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optical networking standards

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In this ever-evolving landscape of optical networking, the development of coherent optical standards, such as 400G ZR and ZR+, represents a significant leap forward in addressing the insatiable demand for bandwidth, efficiency, and scalability in data centers and network infrastructure. This technical blog delves into the nuances of these standards, comparing their features, applications, and how they are shaping the future of high-capacity networking. ZR stands for “Ze Best Range” and ZR+ is reach “Ze Best Range plus”

Introduction to 400G ZR

The 400G ZR standard, defined by the Optical Internetworking Forum (OIF), is a pivotal development in the realm of optical networking, setting the stage for the next generation of data transmission over optical fiber’s. It is designed to facilitate the transfer of 400 Gigabit Ethernet over single-mode fiber across distances of up to 120 kilometers without the need for signal amplification or regeneration. This is achieved through the use of advanced modulation techniques like DP-16QAM and state-of-the-art forward error correction (FEC).

Key features of 400G ZR include:

  • High Capacity: Supports the transmission of 400 Gbps using a single wavelength.
  • Compact Form-Factor: Integrates into QSFP-DD and OSFP modules, aligning with industry standards for data center equipment.
  • Cost Efficiency: Reduces the need for external transponders and simplifies network architecture, lowering both CAPEX and OPEX.

Emergence of 400G ZR+

Building upon the foundation set by 400G ZR, the 400G ZR+ standard extends the capabilities of its predecessor by increasing the transmission reach and introducing flexibility in modulation schemes to cater to a broader range of network topologies and distances. The OpenZR+ MSA has been instrumental in this expansion, promoting interoperability and open standards in coherent optics.

Key enhancements in 400G ZR+ include:

  • Extended Reach: With advanced FEC and modulation, ZR+ can support links up to 2,000 km, making it suitable for longer metro, regional, and even long-haul deployments.
  • Versatile Modulation: Offers multiple configuration options (e.g., DP-16QAM, DP-8QAM, DP-QPSK), enabling operators to balance speed, reach, and optical performance.
  • Improved Power Efficiency: Despite its extended capabilities, ZR+ maintains a focus on energy efficiency, crucial for reducing the environmental impact of expanding network infrastructures.

ZR vs. ZR+: A Comparative Analysis

Feature. 400G ZR 400G ZR+
Reach Up to 120 km Up to 2,000 km
Modulation DP-16QAM DP-16QAM, DP-8QAM, DP-QPSK
Form Factor QSFP-DD, OSFP QSFP-DD, OSFP
Application Data center interconnects Metro, regional, long-haul

Adding few more interesting table for readersZR

Based on application

Product Reach Client Formats Data Rate & Modulation Wavelength Tx Power Connector Fiber Interoperability Application
800G ZR+ 4000 km+ 100GbE
200GbE
400GbE
800GbE
800G Interop PCS 
 600G PCS 
 400G PCS
1528.58  to
 1567.34
>+1 dBm (with TOF) LC SMF OpenROADM interoperable PCS Ideal for metro/regional Ethernet data center and service provider network interconnects
800ZR 120 km 100GbE
200GbE
400GbE
800G 16QAM 
 600G PCS 
 400G Interop
QPSK/16QAM 
 PCS
1528.58  to
 1567.34
-11 dBm to -2 dBm LC SMF OIF 800ZR
 OpenROADM Interop PCS
 OpenZR+
Ideal for amplified single-span data center interconnect applications
400G Ultra Long Haul 4000 km+ 100GbE
200GbE
400GbE
400G Interoperable
QPSK/16QAM 
 PCS
1528.58  to
 1567.34
>+1 dBm (with TOF) LC SMF OpenROADM Interop PCS Ideal for long haul and ultra-long haul service provider ROADM network applications
Bright 400ZR+ 4000 km+ 100GbE
200GbE
400GbE OTUCn
OTU4
400G 16QAM 
 300G 8QAM 
 200G/100G QPSK
1528.58  to
 1567.34
>+1 dBm (with TOF) LC SMF OpenZR+
 OpenROADM
Ideal for metro/regional and service provider ROADM network applications
400ZR 120 km 100GbE
200GbE
400GbE
400G 16QAM 1528.58  to
 1567.34
>-10 dBm LC SMF OIF 400ZR Ideal for amplified single span data center interconnect applications
OpenZR+ 4000 km+ 100GbE
200GbE
400GbE
400G 16QAM 
 300G 8QAM 
 200G/100G QPSK
1528.58  to
 1567.34
>-10 dBm LC SMF OpenZR+
 OpenROADM
Ideal for metro/regional Ethernet data center and service provider network interconnects
400G ER1 45 km 100GbE
400GbE
400G 16QAM Fixed C to
band
>12.5 dB Link Budget LC SMF OIF 400ZR application code 0x02
 OpenZR+
Ideal for unamplified point-to-point links

 

*TOF: Tunable Optical Filter

The Future Outlook

The advent of 400G ZR and ZR+ is not just a technical upgrade; it’s a paradigm shift in how we approach optical networking. With these technologies, network operators can now deploy more flexible, efficient, and scalable networks, ready to meet the future demands of data transmission.

Moreover, the ongoing development and expected introduction of XR optics highlight the industry’s commitment to pushing the boundaries of what’s possible in optical networking. XR optics, with its promise of multipoint capabilities and aggregation of lower-speed interfaces, signifies the next frontier in coherent optical technology.

 

Reference

Acacia Introduces 800ZR and 800G ZR+ with Interoperable PCS in QSFP-DD and OSFP

Signal integrity is the cornerstone of effective fiber optic communication. In this sphere, two metrics stand paramount: Bit Error Ratio (BER) and Q factor. These indicators help engineers assess the performance of optical networks and ensure the fidelity of data transmission. But what do these terms mean, and how are they calculated?

What is BER?

BER represents the fraction of bits that have errors relative to the total number of bits sent in a transmission. It’s a direct indicator of the health of a communication link. The lower the BER, the more accurate and reliable the system.

ITU-T Standards Define BER Objectives

The ITU-T has set forth recommendations such as G.691, G.692, and G.959.1, which outline design objectives for optical systems, aiming for a BER no worse than 10−12 at the end of a system’s life. This is a rigorous standard that guarantees high reliability, crucial for SDH and OTN applications.

Measuring BER

Measuring BER, especially as low as 10−12, can be daunting due to the sheer volume of bits required to be tested. For instance, to confirm with 95% confidence that a system meets a BER of 10−12, one would need to test 3×1012 bits without encountering an error — a process that could take a prohibitively long time at lower transmission rates.

The Q Factor

The Q factor measures the signal-to-noise ratio at the decision point in a receiver’s circuitry. A higher Q factor translates to better signal quality. For a BER of 10−12, a Q factor of approximately 7.03 is needed. The relationship between Q factor and BER, when the threshold is optimally set, is given by the following equations:

The general formula relating Q to BER is:

bertoq

A common approximation for high Q values is:

ber_t_q_2

For a more accurate calculation across the entire range of Q, the formula is:

ber_t_q_3

Practical Example: Calculating BER from Q Factor

Let’s consider a practical example. If a system’s Q factor is measured at 7, what would be the approximate BER?

Using the approximation formula, we plug in the Q factor:

This would give us an approximate BER that’s indicative of a highly reliable system. For exact calculations, one would integrate the Gaussian error function as described in the more detailed equations.

Graphical Representation

ber_t_q_4

The graph typically illustrates these relationships, providing a visual representation of how the BER changes as the Q factor increases. This allows engineers to quickly assess the signal quality without long, drawn-out error measurements.

Concluding Thoughts

Understanding and applying BER and Q factor calculations is crucial for designing and maintaining robust optical communication systems. These concepts are not just academic; they directly impact the efficiency and reliability of the networks that underpin our modern digital world.

References

https://www.itu.int/rec/T-REC-G/e