D2D PHY

A D2D PHY (Die-to-Die Physical Layer) is a high-speed physical communication layer that enables data exchange between multiple semiconductor dies integrated within the same package. D2D PHYs are a key building block in modern chiplet-based architectures, 2.5D/3D integration, and advanced heterogeneous computing systems.

The D2D PHY represents the lowest hardware communication layer of a die-to-die interconnect. It manages electrical signaling between dies, including data transport, clocking, synchronization, signal integrity, power management, and calibration mechanisms.

With the rapid growth of artificial intelligence, high-performance computing (HPC), and modular semiconductor architectures, die-to-die interconnects have become essential for overcoming the limitations of traditional monolithic SoC designs.

Background and Evolution

For decades, semiconductor devices were primarily designed as monolithic chips where all functional blocks were integrated on a single die. However, increasing design complexity, rising advanced-node manufacturing costs, and reticle size limitations accelerated the adoption of multi-die architectures.

Chiplet-based designs provide several advantages:

• Improved manufacturing yield
• Better cost optimization
• Reuse of existing IP blocks
• Faster time-to-market
• Ability to combine multiple process technologies within a single package

In these architectures, D2D PHYs provide the high-speed communication infrastructure connecting the various dies together.

D2D PHY Architecture

A D2D PHY typically consists of several major functional blocks.

Transmitters and Receivers

The PHY integrates:

• Transmitters (TX)
• Receivers (RX)
• Output drivers
• Equalization circuits
• Termination circuits

These blocks ensure reliable data transmission over very short distances inside the package.

Clocking and Synchronization

D2D interfaces may use various synchronization mechanisms:

• Source-synchronous clocking
• Embedded clocking
• Clock forwarding
• Strobe forwarding
• DLLs and PLLs

Because die-to-die links operate over extremely short channels, they can support very high operating frequencies with low latency.

Training and Calibration

Modern D2D PHYs include sophisticated calibration and training features such as:

• Lane deskew
• Eye training
• Lane repair
• Thermal compensation
• PVT (Process, Voltage, Temperature) compensation

These mechanisms help maintain reliable communication under varying operating conditions.

Power Management

Energy efficiency is a critical requirement for D2D PHYs, particularly in AI and HPC applications.

Common power optimization techniques include:

• Dynamic voltage scaling
• Power gating
• Low-power idle states
• Adaptive link management

Packaging Technologies

D2D PHYs are closely associated with advanced semiconductor packaging technologies.

2.5D Integration

In 2.5D architectures, multiple dies are interconnected through a silicon interposer.

Typical applications include:

• GPUs with HBM memory
• AI accelerators
• High-performance FPGAs

3D IC

3D IC technologies vertically stack multiple dies using:

• Through-Silicon Vias (TSVs)
• Hybrid bonding

Benefits include:

• Extremely high bandwidth
• Reduced latency
• Higher integration density

Organic Substrate Packaging

Some D2D PHY implementations operate directly on organic substrates without silicon interposers.

This approach is generally more cost-effective but introduces greater signal integrity challenges.

Major D2D Standards

Several industry standards have emerged to standardize chiplet interconnect ecosystems.

UCIe

Universal Chiplet Interconnect Express (UCIe) Consortium is currently the leading open standard for die-to-die communication.

The specification defines:

• PHY layer requirements
• Protocol stack
• Software interoperability
• Multi-vendor compatibility

UCIe supports multiple packaging approaches, including:

• Organic substrates
• Silicon interposers
• Advanced packaging technologies

BoW

BoW (Bunch of Wires), developed by the Open Compute Project, provides a simplified low-power die-to-die interface approach.

BoW focuses on:

• Low complexity
• Reduced power consumption
• Short-reach communication

Proprietary D2D PHYs

Many semiconductor vendors also develop proprietary D2D PHY technologies optimized for:

• Maximum bandwidth
• Low latency
• High density
• Superior energy efficiency