The Color X 100G QSFP28 DWDM1 O-BAND Silicon Photonics integrates an advanced DSP chip for 4x25G NRZ to 100G PAM4 conversion and a monolithic silicon MZ modulation chip with a 150GHz O-BAND DWDM CWL laser. It offers low power consumption and high performance, with key advantages as follows:

• TDECQ per channel <2.4dB (better than protocol spec <3.4dB)
• Rx Sens(OMA) < -9dBm@2.4e-4 Pre-FEC 53GBd PAM4 (better than spec <-6.1dBm)
• Maximum power consumption <3.5W

FIBERSTAMP leverages silicon photonics with traditional technology to develop cost-effective, non-coherent DWDM solutions for 100G DCI networks, ensuring market leadership through innovation.

The 800G QSFP-DD CWDM8/LR8 enables 800GE transmission over two single-mode fibers (2km/10km), enhancing long-distance interconnects for telecom, data centers, and cloud computing. It reduces power consumption and system costs while offering flexible, high-performance solutions. 

Key features include:
Supports 2km/10km transmission over dual single-mode fibers
Duplex LC interface
CWDM8 (2km) with TEC-cooled CWDM EML laser and PIN detector
LWDM8 (10km) with TEC-cooled LWDM EML laser and PIN detector
Efficient reuse of miniature CWDM8 and LWDM8 optical devices
8x100G PAM4 electrical interface with a 5nm DSP chip

FIBERSTAMP leverages its deep R&D expertise in 8-channel TOSA/ROSA integration to deliver 200G QSFP-DD LR8 (8x25G NRZ), 400G QSFP-DD LR8 (8x50G PAM4), and Open 800G QSFP-DD CWDM8/LR8 solutions.

Lightwave + BTR Innovation Reviews honors top optical networking products and services, evaluated by industry experts from leading service providers, technology firms, analysts, and media. FIBERSTAMP’s double win highlights its leadership in driving the future of high-speed, high-capacity Optical Communication Networks.

The 100G QSFP28 DWDM1 O-BAND Silicon Photonics received a high score of 4.5/5, highlighting its originality, innovation, and customer impact. Meanwhile, the 800G QSFP-DD CWDM8/LR8 earned a 3.5/5, showcasing its efficiency in addressing next-generation connectivity needs.

The post FIBERSTAMP WINS TWO LIGHTWAVE INNOVATION AWARDS FOR 100G QSFP28 DWDM1 O-BAND AND 800G QSFP-DD CWDM8 LR8 first appeared on FIBERSTAMP.

200G/400G Networks for Low-latency, High-frequency Data Centers and Edge Data Centers

The 200G QSFP-DD SR8/PSM8 based on high-frequency trading data center interconnect technology has been widely adopted by numerous customers all around the world. With the goal of ensuring technological continuity, FIBERSTAMP has extended its offerings to include 200G QSFP-DD PSM8 and 400G QSFP-DD XPSM8 solutions, providing robust and efficient connectivity for next-generation data centers.

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We define edge data centers as facilities positioned at the periphery of future 5G or 6G core networks, designed to ensure real-time data responsiveness. These data centers demand ultra-low latency and high-performance solutions, which are perfectly addressed by FIBERSTAMP’s 200G QSFP-DD 2×CWDM4 and 400G QSFP-DD 2×FR4 optical modules.

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We understand that high-frequency trading data centers and edge data centers share similar requirements for rapid network response. Customers can flexibly choose the most suitable solutions to meet their specific needs.

AI&DC 1.6T R&D Plan Launched (Stay tuned!)

The challenge of widespread deployment of 1.6T lies in power consumption design. Various methods for reducing power consumption have been proposed in the industry. Our 1.6T product plan is based on:

• 1.6T OSFP-XD LPO/LRO plan
• 1.6T OSFP-XD PCC/ACC plan

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800G Product Upgrade Plan for Metro Data Center Interconnect

• 800G QSFP-DD FR8/LR8 (single-wavelength 100G)
• 800G QSFP-DD DR4/FR4/LR4 (single-wavelength 200G)

Complete Solution for Immersion Liquid Cooling Interconnect Data Centers

FIBERSTAMP is the company with the richest practical experience in this field. Our plan includes:

• Launching immersion liquid cooling optical extenders in all packaging formats
• Launching 800G/400G immersion liquid cooling optical modules based on silicon photonics technology platform
• Launching 800G/400G PCC/ACC immersion high-speed copper cables

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Innovation in Short-Distance Transmission Optical Modules for Metro DWDM Interconnect

• 100G QSFP28 PSM DWDM4 -C-BAND –48 wavelengths –80km
• 100G QSFP28 DWDM1 –O-BAND 150GHz –16 wavelengths –15km
• 100G QSFP28 DWDM1 -O-BAND 200GHz -16 wavelengths -30km
• 400G QSFP DD PSM DWDM4 –O-BAND 200GHz -6 wavelengths 10km (30km with external SOA)

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FIBERSTAMP continues to drive innovation at the forefront of optical module technology, particularly in the fields of low-latency high-frequency trading, edge computing, and data center interconnect. As the demand for AI computing power rises, FIBERSTAMP’s technological advancements bring more efficient and flexible differentiated solutions to the industry, driving the evolution of global network architecture. In the future, FIBERSTAMP will continue to provide customers with high-quality, innovative products, further promoting the efficient development of global optical networks.

The post 2025 Optical Transceivers Innovation Plan & Insights on Evolving Network Architectures! –FIBERSTAMP first appeared on FIBERSTAMP.

We believe that not all networks are based on common infrastructure purposes. The diversification of network purposes is the ecological foundation for network diversification. Precisely because of this diversification, we cannot blindly accept the theory that networks based on a 100G PAM4 underlying architecture are infallible. Further refinements to this theory are inevitable.

Generally speaking, for applications like high-frequency trading and edge networks that require prompt responses, a more stable network underlayer is necessary. This underlayer does not necessarily rely on 100G PAM4 technology, as the stability of such networks is best achieved on the signal foundation of NRZ and 50G PAM4. If our goal is to achieve higher signal sensitivity and eliminate noise interference, NRZ and 50G PAM4 serve as the optimal bases for network practices. NRZ has an advantage over PAM4 primarily in signal-to-noise ratio (SNR), which is the foundation for eliminating DSP. As we all know, DSP introduces power consumption and significant network latency. Although both 50G PAM4 and 100G PAM4 belong to the PAM4 technology paradigm, their impacts on networks are strikingly different, with vastly different system SNR and power consumption implications. Technologies similar to LPO, which are currently trusted, can indeed form the basis for the next-generation network architecture akin to 50G PAM4. Attempts at this network have actually given us glimpses of the facts.

For high-frequency trading and edge networks, FIBERSTAMP offers two evolutionary blueprints for technological practices. One is a network built on 400G QSFP-DD PSM8 optical transceivers, and the other is a network built on 400G QSFP-DD 2×FR4. These two networks can fulfill the purposes of high-frequency trading centers and edge networks, and they possess long-term effectiveness. If people must evolve towards 800G, we can still form a network architecture based on 16×50G PAM4. However, we also believe that both 50G PAM4 and 100G PAM4-based linear LPO and CPO technologies are goals for this network. The main dividing point remains: you must create a sufficiently stable, low-latency, and reliable foundation for this network. There is no need to pursue industry hotspots at the expense of blurring the practical functions of the network.

It is now believed that NV provides the most advanced network hardware for data center computing power, such as pluggable networks based on 200G SERDES/1.6T. However, this network faces challenges such as thermal power consumption and signal integrity. The industry has various technical concepts for improving this network, which are currently being tested and deployed. However, technologies like 3nm DSP, LPO, LRO, or immersion liquid cooling all require a certain amount of time for trial and error. Therefore, generally speaking, CPO may be a better solution. However, the premature definition of CPO makes this vision difficult to achieve in the short term. It is evident that NPO technology is the best practical blueprint for CPO implementation. Personally, I believe that data centers for computing power can continue to innovate along the path of 100G PAM4 without getting caught up in extending or evolving single-channel baud rates to 200G or 400G. Increasing baud rates reduces the system’s SNR and thermoelectric stability. I believe there are limits to deploying higher baud rate networks, and this model can be scientifically refuted, requiring reconsideration. Mainly, people must dispel the misconception that higher baud rates equate to technological advancement.

FIBERSTAMP has a rich product line for AI&DC 800G computing power networks. We are currently establishing an innovative and differentiated product line for computing power networks starting from 800G and 1.6T. Products like FIBERSTAMP’s 800G CWDM8/LR8 will serve as a supplementary architecture for 800G networks. For 1.6T, GIGALIGHT will begin a new product line layout and will release it by Q4 2025 at the latest.

The stagnation in 100G PAM4 technology research and development has led to difficulties in the innovation and evolution of metropolitan telecommunication networks. It is hard to believe that vast telecommunication networks in different locations can be built on the current underlying foundation of 100G PAM4 Ethernet. Future telecommunication networks must be based on three assumptions: first, building an infrastructure based on space wavelength division optics and a 50G network underlayer; second, developing a new technological platform for the next generation of 100G PAM4 DSP that is suitable for telecommunication networks; and third, establishing the next generation of high-speed networks entirely on the descent of various wavelength coherent technologies. These network architectures are not mutually exclusive, and each network can accommodate these three technologies. The main argument is that at different network nodes, corresponding technologies based on correct understanding are needed. However, this “correct understanding” must be based on the talent, preferences, and understanding of network rights of the network architects.

Based on the above understanding, FIBERSTAMP will build the next generation of telecommunication network products within its own technological cognition. Indeed, this is a historical period dominated by computing power networks. However, people should not forget that it is the innovation in telecommunication networks that brings about the foundation for economic and industrial inclusiveness.

As for the most popular data center networks currently, since their concept is entirely focused on the general purpose of “data storage and retrieval,” this purpose is primarily based on simplicity and low cost. Therefore, their evolution is mainly driven by the interest in technological discoveries, the advanced deployment goals of the company’s future business, and assessments of its own economic strength and capabilities. Since the increase in general network baud rates cannot bring any additional benefits, we previously believed that 200G networks represented the optimal balance between cost and technology, and we still believe this today. Investments in 400G, 800G, and 1.6T general networks are mainly aimed at establishing a hierarchical structure within the network. If not driven by the demand for a hierarchical structure, the deployment of higher baud rate networks is solely motivated by the advancement of silicon photonics technology.

In the field of general data center architectures, FIBERSTAMP has a comprehensive product line of silicon photonics, as well as a rich product line based on copper cable interconnection, VCSEL-based AOC, and EML technology. Due to the solidification of architectures, these products mainly compete on cost in the industry.

The post The Basic Dialogue Between Fiberstamp And Network Architecture first appeared on FIBERSTAMP.

25G SFP28 ZR 80km

• Both TOSA (Transmitter Optical Sub-Assembly) and ROSA (Receiver Optical Sub-Assembly) utilize hermetically sealed packaging for stability and reliability, meeting telecom-grade application requirements.
• The TOSA employs an EML (Electro-Absorption Modulated Laser) 1310nm laser with TEC (Thermo-Electric Cooler) cooling.
• The ROSA integrates a PIN photodiode and SOA (Semiconductor Optical Amplifier) to provide a 30dB optical budget.
• Supports 80km dual-fiber single-mode transmission with host RS-FEC (Reed-Solomon Forward Error Correction) enabled.
• Product power consumption is less than 2.5W.

40G QSFP+ ZR4 80km

• Both TOSA and ROSA utilize hermetically sealed packaging for stability and reliability, meeting telecom-grade application requirements.
• The TOSA uses a 4-wavelength LAN-WDM DML (Directly Modulated Laser) with TEC cooling.
• The ROSA employs a high-sensitivity APD (Avalanche Photodiode) optical detector to provide a 28dB optical budget.
• Supports 80km dual-fiber single-mode transmission.
• Product power consumption is less than 4.5W.

100G QSFP28 BiDi ZR4 80km

• Both TOSA and ROSA utilize hermetically sealed packaging for stability and reliability, meeting telecom-grade application requirements.
• Designed with 8-wavelength LAN-WDM BIDI (Bidirectional) technology, used in pairs.
• The TOSA uses a 4-wavelength EML LAN-WDM laser with TEC cooling.
• The ROSA integrates a PIN photodiode and SOA to provide a 30dB optical budget.
• Supports 80km single-fiber single-mode transmission with host RS-FEC enabled.
• Built-in 4×25G CDR (Clock and Data Recovery).
• Product power consumption is less than 6.5W.

FIBERSTAMP has always been committed to providing high-performance, high-quality, and reliable optical communication solutions to global customers. The launch of the 25G SFP28 ZR, 40G QSFP+ ZR4, and 100G QSFP28 ZR4 BiDi optical transceivers will further enhance our market competitiveness in ultra-long-haul telecom-grade applications, providing even better optical transmission solutions for 5G communications, telecom and MAN applications.

The post FIBERSTAMP Launches Long-Haul Telecom-Grade Optical Transceivers first appeared on FIBERSTAMP.

Highlights Of FIBERSTAMP O–Band Transmission System

FIBERSTAMP O–Band System 100G Optical Transceiver

O-Band WDM Interconnection For Data Center Without SOA

• Large transmission capacity up to 16*100G in one fiber
• low cost because of only passive MUX/DEMUX devices and optical transceivers
• Easy deployment and about 10km transmission distance

O-Band WDM Interconnection For Data Center With SOA

• Large transmission capacity up to 16*100G in one fiber
• low cost because of only SOA and OLP components and optical transceivers
• Easy deployment and about 30km transmission distance
• Support 1+1 protection for fiber link
• Support remote NMS management

O-Band WDM solution for metro network

• Transmission capacity up to 16*100G in one fiber
• low cost ,no need additional transponders or DCM modules
• Transmission distance 30km, easy maintenance
• Support 1+1 protection for fiber link
• Support remote NMS management

The post Advantages of FIBERSTAMP O-Band DWDM Solutions first appeared on FIBERSTAMP.

At Network X 2024 in Paris, France, FIBERSTAMP presented our 100G SFP112 products, which features a compact design that effectively simplifies the choice of dual – and four-wavelength optical transmission, reducing space footprint, power consumption and overall cost.

The 100G SFP112 series uses an advanced 7nm CMOS DSP design, adopts 53G Baud EML laser or VCSEL laser, and supports 100G single-channel transmission based on PAM4 modulation technology. Compliant with the IEEE 802.3ck SR1/LR1/ER1 Lite single-mode fiber transmission specification and the 100G Lambda MSA standard, 100G SFP112 ER1 is also equipped with a highly sensitive APD photodiode that supports transmission up to 30 km.

As the industry’s leading and smallest package 100G SFP112 optical transceiver, the product is widely considered to be the next generation of 100G pluggable optical transceiver, similar to the 10G SFP+ module path. With a simplified structure and fewer components, the 100G SFP112 is suitable for mass production and forward compatibility, making it ideal for high-density routers and switches, while providing an ideal upgrade for the next generation of 100G optical networks.

100G SFP112 SR1

• COB package 100G PAM4 850nm VCESL and PIN
• Up to 100m on MMF OM4/OM5 with the HOST FEC
• Dual LC/APC
• SFP112 MSA
• Supports the CMIS 4.0 protocol
• Built-in low power DSP
• The power consumption of the product is less than 2.1W at 70℃

100G SFP112 LR1 Lite

• Power consumption is less than 3.5W at 70℃
• Airtight package 100G PAM4 1310 EML and PIN
• Up to 10Km on SMF with the HOST FEC
• Dual LC/UPC
• SFP112 MSA
• Supports the CMIS 4.0 protocol
• Built-in low power DSP

100G SFP112 ER1 Lite

• Airtight package 100G PAM4 1310 EML and APD
• Up to 30Km on SMF with the HOST FEC
• Dual LC/UPC
• SFP112 MSA
• Supports the CMIS 4.0 protocol
• Built-in low power DSP
• Power consumption is less than 3.5W at 70℃

The post FIBERSTAMP introduces the single-wave 100G SFP112 SR1/LR1/ER1 optical transceivers first appeared on FIBERSTAMP.

During the SC24 exhibition, Fiberstamp will present the the following optical products solutions for AI Data Center and super computing networking.

400G/800G Silicon Photonics Transceivers

• 800G QSFP-DD DR8/DR8+
• 800G QSFP-DD 2XFR4/2X LR4
• 800G OSFP DR8/DR8+
• 800G OSFP 2XFR4/2X LR4
• 400G QSFP-DD DR4/FR4/LR4
• 400G QSFP112 DR4/FR4/LR4
• 400G OSFP-RHS DR4/FR4/LR4

Immersible Liquid Cooling Interconnect Solutions

• Immersible 800G OSFP SR8 with MPO pigtail
• Immersible 800G OSFP AOC
• Immersible 800G OSFP DAC
• Immersible 400G OSFP-RHS/QSFP112 SR4 with MPO pigtail
• Immersible 400G OSFP-RHS/QSFP112 AOC
• Immersible 400G OSFP-RHS/QSFP112 DAC

High-Speed Interconnect Cables

• 800G OSFP/QSFP-DD AOC
• 400G QSFP112/OSFP-RHS AOC
• 800G OSFP/QSFP-DD, DAC up to 3meters and ACC up to 5meters
• 400G QSFP112/OSFP-RHS, DAC up to 3meters and ACC up to 5meters

The post FIBERSTAMP will exhibit AI 800G high-speed AOC and DAC interconnect I/O assembly and immersible liquid cooling interconnect at SC24! first appeared on FIBERSTAMP.

Fiberstamp will DEMO the following product lines at the show:

• 400G 1U 6.4T DCI BOX Coherent Subsystem
• 100G Non-Coherent CWDM&DWDM System

400G 1U 6.4T DCI BOX Coherent Subsystem

400G 1U 6.4T Coherent DCI BOX can use 400G QSFP-DD ZR+ and 400G CFP2 DCO coherent optical modules, with the newly developed 4x 400G QSFP-DD OEO service card, 1U single frame can support a maximum 6.4T broadband capacity. It is mainly used for the interconnection of data center rooms of operators and Internet companies, and can also be applied to the aggregation layer and access layer of long-distance networks of various transmission applications LAN/MAN. In addition, we also have 2U DCI BOX available. A single enclosure can support a maximum of 12.8T broadband capacity, and a cascade of multiple enclosures can achieve 38.4T.

The newly developed 400G QSFP-DD OEO card supports four 400G signal wavelength conversion and regeneration trunks. A single board supports a maximum of eight 400G QSFP-DD optical module

400G QSFP-DD OEO Card

Functional characteristics	Description
Client side optical module	400G QSFP-DD FR4/DR4/SR8
Line side optical module	400G QSFP-DD ZR+/ZR
Line side modulation format	400G PM-16QAM
	200G PM-QPSK
	200G PM-16QAM
Signal spectrum width of	400G PM-16QAM:75GHz
wave division side	200G PM-QPSK:75GHz
	200G PM-16QAM:50GHz
Time delay	＜20us

The Coherent DCI BOX series at the live DEMO will feature the latest 400G CFP2 DCO and 400G QSFP-DD ZR+ coherent optical module series. The 400G QSFP-DD ZR+ coherent optical transceivers, DWDM single wave 400G, Tx optical power support 0~-6dbm adjustable, support flexible grid and open ZR+ protocol, use OFEC, The Rx OSNR provides 24db/0.1nm@400G 16QAM and 300km to 400km service interconnections. The typical power consumption is less than 22W.

In addition, the upcoming 100G QSFP28 DCO coherent optical transceivers, single-wave 100G DP-QPSK modulation mode, Tx optical power support -3~-10dbm adjustable, DWDM Full C-band tunable, 50GHz/100GHz grid, 100GE/OTU4, 120km service interconnection, typical power consumption is less than 8W.

100G NON-Coherent CWDM&DWDM system

Non-coherent DWDM subsystem, operating on the O-E-O principle, excel in signal conversion, relay amplification, and more within the 25.5-28.1Gbps range. It could work our new Color ZR 100G QSFP28 PSM4 DWDM and Color X 100G QSFP28 DWDM1 optical transceivers. Ideal for the 25G/100G optical domains, they offer extensive rate access, versatile service capabilities, and support 3R function. Through their compact design and seamless integration, these devices offer network operators adaptable, user-friendly, and high-performance solutions.

• Support 1U/2U/4U chassis for different applications
• NON-Coherent system’s capacity C-band 96x25G=2.4T or O-band 16x100G=1.6T
• Full services access like P/SDH、FC、Ethernet、ATM etc.
• Modular design and Hot swapping for all cards like NMU, FAN, service cards etc.
• Easy Expansion Service card can be mixed interpolation
• Optional AC/DC power supply with 1+1 backup
• HD dual color LCD display screen and easy operation keys on panel

FIBERSTAMP will also DEMO silicon 800G OSFP DR8/2xFR4 for AI computing and commercial 50G SFP56 DWDM for 5G Front-haul, which can show our ability to provide the full optical transceivers solutions for AI computing and telecom 5G front-haul area.

For more information, our team will be on-site for you to carry out a detailed introduction. Look forward to seeing you at Nextwork X, on October 8-10, at booth#B10!

The post FIBERSTAMP Will Present 400G DCI BOX, Coherent and Metro Telecom Optical Transceivers At Network X! first appeared on FIBERSTAMP.

In order to catch up with the high demand of AI computing data center for high energy efficiency and heat dissipation, Fiberstamp has improved our immersible liquid cooling optical transceiver with  higher reliability and cost–performance. They use direct immersible liquid cooling technology and optimized optical device sealing design to effectively prevent coolant from entering the optical path,and thereby eliminating the negative impact of liquids on the optical route.

Fiberstamp’s immersible liquid cooling interconnect optics are mainly built on a unique technology and superior signal integrity. It is designed by integrating material compatibility, mechanics, optics, pressurization, SI simulation and comprehensive tests. The optimized sealing design of optical components and engines ensures that all products undergo rigorous 100% immersion testing before leaving the factory to verify their suitability and durability in both spray-type and fully immersible liquid cooling environments.

Currently, our immersible liquid cooling products have been successfully deployed in a variety of cooling liquids, including 3M and domestic fluoridated liquids, silicone oil, and PAO, proving their broad applicability and outstanding compatibility. Till now, Fiberstamp has become one of the world’s pioneer in the field of liquid cooling interconnection. Nowadays, we have the following detailed immersible liquid cooling optical transceivers available.

Immersible Liquid Cooling Optical Transceivers (with MPO Pigtail) for Data Center and 5G Fronthaul

• 25G SFP28 SR 850nm
• 25G SFP28 LR 1310nm
• 100G QSFP28 SR4 850nm
• 100G QSFP28 PSM4 1310nm
• 200G QSFP56 SR4 850nm
• 200G QSFP56 DR4 1310nm
• Immersible Liquid Cooling AOC of above items

Immersible Liquid Cooling Optical Transceivers (with MPO Pigtail) for AI Computing Data center

• 400G QSFP112 SR4 850nm 100m
• 400G OSFP-RHS SR4 850nm 100m
• 800G OSFP finned-top SR8 850nm 100m
• 800G QSFP-DD SR8 850nm 100m

The post FIBERSTAMP Upgrades The Immersion Interconnect Solutions To Improve Energy Efficiency For “Green AI” Data Center first appeared on FIBERSTAMP.

Fiber Connect, sponsored by the Optical Fiber to the Home Committee of USA, is the most professional optical communication interconnection industry seminar & exhibition in USA, and is recognized by the industry as the most important exhibition and conference exchange platform for optical communication access networks in USA. During the exhibition, we will show you the DWDM DCI BOX optical network solutions for urban IDC interconnect, including Non-coherent DWDM subsystem and coherent DWDM subsystem, as well as non-coherent DWDM optical transceivers and coherent optical transceivers that can be widely used in such solutions.

Fiberstamp will DEMO the 400G DCI/1U 6.4T Coherent DCI BOX transmission device at the show. The system can use 400G QSFP-DD ZR+ and 400G CFP2 DCO coherent optical modules, with the newly developed 4x 400G QSFP-DD OEO service card, 1U single frame can support a maximum 6.4T broadband capacity. It is mainly used for the interconnection of data center rooms of operators and Internet companies, and can also be applied to the aggregation layer and access layer of long-distance networks of various transmission applications LAN/MAN.

The newly developed 400G QSFP-DD OEO card supports four 400G signal wavelength conversion and regeneration trunks. A single board supports a maximum of eight 400G QSFP-DD optical modules.

Functional characteristics	Description
Client side optical module	400G QSFP-DD FR4/DR4/SR8
Line side optical module	400G QSFP-DD ZR+/ZR
Line side modulation format	400G PM-16QAM
	200G PM-QPSK
	200G PM-16QAM
Signal spectrum width of wave division side	400G PM-16QAM:75GHz
	200G PM-QPSK:75GHz
	200G PM-16QAM:50GHz
Time delay	＜20us

In addition, we also have 2U DCI BOX available, which can support up to 12.8T broadband capacity.

• Unified 2U rack integrated Optical layer and electrical layer boards access
• Support 400G/200G/100G rates on line-side CFP2/QSFP-DD interfaces
• ROADM function supported up to 9 dimensions
• Maximum capacity of 6.4T single rack access
• Optical Layer Supports EDFA Cards, WSS Cards, OP Cards, etc.
• Enables shared or independent racks for optical and electrical devices, saving rack space and providing expansion flexibility.

Fiberstamp 400G QSFP-DD ZR+ coherent optical transceivers, DWDM single wave 400G, Tx optical power support 0~-6dbm adjustable, support flexible grid and openZR+ protocol, use OFEC, The Rx OSNR provides 24db/0.1nm@400G 16QAM and 300km to 400km service interconnections. The typical power consumption is less than 22W.

• Transmission distance up to 400km
• Advanced process 7nm DSP
• RX OSNR tolerance meets 24dB/0.1nm
• Operate at full C-band DWDM wavelengths at 75GHz (up to 64 channels) or 100GHz (up to 48 channels) channel spacing
• Triple-temperature power consumption < 22W

Fiberstamp 100G QSFP28 DCO coherent optical transceivers, single-wave 100G DP-QPSK modulation mode, Tx optical power support -3~-10dbm adjustable, DWDM Full C-band tunable, 50GHz/100GHz grid, 100GE/OTU4, 120km service interconnection, typical power consumption is less than 8W.

In addition, we will also exhibit a series of AI supercomputing data center interconnection products, including silicon optical 800G silicon optical modules and 800G/400G PCC/ACC and AOC short-range data center interconnection products. All AI supercomputing data center interconnect products are available in both OSFP and QSFP-DD packages.

For more product information, please visit booth #1090 and we will introduce more details to you!

The post FIBERSTAMP Will Present DWDM Optical Network Solutions At Fiber Connect 2024. first appeared on FIBERSTAMP.