path selection, and an intuitive OAM management interface. By using Ethernity’s FPGA- and ARM-based platform, TiCOMM will benefit from a low-cost, high-capacity, yet fully programmable solution compared to x86 servers, resulting in higher throughput and lower expenses. Nonetheless, the platform is still able to connect to external servers to access even greater computing resources through the embedded NIC function.