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Yes , it is stable at 100 Mhz, as at 100M, the phase margin is around +80deg. So immaterial of the value of the gain, the output will be stable at 100Mhz.
CANNOT BE DECIDED. Whether the system is stable or not, cannot be decided on the basis of phase plot only. You must provide the gain plot as well.
If the gain plot cuts the 0 dB line BEFORE the phase difference (as compared to 0 Hz) is greater than 180 degree, the system is stable. Otherwise, it is unstable.
This is b/c the system becomes a positive feedback system for those frequencies for which gain > 0 dB and phase difference > 180 degrees.
For your system, let's assume that the gain plot crosses the 0 dB line at 1 MHz. Then you system will be stable, because the phase difference (as compared to the phase at 0 Hz) is less than 180 degrees.
Now assume that the gain plot crosses the 0 dB line at 20 Mhz. Now the system will be unstable. This is because if somehow, a frequency component for which gain > 0 dB and phase > 180 degree were to enter the system (for example, due to ambient noise)..the system would behave as a positive feedback system for that frequency component, causing it to remain increasing in amplitude, until the whole system either saturates or oscillator. Either way, it's unstable.
Now assume that the gain plot crosses the 0 dB line at 20 Mhz. Now the system will be unstable. This is because if somehow, a frequency component for which gain > 0 dB and phase > 180 degree were to enter the system (for example, due to ambient noise)..the system would behave as a positive feedback system for that frequency component, causing it to remain increasing in amplitude, until the whole system either saturates or oscillator. Either way, it's unstable.
I have meet the same problem.
my question is:
1. usually the phase is 0 at low frequency, but why is it 180 at low frequency?
2. why "assume that the gain plot crosses the 0 dB line at 20 Mhz. Now the system will be unstable. "? the phase-margin is defined as 180+phase[A(s)], then the phase margin at 20MHz is about 130, why is is unstable?
Hi
Yes, it is true.
there is a positive feedback. but positive feedback can be stable.
flysnows said:
my question is:
1. usually the phase is 0 at low frequency, but why is it 180 at low frequency?
2. why "assume that the gain plot crosses the 0 dB line at 20 Mhz. Now the system will be unstable. "? the phase-margin is defined as 180+phase[A(s)], then the phase margin at 20MHz is about 130, why is is unstable?
Yes. I agree. you are right. For eg. I've seen many filter ckts. which employ both negative and positive feedback (the amount of negative feedback (1+Aβ) > the amount of +ve f/b; and thus +ve feedback is counteracted by the negative f/b).
However, IN MOST SYSTEMS, if your negative feedback path becomes a positive feedback path, due to the phase shift of the output signal....the system DOES become unstable, b/c there is no reduction in the ever-increasing input signal.
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