Designing a multiband SSPA with a perfectly flat gain curve feels like an impossible task. The physics just seems to be working against you. But it is achievable.
To design a multiband Solid State Power Amplifier (SSPA) with flat gain, you must combine three techniques1. First, use a negative feedback circuit for stability. Second, add an R-L-C input matching network to flatten the gain. Third, use wideband load-pull to control harmonics and maintain efficiency.
I've been designing RF components for over a decade, and this challenge comes up on almost every wideband project. The temptation is to focus on just one area, like output power, and hope for the best. But that never works. A great wideband amplifier isn't about one single achievement; it's about balancing multiple competing factors. The good news is that there's a proven method. By breaking the problem down into three specific areas—gain stability, gain shaping, and harmonic control—you can build an amplifier that performs consistently across its entire frequency range. Let’s walk through how we do it.
How does negative feedback stabilize gain in a distributed amplifier?
You've built a distributed amplifier, but the gain is all over the place. It seems to change with temperature, frequency, and even on different days. This makes it unreliable.
Negative feedback is the key to taming this instability. By feeding a small, inverted portion of the output signal back to the input, you sacrifice a little gain to achieve a much more predictable and flat response across the entire band.
In my experience, especially with distributed architectures where you're combining power from multiple transistors, inherent gain can be very high but also very unstable. The primary job of negative feedback is to bring order to this chaos. Think of it as a governor on an engine. It keeps things from running wild. We intentionally reduce the overall gain, which might sound counterintuitive. But in return, we get a system that is far less sensitive to variations in individual components or operating conditions. I remember a specific project where the prototype's gain swung by 4 dB across the band. After implementing a simple resistive feedback loop, that variation dropped to less than 1 dB. The amplifier became a reliable, predictable building block. This stability also helps improve the input and output return loss, making the SSPA easier to integrate into a larger system.
| Paramètre | Without Negative Feedback | With Negative Feedback |
|---|---|---|
| Gain Variation | High (e.g., >3 dB) | Low (e.g., <1 dB) |
| Stability | Poor, sensitive to changes | Excellent, very robust |
| Return Loss | Poor | Good |
Why is an R-L-C network crucial for input matching?
Even with feedback, your gain probably still droops at high frequencies. Most transistors naturally have more gain at lower frequencies. This imbalance ruins your wideband performance.
An R-L-C input matching network acts as a gain equalizer2. It's designed to introduce more loss at lower frequencies3, bringing the gain down to match the naturally lower gain at higher frequencies. This is how you achieve a flat response.
This is a step that many designers overlook. They spend all their time trying to boost the high-frequency gain, which is incredibly difficult and often compromises other aspects of the design. The smarter approach is to gently reduce the low-frequency gain. This is where the R-L-C network comes in. The resistor (R) is what creates the loss, and the inductor (L) and capacitor (C) make that loss frequency-dependent. At low frequencies, the network is designed to have a lower impedance, causing more of the input signal to be attenuated. As the frequency increases, the network's impedance rises, and less signal is lost. For a recent 3000-watt SSPA we developed at Safari Microwave, this was the exact technique we used. The raw amplifier had a 5 dB downward tilt from 2 GHz to 6 GHz. By carefully tuning the R-L-C values, we flattened it to within 0.8 dB, creating a truly ultra-wideband product.
| Frequency | Gain without RLC Network | Gain with RLC Network |
|---|---|---|
| Low Band | 20 dB | 16 dB |
| Mid Band | 18 dB | 15.8 dB |
| High Band | 15 dB | 15.2 dB |
What is the role of wideband load-pull in harmonic suppression?
Your gain is finally flat, but your Power Added Efficiency (PAE) is terrible. Looking closer, you see that harmonics are running wild, distorting your signal and wasting precious DC power.
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|---|---|---|
| PAE | 45% | 65% |
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| Intégrité du signal | Modérée | Excellente |
Conclusion
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"Intermodulation noise related to THD in wide-band amplifiers", https://ieeexplore.ieee.org/document/554340/. Technical literature on wideband and multi-octave amplifiers highlights the challenge of in-band harmonics, where, for example, the second harmonic of a signal at the low end of the band falls within the operational frequency range, causing distortion that cannot be filtered externally. Evidence role: general_support; source type: paper. Supports: The claim that harmonics generated at lower frequencies can fall within the passband of a wideband amplifier.. ↩
"Long-Term PAE Results: What Do We Know - PMC", https://pmc.ncbi.nlm.nih.gov/articles/PMC9767787/. Research papers comparing power amplifier designs often report significant improvements in PAE with the implementation of harmonic tuning, with some studies showing increases from around 40-50% to over 70-80%, supporting the claim that neglecting it can result in substantially lower efficiency. Evidence role: statistic; source type: paper. Supports: The claim that harmonic termination can lead to a very large increase in Power Added Efficiency (PAE).. Scope note: The exact percentage of PAE improvement is highly dependent on the transistor technology, frequency, and specific amplifier class being designed. ↩
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