Bad amplifier output
550j = j*2*pi(470*10^6)L
L = 186 nH
X_L = j*2*pi(100*10^6)(1.86*10^-7) = 117 ohms @ 100 MHz
I can't use the monolithic bias tee minicircuits makes because of budget constraints. Any help figuring this out would be greatly appreciated.
Hi aloishis89
I hope you know your amplifier's out put impedance will be related to the value of XL of that inductor . and as it appears value of your capacitor seems high for that range of frequency . hence that DC component it usual . we have a grate formula to select capacitor to remove DC in our desired range : t/0.4Z hence value your capacitor should be reduced . for preventing some of these problems most of the times these stages will be used as a low power stage and then a buffer or a PA will be added . like a high impedance amplifier . e.g a class C or a simple class E amplifier . but if you select your capacitor properly you won't have any problem .
Best Wishes
Goldsmith
Thanks goldsmith. Could you clarify that formula for me? I'm not sure what the 't' is. Also, which capacitor are you referring to as being too large? C80 or the parallel combination of C81, C82, and C83?
Yes; the 100nF capacitors C79 & C80 are rather large.
You might also look at L21. Chokes are complex devices and should be tested at the frequencies at which they are proposed to operate.
Just calculating the impedance is not good enough.
See here;
http://www.cliftonlaboratories.com/s..._inductors.htm
and other information that Google will find.
Your L21 will have a SRF at some frequency; if it's close to or below your amplifier's operating frequency it will give problems.
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Sorry; I didn't explain the capacitor value.
A very large capacitor such as you have for C79 & C80 will pass frequencies down to very low frequency; a smaller-value capacitor will act as a crude high-pass filter and limit unwanted lower frequencies entering your amplifier.
Mini Circuits use a rule-of-thumb formula; C (the DC block/coupling capacitor) = 47000pF/Frequency (MHz).
So, for your amplifier's lowest frequency of 470 MHz, C = 47000/470 = 100 pF.
Remember that this is a rule-of-thumb, not a fixed rule, but it works!
I have used PSA4-5043+ without problems; I was surprised to achieve noise figure of < 0.5 dB over band.
I observed, however, that some 3V regulators like LP2950CZ-3 generated oscillations and disturbed the operation of those nice LNAs. I had to connect a 10 uF capacitor across the LP terminals to get a clean 3V output.
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The spectrum peaks shown in your picture apparently come from external sources and the ADG device. If you need a clean spectrum, you must use a suitable band-pass filter BEFORE the PSA LNA, and enclose the circuits before it to prevent external FM and local TV signals from getting into PSA. Remember, it is an extremely low noise device. The more sensitive you make the receiver front-end, the more vulnerable it is to interference.
Thanks for the help everybody, I really appreciate it. For the inductor, L21, I found one that Coilcraft makes that is 180 nH and has an SRF of 1.08 GHz. Could that work? Since the rest of my system is 50 ohms, the impedance looking in to the amp and bias tee will be different, so would a buffer amp be a good idea there or can I pick capacitor and inductor values that will look like 50 ohms?
Hi
Sorry for the delayed answer .
t? t is time ! 1/F !
And about which capacitor my mean is out put capacitor .
Best Wishes
Goldsmith
Yes, 180nH with SRF 1G surely can work for 600MHz.