mixaloybas
Junior Member level 1
Suppose we have an RF power amplifier that the manufacturer has stated that in order for the amplifier to provide max power , it has got to "see" a load characterized by some impedance vs freq.
We also know that the amplifier in NOT linear (something like class C for example). We want to use the amplfier in a narrow band system, so we try to match the amplifier only in this narrow band of frequncies in order to obtain sufficient power tranfer to the load. We must also not be disturbing other bands, so we have to employ filterring. Suppose we decide to design a reflective type filter, that reflects the energy in the stopband back to the source.
We take our LINEAR simulator and design such a matching network and filter, and indeed we have an almost perfect match at the frequency of our band, and great missmatch losses at the stopband-->which means the stopband is efficiently filtered.
IF the amplifier was LINEAR,and if we examined the plot of S21 vs freq and found that at xxxMHz(in stopband) it is -30dB, we could confidently say that this frequency is attenuated by 30dB. Is that correct?
However, our amplifier is NOT a linear device, so a possible mismatch of 30dB (calculated using LINEAR theory) doesnt mean that the amplifier will deliver 30dB less power than that it would deliver if it had an optimum load connected. What I want to say is that (if for example the optimum load values were derived using load pull analysis) it could be possible for the amplifier to give 20dBm to a load of 20+j30, 19.5dBm to a load of 10+j5, 19dBm to 1-j20 (and so on), which is totally uncorrelated with the linear results...
So , the plot that we derived using the linear simulator is not at all accurate concerning the filtering characteristics. It maybe just shows the tendency of the filter - if the amplifier does not "see" the optimum load, by definition the output power will be less, otherwise the load wouldnt be optimum. But we dont know the amount of reduction in the output power.
Is all that true, or am I seriously missing something??
We also know that the amplifier in NOT linear (something like class C for example). We want to use the amplfier in a narrow band system, so we try to match the amplifier only in this narrow band of frequncies in order to obtain sufficient power tranfer to the load. We must also not be disturbing other bands, so we have to employ filterring. Suppose we decide to design a reflective type filter, that reflects the energy in the stopband back to the source.
We take our LINEAR simulator and design such a matching network and filter, and indeed we have an almost perfect match at the frequency of our band, and great missmatch losses at the stopband-->which means the stopband is efficiently filtered.
IF the amplifier was LINEAR,and if we examined the plot of S21 vs freq and found that at xxxMHz(in stopband) it is -30dB, we could confidently say that this frequency is attenuated by 30dB. Is that correct?
However, our amplifier is NOT a linear device, so a possible mismatch of 30dB (calculated using LINEAR theory) doesnt mean that the amplifier will deliver 30dB less power than that it would deliver if it had an optimum load connected. What I want to say is that (if for example the optimum load values were derived using load pull analysis) it could be possible for the amplifier to give 20dBm to a load of 20+j30, 19.5dBm to a load of 10+j5, 19dBm to 1-j20 (and so on), which is totally uncorrelated with the linear results...
So , the plot that we derived using the linear simulator is not at all accurate concerning the filtering characteristics. It maybe just shows the tendency of the filter - if the amplifier does not "see" the optimum load, by definition the output power will be less, otherwise the load wouldnt be optimum. But we dont know the amount of reduction in the output power.
Is all that true, or am I seriously missing something??
