Before we go on, can we just amplif

Before we go on, can we just amplify the signal by 110 dB at 11.7-12.2 GHz to get a signal level of 10
dBm (this is about 0.7Vrms in a 50 ohm system), then take off the modulated signal from the 11.7-12.2
GHz spectrum? The answer to this is: No! First, 110 dB gain amplifiers at 11.7-12.2 GHz (or even at 2
GHz for cell phones) are very hard to build and are prone to severe problems since any fF-level
capacitance feedback from the input to the output can cause oscillations. Also, they consume an immense
amount of current since we are working close to the unity-gain frequency of the transistor. Third, once we
have amplified the signal to 10 dBm, it is still at 11.7-12.2 GHz, and we need extremely fast digital
electronics (and extremely power-consuming) to take off the modulation from the carrier. We have to
“follow the carrier” at 11.7-12.2 GHz for demodulation to occur and strip the “baseband” information
from the carrier and this is very hard to do directly at 12 GHz (very difficult even at 2 GHz for cell phone
applications, which is still too fast for low power digital electronics). This is why we use mixers!
ƒ Mixers: Without mixers, we have no radios. This component is much more important than the
LNA and actually, until the 1940’s, most radios were build without the LNA but never without a
mixer. It is an amazing device, because it is a linear and a non-linear device at the same time.
Non-linear in that it acts as a multiplier, and multiplies the local oscillator frequency (fLO) with
the RF frequency (fRF) to result in a difference frequency (fRF-fLO) which is called the intermediate
frequency (fIF). So, there is a frequency translation happening in the mixer which can only happen
in a non-linear device. It is linear in the terms that it translates the RF spectrum in a linear nondistortion
matter to the IF spectrum, that is, if you have two RF frequencies, fRF1 and fRF2 with
complex levels a1 and a2, they are translated to the IF band as fIF1 and fIF2 and their respective
amplitudes and phases and perfectly preserved. This is important since you want to translate a
complicated spectrum centered at the RF frequency to an IF spectrum while preserving all the
different frequency components (amplitudes and phases).
In this case, the LO is set at 10.5 GHz and the IF is at 1.2-1.7 GHz.
ƒ Oscillators: The oscillator provides the local signal to the mixer for the frequency translation
process. They have to be extremely stable in frequency and are referenced to a crystal resonator
using a phased-locked loop (PLL). In addition, they should be tunable so as to change their
frequency (if needed) to access different channels. They should also have very low amplitude and
phase noise since you do not want to inject noise into the IF spectrum from a badly designed local
oscillator.
ƒ IF/Baseband Chain: Now, that the frequency is lowered to 1.2-1.7 GHz, we can add about 20 dB
of gain at this stage in order to boost the signal. The 1.2-1.7 GHz becomes the new carrier and the
video and sound information is still on top of this carrier. In the satellite case, the IF is mixed
again to baseband (0-2.5 MHz) using another oscillator in the 1.2-1.7 GHz range. The frequency
of this oscillator is set at 1.2-1.7 GHz (variable setting) so as to select a single 2.5 MHz channel
out of the 200 channels. Once the signal is at baseband (0-2.5 MHz), the signal is then amplified
using standard CMOS electronics by 80 dB (the amplification is done at 0-2.5 MHz), sent to the
DSP chip, and the DSP does the digital demodulation