User:Msiddalingaiah/Oscillator Analysis

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References

Maxim Crystal Oscillator Analysis

Colpitts Oscillator

Ignoring the inductor, the input impedance at the base of a common collector circuit can be written as

${\displaystyle Z_{in}={\frac {v_{1}}{i_{1}}}}$ 

Where ${\displaystyle v_{1}}$  is the input voltage and ${\displaystyle i_{1}}$  is the input current. The voltage ${\displaystyle v_{2}}$  is given by

${\displaystyle v_{2}=i_{2}Z_{2}}$ 

Where ${\displaystyle Z_{2}}$  is the impedance of ${\displaystyle C_{2}}$ . The current flowing into ${\displaystyle C_{2}}$  is ${\displaystyle i_{2}}$ , which is the sum of two currents:

${\displaystyle i_{2}=i_{1}+i_{s}}$ 

Where ${\displaystyle i_{s}}$  is the current supplied by the transistor. ${\displaystyle i_{s}}$  is a dependent current source given by

${\displaystyle i_{s}=g_{m}\left(v_{1}-v_{2}\right)}$ 

Where ${\displaystyle g_{m}}$  is the transconductance of the transistor. The input current ${\displaystyle i_{1}}$  is given by

${\displaystyle i_{1}={\frac {v_{1}-v_{2}}{Z_{1}}}}$ 

Where ${\displaystyle Z_{1}}$  is the impedance of ${\displaystyle C_{1}}$ . Solving for ${\displaystyle v_{2}}$  and substituting above yields

${\displaystyle Z_{in}=Z_{1}+Z_{2}+g_{m}Z_{1}Z_{2}}$ 

The input impedance appears as the two capacitors in series with an interesting term, ${\displaystyle R_{in}}$  which is proportional to the product of the two impedances:

${\displaystyle R_{in}=g_{m}\cdot Z_{1}\cdot Z_{2}}$ 

If ${\displaystyle Z_{1}}$  and ${\displaystyle Z_{2}}$  are complex and of the same sign, ${\displaystyle R_{in}}$  will be a negative resistance. If the impedances for ${\displaystyle Z_{1}}$  and ${\displaystyle Z_{2}}$  are substituted, ${\displaystyle R_{in}}$  is

${\displaystyle R_{in}={\frac {-g_{m}}{\omega ^{2}C_{1}C_{2}}}}$ 

If an inductor is connected to the input, the circuit will oscillate if the magnitude of the negative resistance is greater than the resistance of the inductor and any stray elements. The frequency of oscillation is as given in the previous section.

For the example oscillator above, the emitter current is roughly 1 mA. The transconductance is roughly 40 mS. Given all other values, the input resistance is roughly

${\displaystyle R_{in}=-30\ \Omega }$ 

This value should be sufficient to overcome any positive resistance in the circuit. By inspection, oscillation is more likely for larger values of transconductance and smaller values of capacitance.

If the two capacitors are replaced by inductors and magnetic coupling is ignored, the circuit becomes a Hartley oscillator. In that case, the input impedance is the sum of the two inductors and a negative resistance given by:

${\displaystyle R_{in}=-g_{m}\omega ^{2}L_{1}L_{2}}$ 

In the Hartley circuit, oscillation is more likely for larger values of transconductance and larger values of inductance.

Pierce Oscillator

In a common emmitter circuit, ${\displaystyle Z_{1}}$  and ${\displaystyle Z_{2}}$  are the feedback (collector to base) and output (collector to ${\displaystyle V_{cc}}$ ) impedances respectively. Transistor impedance will be ignored initially. Input impedance at the base terminal is:

${\displaystyle Z_{in}={\frac {v_{1}}{i_{1}}}}$ 

Where ${\displaystyle v_{1}}$  is the input voltage and ${\displaystyle i_{1}}$  is the input current. The voltage ${\displaystyle v_{2}}$  is given by

${\displaystyle v_{2}=i_{2}Z_{2}}$ 

Where ${\displaystyle Z_{2}}$  is the impedance of ${\displaystyle C_{2}}$ . The current flowing into ${\displaystyle C_{2}}$  is ${\displaystyle i_{2}}$ , which is the sum of two currents:

${\displaystyle i_{2}=i_{1}+i_{s}}$ 

Where ${\displaystyle i_{s}}$  is the current supplied by the transistor. ${\displaystyle i_{s}}$  is a dependent current source given by

${\displaystyle i_{s}=-g_{m}v_{1}}$ 

Where ${\displaystyle g_{m}}$  is the transconductance of the transistor. The input current ${\displaystyle i_{1}}$  is given by

${\displaystyle i_{1}={\frac {v_{1}-v_{2}}{Z_{1}}}}$ 

Solving for ${\displaystyle v_{2}}$  and substituting above yields:

${\displaystyle Z_{in}={\frac {Z_{1}+Z_{2}}{1+g_{m}Z_{2}}}}$ 

Capacitor-Inductor-Capacitor Model

If ${\displaystyle Z_{1}}$  is an inductor, ${\displaystyle Z_{2}}$  is a capacitor, and frequencies above resonance:

${\displaystyle |Z_{1}|>|Z_{2}|}$ 

${\displaystyle Z_{1}=-kZ_{2}}$  for ${\displaystyle k>1}$ 

${\displaystyle Z_{2}={\frac {-Z_{1}}{k}}}$ 

${\displaystyle Z_{1}=jX}$ 

Substituting ${\displaystyle Z_{1}}$  and ${\displaystyle Z_{2}}$ :

${\displaystyle Z_{in}={\frac {-g_{m}X^{2}(k-1)}{k^{2}+g_{m}^{2}X^{2}}}+{\frac {jX(k^{2}-k)}{k^{2}+g_{m}^{2}X^{2}}}}$ 

The input impedance appears as a negative resistance in series with an inductor.

Inductor-Capacitor-Inductor Model

If ${\displaystyle Z_{1}}$  is a capacitor, ${\displaystyle Z_{2}}$  is an inductor, and frequencies below resonance:

${\displaystyle |Z_{1}|>|Z_{2}|}$ 

${\displaystyle Z_{1}=-kZ_{2}}$  for ${\displaystyle k>1}$ 

${\displaystyle Z_{2}={\frac {-Z_{1}}{k}}}$ 

${\displaystyle Z_{1}=-jX}$ 

${\displaystyle Z_{in}={\frac {-g_{m}X^{2}(k-1)}{k^{2}+g_{m}^{2}X^{2}}}-{\frac {jX(k^{2}-k)}{k^{2}+g_{m}^{2}X^{2}}}}$ 

The input impedance appears as a negative resistance in series with a capacitor.

Wien Bridge Oscillator

 

Input admittance analysis

The analysis of the circuit will be performed by looking at the circuit from the negative impedance viewpoint. If a voltage source is applied directly to the input of an ideal amplifier with feedback, the input current will be:

${\displaystyle i_{in}={\frac {v_{in}-v_{out}}{Z_{f}}}}$ 

Where ${\displaystyle v_{in}}$  is the input voltage, ${\displaystyle v_{out}}$  is the output voltage, and ${\displaystyle Z_{f}}$  is the feedback impedance. If the voltage gain of the amplifier is defined as:

${\displaystyle A_{v}={\frac {v_{out}}{v_{in}}}}$ 

And the input admittance is defined as:

${\displaystyle Y_{i}={\frac {i_{in}}{v_{in}}}}$ 

Input admittance can be rewritten as:

${\displaystyle Y_{i}={\frac {1-A_{v}}{Z_{f}}}}$ 

For the Wien bridge, Z_f is given by:

${\displaystyle Z_{f}=R+{\frac {1}{j\omega C}}}$ 

${\displaystyle Y_{i}={\frac {\left(1-A_{v}\right)\left(\omega ^{2}C^{2}R+j\omega C\right)}{1+\left(\omega CR\right)^{2}}}}$ 

If ${\displaystyle A_{v}}$  is greater than 1, the input admittance can be thought as of a negative resistance in parallel with an inductance. The inductance is:

${\displaystyle L_{in}={\frac {\omega ^{2}C^{2}R^{2}+1}{\omega ^{2}C\left(A_{v}-1\right)}}}$ 

As a capacitor with the same value of C is placed in parallel with the input, the circuit has a natural resonance at:

${\displaystyle \omega ={\frac {1}{\sqrt {L_{in}C}}}}$ 

Substituting and solving for inductance yields:

${\displaystyle L_{in}={\frac {R^{2}C}{A_{v}-2}}}$ 

If ${\displaystyle A_{v}}$  is chosen to be 3:

${\displaystyle L_{in}=R^{2}C}$ 

Substituting this value yields:

${\displaystyle \omega ={\frac {1}{RC}}}$ 

Or:

${\displaystyle f={\frac {1}{2\pi RC}}}$ 

Similarly, the input resistance at the frequency above is:

${\displaystyle R_{in}={\frac {-2R}{A_{v}-1}}}$ 

For ${\displaystyle A_{v}}$  = 3:

${\displaystyle R_{in}=-R}$ 

The resistor placed in parallel with the amplifier input cancels some of the negative resistance. If the net resistance is negative, amplitude will grow until clipping occurs. Similarly, if the net resistance is positive, oscillation amplitude will decay. If a resistance is added in parallel with exactly the value of R, the net resistance will be infinite and the circuit can sustain stable oscillation at any amplitude allowed by the amplifier.

Notice that increasing the gain makes the net resistance more negative, which increases amplitude. If gain is reduced to exactly 3 when a suitable amplitude is reached, stable, low distortion oscillations will result. Amplitude stabilization circuits typically increase gain until a suitable output amplitude is reached. As long as R, C, and the amplifier are linear, distortion will be minimal.