SdrDx Documentation -- Visual Signal Processing (page 24)

4.12 - Visual Signal Processing

4.12.1 - General

One of the joys of SDR use is the rich spectrum and waterfall information available to assist in station identification and tuning. The bane of figuring out what is going on, however, is noise. Just as noise is never helpful when attempting to receive what a radio transmission is sending, it is also not helpful when looking at the information in the form of the spectrum and the waterfall.

SdrDx offers a range of options for controlling what you see, as opposed to what you hear, with the specific goal of making what you see more useful to you.

4.12.2 - Noise Blanker Display Options

There are three states you can be in when you click NBL or use the keyboard to change its state (the standard key is /, although you can change that with Ref.)

With NBL, no processing is going on, and the spectrum and waterfall therefore represent the raw RF information coming from the SDR or recording. The RF goes to the active demodulator with no changes.

With NBL, the noise blanking DSP removes what impulse noise it can identify, and the resulting RF is fed both to the active demodulator and to the spectrum and waterfall. With the general noise removed, you can see more in some ways, but when noise is removed from the RF, the information in the spectrum and waterfall is no longer an accurate representation of the RF, and signals can look different in ways that are not accurate as far as the received signal is concerned -- but is accurate in that any signal that looks different on the spectrum and waterfall will also be processed by the active demodulator differently. Often, that means "better", but not always.

With NBL, the RF is fed to the spectrum and waterfall prior to the noise blanking, so there is no effect from the blanker on the displayed information — but the above remarks about effects on demodulation still apply. The noise blanker is running, you just won't see the effects visually. Sometimes this is more informative; sometimes not. It's always good to try both until you have a good sense of what you'll see, and why.

4.12.3 - SBW - Spectrum Bandwidth

SBW reduces visual noise by using the random nature of adjacent frequencies to average out the random changes at any point along the spectrum that are under the threshold, which is set by →Right-click SBW

4.12.4 - TRI - Amplitude Triage

TRI reduces visual noise by using the random nature of each specific frequency over time to average out the random changes at any point along the spectrum that are under the threshold, which is set by →Right-click TRI — you can set the degree of noise reduction above and below the threshold independently.

4.12.5 - SNF - Smooth Noise Floor

SNF reduces visual noise by directly reducing the amplitude of all frequencies that are under the threshold, which is set by →Right-click SNF.

4.12.6 - FFT Resolution

In the DSP (Display) dialog, you can set FFT Averaging from 1 to higher values. Values above 1 average the spectrum and waterfall over time, which has the salutary effect of significantly reducing spiky noise at the noise floor level. The FFT Averaging setting profoundly affects SBW, TRI and SNF.

4.12.7 - FFT Averaging Behaviors

TRI has its own FFT averaging settings; so if you adjust it in the DSP (Display) dialog with TRI on, it will change back to whatever it was if you turn TRI off. Each state will recall its setting, it's just something to be aware of as intended behavior.

4.12.8 - Waterfall Palettes

The color palette applied to the RF waterfall has a significant effect on your ability to see just what is going on, so it is highly recommended to experiment with various palettes of your own design using EDP, and if you like the results, use SVP to save the results for later reuse. If you're not willing to go to that extent, you can still use the PAL button to switch between two preset palettes; one is color, the other is greyscale.

4.12.8.1 - Using Auto-Adjust Waterfall

Before AAW

After AAW

While tuned to a station, pressing and holding AAW allows SdrDx to sample the spectrum within the demodulator bounds. When you release AAW, the waterfall intercept and contrast are adjusted to try to optimize the waterfall for that particular tuning. This works best if the signal goes to maximum and minimum during the sample time (the time you hold down AAW) It won't do a perfect job in all situations because noise spikes can throw it off, so particular with low FFT averaging, you'll see some less-than-optimum results.

You can →Right-click AAW to adjust its settings. 500 is no effect for both bias and contrast. Increasing bias pushes intercept up; increasing contrast above 500 pushes contrast up. Likewise, below 500 these cause decreases in the computed AAW results.

If the display resulting from application of AAW has too dark a noise floor for your taste, try reducing the →Right-click AAW contrast setting a little bit (say, to 400 or so) before you try adjusting the bias setting.

If you sample higher levels without catching some of the noise floor, you'll get a lower (generally darker, unless you've gotten really creative with the waterfall palette) intercept and a bit more contrast. This might be what you want — try it and see.

Of course, once AAW has made its changes to intercept and contrast, you can further adjust the settings manually to your precise taste.

4.12.9 - Combining Visual Noise Reduction Techniques

SBW, TRI and SNF can be used together in any combination, with or without NBL, with various FFT averaging settings, and with any waterfall palette and associated intercept and contrast settings you choose.

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