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  3. LC parallel circuit at resonant frequency

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LC parallel circuit at resonant frequency

baristaskin
baristaskin over 10 years ago

Dear All,

I am trying to simulate a simple LC parallel circuit when it is drived by a voltage source.

I'm expecting the current of the voltage source V1 to get smaller as its frequency gets closer to the resonant frequency.

When I simulate this circuit at the resonant frequency, with spectre default values, I get:

I tried to play around with the following parameters:

maxstep, reltol, vabstol, iabstol

without success.

My question is: how do I setup Spectre in order to get consistent and accurate results?

What I expect to see is a sine-shaped current signal with no DC value.

I'm including the netlist of the simulation shown above:

// Generated for: spectre
// Generated on: Mar 2 16:11:27 2015
// Design library name: paper3
// Design cell name: LC_osc
// Design view name: schematic
simulator lang=spectre
global 0
parameters _EXPR_8=1.986858915135295e-08 C=1p L=100n vdd=1 \
freqC=503.30696M cycles=10 L_IC=-sqrt(C/L)*vdd/2

// Library name: paper3
// Cell name: LC_osc
// View name: schematic
L1 (Vin 0) inductor l=L r=1a ic=0
V1 (Vin 0) vsource type=sine freq=freqC ampl=vdd/2 sinephase=90 sinedc=0
C1 (Vin 0) capacitor c=C ic=vdd/2
simulatorOptions options reltol=1e-3 vabstol=1e-6 iabstol=1e-12 temp=27 \
tnom=27 scalem=1.0 scale=1.0 gmin=1e-12 rforce=1 maxnotes=5 maxwarns=5 \
digits=5 cols=80 pivrel=1e-3 sensfile="../psf/sens.output" \
checklimitdest=psf
tran tran stop=_EXPR_8 errpreset=conservative write="spectre.ic" \
writefinal="spectre.fc" annotate=status maxiters=5
finalTimeOP info what=oppoint where=rawfile
modelParameter info what=models where=rawfile
element info what=inst where=rawfile
outputParameter info what=output where=rawfile
designParamVals info what=parameters where=rawfile
primitives info what=primitives where=rawfile
subckts info what=subckts where=rawfile
save Vin V1:p L1:1
saveOptions options save=allpub

 

Thank you in advance.

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  • ShawnLogan
    ShawnLogan over 10 years ago

    Dear baristaskin,

    I'm happy to read that it helped you - thank you for letting me know!

    In an actual circuit, can a voltage source be used as the sustaining amplifier? My idea is to use the current source in the simulator in order to get power numbers and whatnot, but to design and use an op amp for the fabricated IC.

    Any form of a sustaining amplifier can be used as long as it satisfies the condition for sustained oscillation. In other words. If you place a current source across the terminals of the sustaining amplifier that will connect to your resonator, it's input impedance must be equal and opposite to that of the resonator in steady state. The choice of sustaining amplifier after that condition is met is determined by its parameters - such as the sustaining amplifier's input impedance sensitivity to temperature and supply voltage; its limiting characteristics; its power and area; and its negative resistance characteristics  (i.e. versus frequency as well as margin to the resonator's real impedance).

    Does this make sense? Let me know I misinterpreted your question (again!).

    Shawn

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