Custom Case Study
While developing a next‑generation Ka‑band and W‑band satellite payload for a low‑Earth‑orbit communications constellation, an RF systems engineer encountered an unexpected challenge. Although the team designed a GaN power amplifier and low‑noise receiver chain to operate above 80 GHz, system testing revealed significant performance degradation.
The active devices met their specifications, but once the signal left the die, system performance collapsed:
- Insertion loss exceeded the link budget by 1.5 dB
- Parasitic inductance from wire bonds and interconnects distorted matching
- Board-to-board variation caused gain and phase inconsistencies across flight units
- Commercial passive components were too large and introduced resonances above 70 GHz
Custom Thin Film Integration
The RF front‑end passive network was transitioned to a custom thin‑film substrate platform:
- Ultra‑thin, low‑loss substrates reduced dielectric loss and parasitic inductance to ground
- Highly controlled metallization minimized conductor loss and surface‑roughness effects at mmWave frequencies
- Precision‑machined pockets reduced GaN die wire‑bond lengths by over 60%
- Thin‑film resistors, attenuators, and filters were integrated directly into the substrate, replacing discrete passives
This level of thin‑film integration enabled exact impedance control and filter definition at the substrate level, eliminating downstream tuning and improving build‑to‑build repeatability.
Flight-ready, High Frequency Performance
After integrating thin film:
- Insertion loss improved by 1.2 dB, restoring system link margin
- Build to build phase and gain variation was reduced to below ±0.2 dB
- Wire bond inductance was reduced by over 50%, improving RF stability
- Passive circuit footprint was reduced by 40%, enabling denser module packaging
- Qualification testing confirmed repeatable performance across temperature and vibration extremes
With these improvements, the payload achieved its high frequency performance objectives and successfully completed environmental qualification, enabling transition to flight production.
[Engineering Takeaway]
“At 100 GHz, the PCB was the problem. Thin film gave us the precision, repeatability, and low-loss performance the system demanded.”
— Aerospace RF Systems Engineer
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