3 Short-Range Comms & IoT Mode
3.6 Power Stat CCDF Measurement
–
Mech Atten at 0dB. Elec Atten enabled, Mech Atten set to 10dB, and Elec Atten
set to 0dB. New total attenuation does not equal the value before Elec Atten
enabled
–
Mech Atten at 40dB. Elec Atten enabled, Mech Atten set to 10dB, and Elec
Atten set to 24dB. New total attenuation does not equal the value before Elec
Atten enabled
When the Electronic Attenuation is disabled from an enabled state:
–
The Elec Atten control is grayed out
–
The Auto/Man state of (Mech) Atten is restored
–
If now in Auto, (Mech) Atten recouples
–
If now in Man, (Mech) Atten is set to the value of total attenuation that existed
before the Elec Atten was disabled. The resulting value is rounded up to the
smallest value possible given the (Mech) Atten Step setting - (That is, 57dB
changes to 58dB when (Mech) Atten Step is 2dB)
Using the Electronic Attenuator: Pros and Cons
The electronic attenuator offers finer steps than the mechanical attenuator, has no
acoustical noise, is faster, and is less subject to wear.
The “finer steps” advantage of the electronic attenuator is beneficial in optimizing
the alignment of the instrument dynamic range to the signal power in the front
panel as well as remote use. Thus, you can achieve improved relative signal
measurement accuracy. Compared to a mechanical attenuator with 2dB steps, the
1dB resolution of the electronic attenuator only gives better resolution when the
odd-decibel steps are used. Those odd-decibel steps are less accurately calibrated
than the even-decibel steps, so one tradeoff for this superior relative accuracy is
reduced absolute amplitude accuracy.
Another disadvantage of the electronic attenuator is that the spectrum analyzer
loses its “Auto” setting, making operation less convenient.
Also, the relationship between the dynamic range specifications (TOI, SHI,
compression, and noise) and instrument performance are less well-known with the
electrical attenuator. With the mechanical attenuator, TOI, SHI, and compression
threshold levels increase dB-for-dB with increasing attenuation, and the noise floor
does as well. With the electronic attenuator, there is an excess attenuation of about
1 to 3dB between 0 and 3.6GHz, making the effective TOI, SHI, and so forth, less
well known. Excess attenuation is the actual attenuation relative to stated
attenuation. Excess attenuation is accounted for in the instrument calibration.
Short Range Comms & IoT Mode User's &Programmer's Reference 701
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