The output amplitude of the C class amplifier I designed has a larger amplitude than the voltage source. How did this happen?

Question

I designed a class C amplifier. I used a signal generator for the input signal. For the resonance circuit, I used a 3.3uH coil and a 480pF capacitor. The transistor is BC547-C.

The resonance frequency for these values is 3.99 MHz. Due to the tolerance values of the circuit elements and the use of breadboard, the maximum output amplitude was realized at 3.45MHz. This is an expected situation.

There are three questions that bother me.

1. How did the amplitude of the output become greater than the source voltage? As you increase the coil value (for example 10mH,) the amplitude of the output becomes larger at the resonant frequency.

2. The output resistance of the signal generator is 50 ohms. Impedance matching is essential for maximum power transfer. For this, I calculated the input resistance of the transistor. If I'm not wrong, I calculated the Rpi resistor as 480ohm. The calculation is available in the picture. I wanted to select the base resistance small to bring the input resistance closer to 50 ohms. I tried values like 100ohm, 330ohm, etc. However, the maximum output amplitude was achieved when the base resistance was 1k. Why did the maximum amplitude occur with thr 1k value?

3. If the amplitude of the input signal is less than 0.7 volts, this circuit would not work because the transistor needs about 0.7V for the base to be triggered or to conduct. How can this problem be solved when the signal amplitude is below 0.7 volts? How can the circuit be operated?

edit:LTSpice simulation image.very different with results from real experiment.

Answer 1

How did the amplitude of the output become greater than the source voltage?

• The collector is connected to the DC voltage source via an inductor
• This means that the average voltage level at the collector equals the DC voltage source
• This is all about inductors; if you don't follow this bit then go and study inductors and inductor volt-seconds
• OK, it may be a few millivolts lower due to collector current and non-idealities in the inductor
• Assume it's the same for very practical reasons
• Because DC collector voltage equals the supply voltage, any AC waveform on the collector will "peak" higher than the DC supply and "valley" lower than the DC supply. This will be symmetrical (go study inductors and volt-seconds)
• The lowest undistorted level is nearly 0 volts (say 0.5 volts)
• The highest undistorted level is nearly twice the supply voltage (say 2*Vcc - 0.5 volts)
• Maximum p-p output voltage is nearly twice the supply DC voltage

Why did the maximum amplitude occur with the 1k value?

Because you never accounted for something - try simulating to see what you get and don't forget about the output impedance of the signal generator and miller capacitance of the transistor.

How can this problem be solved when the signal amplitude is below 0.7 volts? How can the circuit be operated?

Operate it as a linear class A amplifier.

Answer 2

How did the amplitude of the output become greater than the source voltage?

For this, I calculated the input resistance of the transistor. If I'm not wrong, I calculated the Rpi resistor as 480ohm.

If the amplitude of the input signal is less than 0.7 Volts, this circuit would not work.

Some pictures to see that it works. Almost sinusoidal. (Others to come).
It can work at a low level, although BJT is not really "on" as in digital circuits.
(See Ebers-Moll at "low-level" input ...).

Pictures : for generator amplitude input < 300 mV peak
One do not forget that an LC tank has "infinite" impedance at resonance.

NB: The addition of L2 and R4 (as well as the corresponding load to an oscilloscope probe x10) does not seem to have a "significant" impact on the curves resulting from the previous simulations, apart from a "small" lowering of the frequency of work.

AC Analysis to see "resonance" frequency

Simulated input impedance calculation
Input impedance should be ~ 800 Ohm.

Transient analysis to see behavior -> amplitude output ... Current driven. See low Ib current.

See the bigger current into the inductor.

And for some other levels