A while ago I was using a software radio receiver to perform some antenna analysis. I left the spectrum display on while disconnecting the cable and noticed that when the cable was disconnected I could see a very large spike in the frequency component at the center frequency of the display (where the receiver was tuned). I changed the center frequency several times and noticed the same spike appeared regardless of where I tuned.

Some time later I reconnected a cable and accidentally tuned to a frequency that was completely "out of spec" for the antenna I was using. The same spike appeared at the center of the display; I tuned around to several nearby frequencies and found that the spike stayed put. It disappeared when I moved back to a frequency at which the antenna was designed for operation.

What is the nature of that spike and why does it appear when tuned to a frequency at which the antenna is not resonant, as well as when the antenna is disconnected?

EDIT: Here are some screenshots of the spike I'm referring to:

FFT tuned

This is an FFT of the received spectrum through an antenna tuned for the 2M band. Everything is nice and flat.

FFT detuned

This is an FFT of the spectrum through the same antenna but at a completely unworkable operating frequency. The middle is a bit noisy but still shows the spike at the center frequency well.

enter image description here

Here's the FFT at the same frequency, but with no antenna connected. The spike is clearly visible here, and this is what I'm interesting in learning about.

  • 1
    $\begingroup$ Can you illustrate this spike? Screenshot of the waterfall, perhaps? $\endgroup$ Commented Oct 22, 2014 at 17:53
  • $\begingroup$ The FFT would be a more useful screenshot; I'll post a few tomorrow. $\endgroup$
    – mtrberzi
    Commented Oct 23, 2014 at 19:17

2 Answers 2


That is probably 1/f noise. This is noise where each octave has equal power. At lower frequencies, each octave is narrow, and thus has more power per unit frequency. It is ubiquitous in every electrical circuit, and in fact a great many physical processes.

This will always appear at the center of your FFT, regardless of where the radio is tuned, as the center of the FFT always corresponds to the frequency of your receiver's VFO input to the mixer. For example, if the VFO is tuned to 900 MHz, then a 900.01 MHz signal will appear at 900.01 - 900 MHz = 10 kHz, after mixing. 900 MHz appears at 0 Hz after mixing, the lowest frequency possible.

1/f noise is present in all electronics, and this is why you observe it even with no antenna connected. It can originate in the components that comprise the gain stages of the receiver like resistors and transistors, and noise so generated then goes on to be amplified and made visible in the FFT.

Better, and usually more expensive engineering can reduce noise like this, but in your particular case it would have negligible benefit. If you compare the scale on the left, this noise is significantly below the RF noise floor when you have an antenna connected. Consequently, you will realize very little benefit from reducing the noise.

  • 1
    $\begingroup$ Is this the same as, or different than, the stronger VFO-centered spike in some hardware commonly called “DC offset”? $\endgroup$
    – Kevin Reid AG6YO
    Commented Oct 25, 2014 at 16:15
  • $\begingroup$ I'd like to express some doubt about the 1/f theory here. I'd rather believe this is just the fact that there is some DC effect possibly by leaving the connector open, as Kevin proposed. It seems to be that 1/f would still have to be present if the antenna is connected (as it would be generated in the hardware). $\endgroup$
    – jcoppens
    Commented Oct 25, 2014 at 17:03
  • $\begingroup$ @jcoppens, isn't that exactly the case in the middle image? $\endgroup$ Commented Oct 25, 2014 at 17:20

The fact that the spike is present, with no antenna connected, inducates it is a product of the receiver chain. Since it happens bang on the frequency you have tuned, implies the DC or low frequency attributes of the system are causing this.
While you show an FFT at 2m with antenna connected, you don't show 2m without antenna. However, even at 900MHz there seems about 20dB difference when antenna is removed.
As other have commented, there comes a point where increasing sigmal into a receiver adds noise as well, for no overall gain. You first picture is showing such a setup, where levels are high enough to "mask" potential distortion caused by receiver performance. The other pictures, where antenna performance is poor (or disconnected) expose the limits of the receiver.


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