What is the expected ambient noise say
@ 600M one should expect??

I then connected to the outside antenna with no external pre-amp or any non

linear device and saw -117 dbm of noise across 10 khz. with a few weak and
floating predictable BB noises..

The P-P Western Eklectic 417As are wasted here...

For now the double balanced, biased 1N34s are fine...
Tried 1N23As, no big deal... Like giving strawberrys to a donkey on 600M...

TNX until the sound of

Dave @ /17

To: <[email protected]>
Sent: Thursday, March 05, 2009 2:31 PM
Subject: Re: LF: Deep copy...


It all depends on your resolution bandwith which you don't specify.
Pnoise = kTB

With my SDR-IQ set to 190kHz span and 131072 point FFT, resolution
bandwidth = 1.5Hz and Rx set to +10dB gain to get the best  noise
figure:
-145dBm with a 50R load.  With the Antenna connected this rises to
-115dBm (measured at 1920 UTC) with no obvious lines or peaks
contributing.

If you normalise to the standard 2.5kHz noise measurement bandwidth,
that equates to -112 (50R)  and -82dBm.(antenna) respectively

Thermal noise at reference temperature of 290K is -174dBm/Hz, so for
2.5kHz that gives -140dBm suggesting the noise figure of the SDR-IQ
could be 140 - 112 = 28dB.    It probably isn't this low as we're in
the quantisation noise with no input signal, but a NF of 15 - 20dB
would probably be a rough guesstimate.

Andy  G4JNT
www.g4jnt.com



2009/3/5 dave.riley3 <[email protected]>:

Thanks to ALL who responded with quick and cogent findings...

It has seemed for a time that with the receiver AGC and NBs OFF that I
generally can see a deeper signal, depending on conditions...

The final audio filter assures that the program does not have to deal with
noise outside of the passband of interest...

TNX


Here is today's gnawing question... What is the expected ambient noise say
@ 600M one should expect??
Rural, City, Country, remote battery operated, etc. combinations...
Especially well away from AC neutral wires...

Today I ran the input to the SDR-IQ into a 50 ohm load and set a long
integrate ( 64+ ) and saw approx -134 dbm of baseband noise with NO
signals...

I then connected to the outside antenna with no external pre-amp or any non

linear device and saw -117 dbm of noise across 10 khz. with a few weak and
floating predictable BB noises..

At night it is sure to be up to near -100 dbm depending on conditions and
noises present...

What do YOU get for a noise difference between a terminated antenna input
and your regular receive antenna??

I'm about to place several e-probes about this place in order to mix and

match phase and amplitudes in order to see what net gain can be made to the SNR with the hope that the most offending noises will not be in the path of

a desired signal...

TNX and ain't this fun???

Dave @ WD2XSH/17









----- Original Message -----
From: Bill de Carle
To: [email protected]
Sent: Thursday, March 05, 2009 9:58 AM
Subject: Re: LF: Deep copy...
At 09:25 PM 3/4/2009, you wrote:

I seem to get best results while trying to pull signals out of the noise
when the AGC of the receiver is OFF as well as the Noise Blanker and Noise
reduction features being OFF...

Do you concur??

Also setting a good audio filter to the passband of interest seems to bypass

some heavy static hits as well...

I've noticed that when doing HF frequency measurement tests (working to the nearest milliHertz) - turning off the AGC under high static conditions seems

to improve the accuracy of the measurement, at least with the software I
use. One plausible explanation is that AGC action necessarily introduces
amplitude modulation (on all signals in the passband). When I process the
AGC'd signal with what amounts to a very narrow DSP filter the added
amplitude modulation shows up as apparent sidebands close-in on the signal
I'm trying to measure. If the power in those sidebands is comparable to

that of the signal whose frequency I'm looking for, the FFT algorithm (which

assumes the real signal has the largest amplitude) gets confused and comes

up with an estimated frequency somewhere between the correct value and that

of a nearby sideband. The effect is small however because the AGC pumping
action doesn't occur very fast so the added sidebands are seen to be only
some milliHertz away from the signal. The sidebands occur on both sides of
the "real" signal, so one might expect them to cancel out but in practice
they don't because the amount of error depends on where the "real" signal
falls with respect to the fixed frequency bins of the FFT. It should be

possible to model the AGC action of a particular receiver and compensate for

it in the software. No doubt the phenomenon becomes less significant with
smaller FFT's or shorter integration times. Changing the AGC setting
between SLOW-FAST-OFF might help under some conditions. With QRSS-60
signaling rates it can take a long time to find out which setting is
optimum, especially when band conditions are changing or the QSB period is
close to a bit time, hi!

VE2IQ