Zupt

During offshore wind installation, crews are often working with limited visibility to monopiles, vessel movement, environmental forces, and tight installation tolerances. Small positioning errors can quickly turn into lost time offshore, additional vessel costs, or rework.

That's why real-time positioning, monitoring, and measurement play such an important role throughout the installation process.

Whether it's subsea template monitoring, monopile installation support, transition piece alignment, or creating digital models that help teams understand what's happening in real time, the goal is the same: give crews the information they need to make confident decisions when conditions are less than perfect.

Our team will be attending Global Offshore Wind this week, and we're looking forward to connecting with people across the industry.

If you're working on offshore wind installation projects and facing challenges around positioning, monitoring, or installation accuracy, we'd love to chat.

Corrosion, free spans, and anode depletion aren't difficult to identify during a pipeline inspection.

Understanding their extent is often the greater challenge.

Without detailed inspection data, it can be difficult to fully characterize observed conditions and understand what is happening along the asset.

That's where Zupt's contactless 3D Recon V2 technology comes in.

Operating from an ROV or AUV, the system collects the data needed to generate a high-resolution point cloud or mesh model of a pipeline section and the surrounding seabed in a single pass.

By integrating an inertial navigation system with five high-definition cameras, the system accurately models a larger area of visible pipeline and nearby seabed while creating a scalable deliverable.

The resulting model can be integrated with vehicle positioning information to provide the absolute position of the surveyed asset, delivering detailed visibility into:

• Corrosion and anomalies
• Free span length and depth
• Anode depletion

This same 3D Recon technology is also used to generate high-resolution, color-palletized models for the inspection of transmission lines, structures, and as-built infrastructure associated with offshore wind projects.

If you'd like to learn more about the technology or discuss a specific application, get in touch with us. https://zupt.com/services/contact-us?utm_source=linkedin&utm_medium=social&utm_campaign=q3_lead_gen

In theory, shallow water is supposed to simplify offshore survey, but in practice, it often makes metrology harder. Acoustic multipath is often a difficult and time-consuming problem to overcome, which adds complexity and vessel time to what would seem like a straightforward LBL metrology.

Zupt actively pushes for clients to use C-PINS as a time-saving metrology solution, ESPECIALLY in shallow-water environments.

Zupt’s C-PINS system delivers:

🟧 Millimeter-level accuracy in any water depth
🟧 No acoustic array requirement
🟧 Reliable performance in noisy environments
🟧 Faster deployment and accelerated turnaround

Instead of working around acoustic limitations, the approach removes many of them entirely.

For operators focused on reducing offshore time while maintaining positioning confidence, that changes the conversation.

Especially in shallow-water projects where efficiency matters just as much as precision.

We’re pleased to welcome Ammar Siddiqui to Zupt as our newest Offshore Survey Engineer.

A recent Mechanical Engineering graduate from NED University of Engineering and Technology, Ammar brings hands-on experience in manufacturing, production processes, quality improvement, and industrial safety across chemical, aerospace, and automotive environments.

His background includes work in root cause analysis, CAD-based design validation, process optimization, and compliance with ASTM, API, and OSHA standards.