Achieving Seamless Interoperability with 224 Gbps SerDes

The exponential growth of AI/ML workloads, particularly large language models is driving a paradigm shift in high-performance computing and AI data center architectures. The need for real-time inference and training at scale is pushing the limits of both compute and interconnect technologies. As model sizes and parameter counts double every 4–6 months, the underlying infrastructure must deliver not only massive computational throughput but also unprecedented bandwidth and low-latency data movement between thousands of accelerators.

This article provides a technical exploration of the system-level challenges and solutions for achieving seamless 1.6Tbps port-level interoperability in next-generation SoCs, focusing on the role of 224G SerDes, emerging interconnect protocols, and the critical importance of signal and power integrity in dense, high-speed environments.

Standards and Specifications

To ensure that 224G SerDes solutions are interoperable and reliable across the industry, standards bodies such as IEEE and OIF are actively developing comprehensive electrical and long-reach (LR) specifications, with ratification expected by 2025. Additionally, the Ultra Ethernet version 1 of the spec was recently released and UALink 200G was announced earlier this year. These standards are crucial: they provide a common framework that allows components from different vendors to work together seamlessly, which is essential for the rapid deployment and scalability of modern data center infrastructure.

Channel and Signal Integrity

At 224G, the Nyquist frequency is doubled compared to 112G, which dramatically increases the impact of channel loss and crosstalk. Every element in the signal path—PCB traces, connectors, and packaging—contributes more loss at these higher frequencies. For example, 32 AWG Twinax cable can exhibit around 14 dB/m insertion loss at 56 GHz, and total channel loss in a typical system can easily reach 40–50 dB. This level of attenuation makes traditional PCB-based routing insufficient for many high-speed links, driving the adoption of advanced materials, improved connector designs, and alternative approaches such as flyover cables to preserve signal integrity.

Need for Equalization and DSP of SerDes Receiver

Maintaining robust data transmission at 224G requires advanced digital signal processing (DSP) and equalization techniques to compensate for severe channel impairments. Modern SerDes architectures incorporate:

• High-bandwidth analog front ends (AFE)

• Low-noise analog-to-digital converters (ADCs)

• Powerful feed-forward and decision feedback equalization (FFE/DFE)

• Maximum Likelihood Sequence Detection (MLSD)

These receiver blocks work together to ensure open eye diagrams and low bit error rates (BER), even in challenging environments, with pre-FEC BER targets orders of magnitude better than 1E-4. The DSP must be adaptable, supporting both short-reach (chip-to-module) and long-reach (backplane, flyover, or optical) channels.

Architectural Demands and DSP Upgrades at 224Gbps

At these speeds, every block in the SerDes architecture must be enhanced. The analog front end (AFE) requires increased bandwidth, and analog-to-digital converters (ADCs) must deliver lower noise performance. The phase-locked loop (PLL) jitter budget is tightened due to reduced unit interval (UI), and the DSP must provide robust equalization—often leveraging advanced techniques such as Maximum Likelihood Sequence Detection (MLSD)—to compensate for 45 dB of channel loss. Importantly, these improvements must be achieved without a proportional increase in power consumption, even as switches and accelerators integrate 200+ SerDes lanes.

Before hardware is available, system implementers rely on comprehensive simulation environments to predict and optimize performance. These simulations model the entire signal path, including:

• Transmitter IBIS-AMI models

• Full package extraction, accounting for near-end and far-end crosstalk across hundreds of lanes

• Interconnect modeling, spanning PCB traces, connectors, flyover cables, and even optical links 

• Receiver IBIS-AMI models

The simulation environment enables designers to evaluate signal integrity, crosstalk, and the impact of simultaneous switching across many lanes. By constructing a virtual system—transmitter to receiver, including all intermediate interconnects—engineers can forecast whether the receiver will observe an open eye diagram and acceptable bit error rate (BER).

Key Metrics and Margin Analysis from simulation to Silicon Interop 

A primary metric is the pre-FEC BER, with specifications typically targeting better than 1E-4. However, robust system design requires margin across process, voltage, and temperature (PVT) variations. Simulations must also assess the effectiveness of forward error correction (FEC), comparing pre-FEC and post-FEC BER across all PVT corners to ensure reliable operation under worst-case conditions.

Hardware Validation and Channel Characterization

Once silicon is available, these models are validated against real hardware. For example, with 224G SerDes, system channels with 40–45 dB of loss are characterized using actual silicon, interconnects, and cables. Both near-end and far-end crosstalk are measured, and the results are compared to simulation predictions to close the loop on model accuracy.

SerDes performance cannot be evaluated in isolation. The full system—including interconnects, cables, connectors, packaging and PCB —must be considered. 

In order to work in a HPC environment, it is not enough to design the SerDes with IEEE or OIF spec and test against the electrical specification for TX compliance or RX JTOL. SerDes needs to work with Eco-system vendors to provide a pre-tested, pre-verified solution for the system integrators and enable seamless integration when they are deployed to form the rack connectivity. For instance, interop with high-density cable assemblies, OSFP pluggable, 1-2m direct attach copper (DAC) cables, and near-chip NPC, CPC assemblies from various vendors with up to 45-50 dB reach provide the groundwork needed on the system validation of the real-world scenarios within the rack and rack-to-rack connectivity path. These interop tests confirm that the SerDes and interconnects, package, PCB – end-to-end channel work together to deliver the required performance on a HPC system.

As the industry looks beyond 224G, the transition to 448G SerDes is already underway. This next leap will require not only doubling the data rate but also rethinking modulation schemes and channel definitions to address the unique challenges at these frequencies.

• Modulation and Channel Evolution

  • Copper Interconnects: For 448G over copper, the industry is converging on PAM-6 modulation, which operates at a Nyquist frequency of approximately 86.7 GHz. Standards bodies such as OIF and IEEE are actively defining new channel specifications for short, mid, and long-reach applications, ensuring robust performance across diverse deployment scenarios.
  • Optical Links: For optical channels, PAM-4 modulation is expected to remain the standard, leveraging its proven high-frequency performance and signal integrity at a Nyquist frequency of around 112 GHz. This approach balances the need for higher data rates with the practicalities of optical component design and deployment. 

These channel behaviors will determine the PHY modulation and complexity, and vice versa.

The move to 448G will intensify demands on every aspect of the system, from advanced materials and connector technologies to even more sophisticated DSP and equalization techniques. Power delivery, thermal management, and system integration will all require further innovation to maintain signal integrity and energy efficiency at these unprecedented speeds.

Achieving seamless 1.6 Tbps interoperability in next-generation HPC and AI/ML SoCs is a complex, multidisciplinary challenge that extends far beyond SerDes design alone. Success depends on:

• Innovative SerDes Architectures: Incorporating advanced equalization, adaptive DSP, and power-efficient design to overcome severe channel impairments.

• High-Performance Interconnects: Leveraging both copper and optical technologies, with careful attention to signal and power integrity across the entire system.

• Comprehensive System Modeling and Validation: Employing rigorous simulation and hardware validation to ensure robust operation under all conditions.

• Ecosystem Collaboration: Fostering close partnerships across silicon, packaging, interconnect, and system integration domains to accelerate innovation and deployment.

With 224G SerDes solutions now entering production and 448G technologies on the horizon, the industry is well-positioned to deliver the bandwidth, scalability, and reliability required for the next wave of AI and HPC advancements. Continued progress will depend on holistic system engineering, robust standards development, and a relentless focus on interoperability—ensuring that tomorrow’s data centers can keep pace with the ever-expanding demands of artificial intelligence and high-performance computing.

Synopsys 224G PHY IP meets the growing high bandwidth and low latency needs of high-performance data center applications. Using leading-edge design, analysis, simulation, and measurement techniques, the Synopsys 224G PHY IP delivers exceptional signal integrity and jitter performance that exceeds the IEEE 802.3 and OIF standards electrical specifications and supports UALink 200G.