Drop in DC current in Class AB amplifier

Hi,

your values have no meaning for as as long as we don´t see your design.

We don´t even know what load you use.

At these frequencies you may have reflections, resonances and so on that let the current move up and down.

Klaus

This is the circuit. I used SRFT to design the matching network. Load pull simulation was done for each frequency to obtain the load and was around 24+3j ohms in the band.

HI,

I don´t think it´s Class AB. But I´m no expert in RF design.

In the NF world a class AB amplifier needs at least two transistors.

Klasu

In RF amplifier techniques, single transistor "class SB" output stages are commonly known. These are amplifiers with bias current and linear (class A) operation up to a certain power level. Above this level, transistor current is clipped at zero. Assuming linear transistor V/I characteristic, we would expect rising average DC current in class B range. Current is also soft clipped at maximum due to saturation, causing opposite behavior. Actual characteristic is however non-linear, so real behaviour is more complicated. Also varying impedance of output matching circuit can make the behavior frequency dependent.

A nonlinear broadband amplifier is more or less impossible. It generates harmonics, therefore output signal spectrum is different from Iinput. Typically single transistor AB amplifiers use a resonant tank and are not broadband.

Two images copied from Steve C. Cripps,
Advanced Techniques in RF Power
Amplifier Design illustrating class AB behaviour:

It seems related to Output Matching Circuit. This circuit transfers an amount of current well to the load at some frequencies, it cannot transfer at some other frequencies.
Therefore average current shows some differences for some of them. There might also be poor harmonic rejection and badly designed supply branch.
0.8-3GHz is already a pretty wide bandwidth so expecting same performance or behavior may cause a disappointment.
You should check out harmonic currents through output matching circuit and get an idea about the efficiency of output matching circuit.

The PA's IMD3 level, using two-tone or modulated signal (especially in class-AB amplifiers) have so named "sweet spots" in their characteristic vs output power.
This may the reason getting various (up and down) collector/drain currents when sweep the output power.
Harmonic frequencies (and the PA load at those frequencies) play an important role of the IMD3 levels.