Replies to post #230864 on Lightwave Logic Inc (LWLG)

[tedpeele]

Gemini q&a: Is the PDK that Luceda can use for the front end processing which adds in the modulator only, or also for the back end processing

This is a technical question that hits on the core of why the Luceda PDK announcement in Ghent is a game-changer for Lightwave Logic.

To answer directly: The PDK is designed to bridge both, but its primary function within the Luceda environment is for the Front-End-of-Line (FEOL) design of the modulator structures, while specifically accounting for the Back-End-of-Line (BEOL) polymer addition.

Here is the breakdown of how this works in the actual chip-making process:

1. The Front-End (Design & Fabrication)

When a customer uses the Luceda IPKISS software, they are performing Front-End design. They are dragging and dropping "PCells" (Parameterized Cells) of Lightwave Logic’s modulator into their chip layout.

The "Slot" Modulator: The foundry (like SilTerra or GlobalFoundries) actually builds the physical "skeleton" or "slot" of the modulator using standard silicon.

The PDK's Role: The PDK ensures that the silicon structures built in the front-end are perfectly optimized to receive the polymer later. It handles the math for light propagation and electrical signals so the designer doesn't have to guess.

2. The Back-End (The "Spin-On" Process)

The physical addition of the Perkinamine® polymer is strictly a Back-End-of-Line (BEOL) process.

The Process: Once the foundry finishes the silicon wafer (Front-End), the polymer is "spun" onto the wafer, filling those silicon slots.

The Benefit: Because this happens at the back end, it doesn't interfere with the delicate transistors or "front-end" electronics. This is why Yves emphasized in Ghent that their material is "allowed" in top-tier foundries where others are banned.

3. Why the Luceda PDK is the "Bridge"

The Luceda PDK is essentially the instruction manual that tells the Front-End foundry exactly how to build the silicon so that the Back-End polymer will work perfectly.

It provides simulation-validated models: A designer in Ghent can simulate exactly how the light will behave once the Denver team adds the polymer, before a single piece of silicon is ever etched.

It enables Tape-Out: This allows the 1.6T transceiver customer you mentioned to send their design to the foundry (FEOL) with the confidence that when the chips come back to Denver for coating (BEOL), they will hit the targeted performance.

Summary of the Workflow

Luceda Software (Front-End Design): Customer designs the PIC with the Lightwave PDK.

Foundry (Front-End Fab): "Top-tier" foundry builds the silicon wafer with empty modulator "slots."

Lightwave Denver (Back-End Processing): Lightwave coats the wafer with polymer, "activating" the modulators.

Final Product: Ready for the 1.6T and 400G CPO markets.