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High Q peak in frequency response means what in time domain?

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1

$begingroup$

Reading Linear Circuit Transfer Functions and one of the graphs got me curious.

I've recreated the circuit (series RLC) and plotted the frequency response for a Q of 7.

We have a peak of ~16.3 dB when Q is 7 @ 10Khz.

Can this value be used (16.3 dB) to accurately predict something in the time domain - such as the value of Q or how long the oscillatory decay would take, the amplitude of the oscillations etc.. ?

Added in case its relevent

passive-networks frequency-response

share|improve this question

edited 3 hours ago

efox29

asked 5 hours ago

efox29efox29

8,06953481

$endgroup$

• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  How did you measure the decay and value vs Q on this example?"
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  @SunnyskyguyEE75 I don't fully understand the question. I caculated the values for my R L and C to give me a Q = 0.5 and Q = 7 (green and blue respectively). In this case, I know ahead of time, the Q and f because its what I used to calculate R, L and C
  $endgroup$
  – efox29
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  because the Zreal=Zreactive for Q=1 the apparent voltage amplitude from phasor current is sqrt (1+1) = sqrt(2) so for Q>>1 it equals gain , try Q=1
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  Did you get an ringing T asymptote of about 300us for 7 ?. So if T=300us = 1/(2πΔf) or Δf= then 530Hz yet Δf=fo/Q = 10k/7=1.43k
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  

  
  
  
  

add a comment | 

1

$begingroup$

Reading Linear Circuit Transfer Functions and one of the graphs got me curious.

I've recreated the circuit (series RLC) and plotted the frequency response for a Q of 7.

We have a peak of ~16.3 dB when Q is 7 @ 10Khz.

Can this value be used (16.3 dB) to accurately predict something in the time domain - such as the value of Q or how long the oscillatory decay would take, the amplitude of the oscillations etc.. ?

Added in case its relevent

passive-networks frequency-response

share|improve this question

edited 3 hours ago

efox29

asked 5 hours ago

efox29efox29

8,06953481

$endgroup$

• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  How did you measure the decay and value vs Q on this example?"
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  @SunnyskyguyEE75 I don't fully understand the question. I caculated the values for my R L and C to give me a Q = 0.5 and Q = 7 (green and blue respectively). In this case, I know ahead of time, the Q and f because its what I used to calculate R, L and C
  $endgroup$
  – efox29
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  because the Zreal=Zreactive for Q=1 the apparent voltage amplitude from phasor current is sqrt (1+1) = sqrt(2) so for Q>>1 it equals gain , try Q=1
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  Did you get an ringing T asymptote of about 300us for 7 ?. So if T=300us = 1/(2πΔf) or Δf= then 530Hz yet Δf=fo/Q = 10k/7=1.43k
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  

  
  
  
  

add a comment | 

$begingroup$

Reading Linear Circuit Transfer Functions and one of the graphs got me curious.

I've recreated the circuit (series RLC) and plotted the frequency response for a Q of 7.

We have a peak of ~16.3 dB when Q is 7 @ 10Khz.

Can this value be used (16.3 dB) to accurately predict something in the time domain - such as the value of Q or how long the oscillatory decay would take, the amplitude of the oscillations etc.. ?

Added in case its relevent

passive-networks frequency-response

share|improve this question

edited 3 hours ago

efox29

asked 5 hours ago

efox29efox29

8,06953481

$endgroup$

share|improve this question

edited 3 hours ago

efox29

asked 5 hours ago

efox29efox29

8,06953481

share|improve this question

edited 3 hours ago

efox29

asked 5 hours ago

efox29efox29

8,06953481

asked 5 hours ago

efox29efox29

8,06953481

asked 5 hours ago

efox29efox29

8,06953481

1 Answer
1

active

oldest

votes

3

$begingroup$

Q is (among other definitions) the voltage gain at resonance, and a voltage gain of 7 times is $$20 * log(7) = 16.9dB$$ which seems close enough as your cursor is clearly not actually on resonance (phase would be -90 not -93). So dB of resonant gain is trivially converted to or from Q.

Q gives you risetime and whether the circuit is over/under or critically damped in the time domain, as well as how well damped the ringing in an under damped circuit is.

share|improve this answer

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

$endgroup$

• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  It's always something simple. This has given me a items to explore deeper into.
  $endgroup$
  – efox29
  4 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  I though Av= √1+Q² so when Q=1 Av=1.414 or +3dB and for LPF the f-3dB breakpoints are not symmetrical about peak unlike a simple BPF so your Q=6.6 ( close enuf)
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  

add a comment | 

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3

$begingroup$

Q is (among other definitions) the voltage gain at resonance, and a voltage gain of 7 times is $$20 * log(7) = 16.9dB$$ which seems close enough as your cursor is clearly not actually on resonance (phase would be -90 not -93). So dB of resonant gain is trivially converted to or from Q.

Q gives you risetime and whether the circuit is over/under or critically damped in the time domain, as well as how well damped the ringing in an under damped circuit is.

share|improve this answer

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

$endgroup$

• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  It's always something simple. This has given me a items to explore deeper into.
  $endgroup$
  – efox29
  4 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  I though Av= √1+Q² so when Q=1 Av=1.414 or +3dB and for LPF the f-3dB breakpoints are not symmetrical about peak unlike a simple BPF so your Q=6.6 ( close enuf)
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  

add a comment | 

3

$begingroup$

Q is (among other definitions) the voltage gain at resonance, and a voltage gain of 7 times is $$20 * log(7) = 16.9dB$$ which seems close enough as your cursor is clearly not actually on resonance (phase would be -90 not -93). So dB of resonant gain is trivially converted to or from Q.

Q gives you risetime and whether the circuit is over/under or critically damped in the time domain, as well as how well damped the ringing in an under damped circuit is.

share|improve this answer

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

$endgroup$

• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  It's always something simple. This has given me a items to explore deeper into.
  $endgroup$
  – efox29
  4 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  I though Av= √1+Q² so when Q=1 Av=1.414 or +3dB and for LPF the f-3dB breakpoints are not symmetrical about peak unlike a simple BPF so your Q=6.6 ( close enuf)
  $endgroup$
  – Sunnyskyguy EE75
  3 hours ago
  
  

  
  
  
  

add a comment | 

$begingroup$

Q is (among other definitions) the voltage gain at resonance, and a voltage gain of 7 times is $$20 * log(7) = 16.9dB$$ which seems close enough as your cursor is clearly not actually on resonance (phase would be -90 not -93). So dB of resonant gain is trivially converted to or from Q.

Q gives you risetime and whether the circuit is over/under or critically damped in the time domain, as well as how well damped the ringing in an under damped circuit is.

share|improve this answer

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

$endgroup$

share|improve this answer

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

answered 4 hours ago

Dan MillsDan Mills

12.2k11225

answered 4 hours ago

Dan MillsDan Mills

12.2k11225