Derivation of Floquet Eigenvectors Displacement for Optimal Design of LC Tank Pulsed Bias Oscillators

doi:10.4236/cs.2011.24043

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Circuits and Systems, 2011, 2, 311-319

doi:10.4236/cs.2011.24043 Published Online October 2011 (http://www.scirp.org/journal/cs)

Derivation of Floquet Eigenvectors Displacement for

Optimal Design of LC Tank Pulsed Bias Oscillators

Stefano Perticaroli, Nikend Luli, Fabrizio Palma

Department of Information Engineering, Electronics and Telecommunications,

Sapienza Università di Roma, Rome, Italy

E-mail: {perticaroli, palma}@die.uniroma1.it

Received June 13, 2011; revised July 3, 2011; accepted July 22, 2011

Abstract

The paper presents an approximated and compact derivation of the mutual displacement of Floquet eigen-

vectors in a class of LC tank oscillators with time varying bias. In particular it refers to parallel tank oscilla-

tors of which the energy restoring can be modeled through a train of current pulses. Since Floquet eigenvec-

tors are acknowledged to give a correct decomposition of noise perturbations along the stable orbit in oscil-

lator's space state, an analytical and compact model of their displacement can provide useful criteria for de-

signers. The goal is to show, in a simplified case, the achievement of oscillators design oriented by eigen-

vectors. To this aim, minimization conditions of the effect of stationary and time varying noise as well as the

contribution of jitter noise introduced by driving electronics are deduced from analytical expression of ei-

genvectors displacement.

Keywords: Floquet Eigenvectors Noise Decomposition, Pulsed Bias Oscillator, Oscillator Phase Noise

1. Introduction

Noise decomposition through Floquet eigenvectors is

widely acknowledged to be a correct methodology for the

analytical treatment of phase noise in electronic oscilla-

tors [1]. For this reason, numerical algorithms which rely

also on the Floquet eigenvectors have been developed in

order to obtain accurate prediction of power density spec-

trum (PDS) around the fundamental oscillation frequency.

A well known example is found in the commercial simu-

lator SpectreRF that computes Floquet eigenvectors from

the shooting matrix and use them as a theoretical based

correction for the PNoise analysis [2]. Although elec-

tronic simulators offer results in good agreement with

effective measurements, they cannot be used to infer gen-

eral properties of the underlying system. Despite the great

amount of work presented even recently in literature [3,

4], since the pioneeristic work of Kaertner [5] and the

latter efforts accomplished by Hajimiri-Lee [6], Demir [7,

8] and Buonomo [9] not many significant theoretical con-

tributions have really extended the capability to develop

innovative techniques in the design of oscillators systems.

In authors opinion the innovation should be founded on

derivation of architecture-related expressions of Floquet

eigenvectors [10], leading to a proper design methodol-

ogy. This approach has been limited in the past by the fact

that, also in relatively simple cases, Floquet eigenvectors

cannot be obtained in analytical closed form.

Mutual displacement among eigenvectors along the pe-

riod of oscillation regulates indeed how noise perturba-

tions affect the spectral purity of oscillator system. In

particular projections of noise on the eigenvectors deter-

mine the PDS of the oscillator [11]. We notice that mu-

tual displacement depends in general on the quality factor

of tank and on the way the lost energy is restored, i.e. on

the chosen architecture. Even if in recent years several

new architectural solutions were proposed for the reduc-

tion of phase noise in CMOS technologies [12-15], none

of them was justified on eigenvectors based considera-

tions. In particular, to knowledge of the authors, in litera-

ture there is no attempt to establish a direct relationship

between Floquet eigenvectors and circuit parameters for a

certain class of oscillators.

In this paper we present an analytical derivation of

mutual displacement of Floquet eigenvectors and of their

relationship with design parameters in the class of the LC

tank oscillators with pulsed bias. First, we propose to in-

troduce a parametrical model for the pulsed bias concept.

Then we extend Floquet theory for the class in study in

order to analyze noise dynamics and thus to optimize

S. PERTICAROLI ET AL.

312

oscillators implemented through architectures with time

varying bias. Finally we validate the proposed analysis

and optimization criteria through the comparison with

numerical results from a dedicated Matlab simulator of

introduced model.

2. Simplified Model of LC Tank Pulsed Bias

Oscillator

In order to characterize the class of LC tank oscillators

with pulsed current bias we adopt the simplified parallel

RLC model in Figure 1: it presents only two state vari-

ables, corresponding to the capacitor voltage VC and the

inductor current IL of tank. This assumption can be seen

as a rather drastic simplification for a model of a real

oscillator, nevertheless, if pulsed bias circuitry does not

introduce parasitic comparable to those in tank, the addi-

tional state variables can be neglected.

In this model the energy refilling is demanded to

pulsed current generator i(t) which is controlled, in par-

ticular, by the capacitor voltage VC. Crossing of a thresh-

old |Vth| by the capacitor voltage, occurring at time de-

fined as Tth, triggers the accumulation of a fixed delay T1.

After this delay the current generator is turned on for a

time T2 at fixed amplitude Imax. The turning on and off

are assumed to be instantaneous, thus application of the

ideal pulses gives rise to non derivable points of the ca-

pacitor voltage. In order to clarify the aforementioned

timings and parameters of the model, a sketch of the

generator current and of the resulting capacitor voltage

waveform is reported in Figure 2.

The differential algebraic equations (DAE) describing

dynamic of the proposed model is reported in Equation (1).



 



11 1

()

Vt RC Cit



 



 







 



 

 











(1)

We choose to not explicitly express the large signal

dependence of i(t) as a function of VC, since in this paper

we are interested in a variational analysis for the study of

noise only. However the existence of a stable orbit can be

easily proved by means of mathematical approach for the

analysis of nonlinear systems (e.g. the describing function

Figure 1. Model of the simplified LC tank pulsed bias oscil-

lator.

Figure 2. Sketch of capacitor voltage and current pulse of

the generator in time.

technique) and will be not reported here.

In Figure 3(a) sketch of the stable orbit and the projec-

tions onto eigenvectors of superimposed noise perturba-

tion b at certain time instant are reported. Due to the

adopted symmetrical model, every half of the orbit can be

subdivided into two different portion delimited by dashed

lines in Figure 3. A first one corresponds to the RLC

dumped evolution only and the second one corresponds to

the evolution when the refilling current pulse is also

active.

3. Floquet Theory for the Study of Noise

Floquet theory describes the periodical linear time vary-

ing (LPTV) response of oscillators systems to small per-

turbations superimposed on the stable oscillation orbit.

Floquet eigenvectors are usually extracted from Mono-

Figure 3. Sketch of the stable orbit and of the projections

onto eigenvectors of superimposed noise perturbation b at

certain time instant. Dashed lines indicate phase portion

when pulsed bias current is active in a half of period.

S. PERTICAROLI ET AL.313

dromy matrix. In general Monodromy matrix is obtained

as the product of sequence of eventually different transi-

tion matrices along one oscillation period. In our treat-

ment Monodromy matrix is calculated by following the

evolution of the state variation vector [vC iL]T in the sys-

tem along the orbit, apart from non derivable points.

Evolution is derived from (1) imposing i(t) = 0 and is

given by



 



vt vt

RC C

it it







 





 



 















, (2)

The state transition matrix Φ(t) of dumped RLC system

(2) results in

  

 

11 12

21 22

ttt















(3)

Every component of (3) can be obtained by direct in-

tegration of (2) and hence assumes the form of dumped

sinusoidal evolution as expressed in Equation (4)



 



 



cos

sin

cos

sin

cos





















 





 











 





(4)

where

12π

222

























 

  



  



 

LC T

QLRCQ

arctgarctgarctg Q

(5)

It has to be noticed that real period T differs in general

from the nominal period Tn as a main effect of the pulsed

bias.

The above described model holds until current pulse

edges are reached. Since at this time instants the capaci-

tor voltage is not derivable, we will need to introduce

Interface matrices [16,17] to properly describe state evo-

lution.

In the simplified adopted model only two Floquet

eigenvectors exist, with two corresponding eigenvalues.

We call “first eigenvector”, u1(t), the one which is tan-

gent to the orbit with unitary eigenvalue and the “second

eigenvector”, u2(t), the one with corresponding eigen-

value lower than 1. Once the evolution of the eigenvec-

tors is available, we may project the perturbation b(t)

multiplying it by inverse eigenvectors. The effect of

noise projection is a state deviation which evolves as the

eigenvector itself and sum in square to further noise pro-

jections along the orbit. Projections depend on the instant

when b(t) is applied, so that the system appears as peri-

odic time variant. In Figure 4(a) sketch of power density

spectrum of the eigenvectors is reported [11]. Contribu-

tion to the PDS of noise projected on the first eigenvec-

tor, can be described by a transfer function with square

modulus 1/ω2, where is the offset with respect to the

fundamental. We notice that at very low offset a cut-off

must be assumed, not reported in the figure, due to

nonlinear behaviour of the system for large values of

phase deviation [7]. Noise projected on the second ei-

genvector can be instead described by a transfer function

with square modulus 1/(γ2

2+ω2), where γ2 is the pole

pulsation related to the second Floquet multiplier.

As a result the main contribution to the overall power

density spectrum at frequencies close to the fundamental

arises from projection on the first eigenvector. On the

contrary contribution arising from the second eigenvec-

tor becomes relevant only at high frequency offsets

(ω>>γ2) due to its low-pass shape with respect to the

fundamental.

Only noise contributions parallel to u2 produce null

contributions on u1 and thus do not increase the phase

noise [1]. Floquet decomposition points out that eigen-

vectors, in general, are not orthogonal. As a result, as-

suming a white noise current generator in parallel to the

RLC resonator, as it will be discussed in next section, a

noise contribution in the direction [1 0]T (the voltage

Figure 4. Sketch of power density spectrum contributions

due to the eigenvectors.

S. PERTICAROLI ET AL.

314

variation axis) applied in correspondence of the voltage

maximum may not yield to a null projection on u1.

These considerations lead to investigate a pulsed bias

strategy, designed to activate the bias only when the pro-

jection of noise related to the biasing electronics on the

first eigenvector is at least around a minimum. Never-

theless a complete evaluation of the proposed architectc-

ture must take into account also the effect of eigenvec-

tors displacement due to the pulsed bias on all the other

noise sources present in the circuit.

As formerly stated, the eigenvectors evolutions are

almost everywhere derived from state transition matrix

of the dumped RLC system except for time instants when

the generator switches on/off. Since an oscillator has no

time reference, in the adopted model we may assume that

at t = 0 the first eigenvector must be equal to u1(0) =

[Vu1(0) Iu1(0)] = k[1 0]T, with null current com-

ponent (an eigenvector can always be defined by means

of a proportionality constant). Until the first discontinu-

ity, occurring at t = Tth + T1, eigenvectors evolutions can

then be described by the following equations normalized

to amplitude of superimposed perturbation

k

 



 



cos

sin

cos

sin

μt

u1 μt

u1 n

μt

uμt

ut== e

It t

ut== e

It t+β

















































(60)

where coefficient F depends on the quality of the tank

and on resonating elements as in (7) and β represents the

phase displacement between eigenvectors.





F= +

(7)

4. Phase Displacement between Eigenvectors

as a Function of Pulse Paramaters

Figures 5 and 6 show a sketch of the evolutions respec-

tively of first and second eigenvector. The effect of turn-

ing on and off of the bias current, taking place at t = Tth

+ T1 and t = Tth + T1 + T2 respectively, corresponds to

discontinuities of eigenvectors states, in direction [1 0]T

(the V voltage variation axis). Due to the introduction of

the Interface matrix theory [16], and as shown in Figure

7, we have to consider that any state variation along each

eigenvector, evolved from t = 0 until Tth, produces a de-

lay t with respect to the crossing of the threshold |Vth|.

The same delay is reported at the time of the turning on

and off of the current generator. The delay is calculated as

Figures 5. Sketch of evolution of the first eigenvector for a

half of the period.

Figures 6. Ske tch of evolution of the second eigenvector for

a half of the period.

Figure 7. Current of the generator in time with delay due to

the variation (a) and additional contributions at the pulse

edges (b).

the ratio of voltage variation to the time derivative of the

capacitor voltage at threshold crossing. Using a smart

notation with subscript J = 1,2 where XJ=1 = 0 and XJ=2 =



, delay for both eigenvectors results in

S. PERTICAROLI ET AL.315



cos

nth J

CtT









 

X

(8)

Implicit voltage variation at numerator ensures dimen-

sional balance in Equation (8). As a result of the delay, at

the pulse edges two additional contributions opposite in

sign sum to the former state variation. Since we are

dealing with a pulsed bias for hypothesis, we now as-

sume T2<<T and then we neglect the relative phase rota-

tion between the pulse edges in both eigenvectors evolu-

tions. As depicted in Figure 5, this allows us to ap-

proximate the effect of the bias current pulse as a unique

discontinuity of the state in direction [0 1]T (the I current

variation axis). We hence calculate discontinuity ampli-

tude for both eigenvectors using (6) and (8) as the sum of

opposite contributions approximating sinusoidal function

for small T2 in



max

Icos









 





nnth

CtT

eTT X

CV F

(9)

The overall state variation, including the effect due to

discontinuities, evolves along a new orbit. The second

part of the evolution can be obtained for both the eigen-

vectors as

 









Acos

Asin

 







 



















μt

Jμt

JnJ J

ut= =

It et+X











(10)

where A and



J are unknown general solution parame-

ters.

We notice that at t = Tth + T1 the voltage components

remain unaltered due to the assumption T2<<T, whereas

the current components of state variations are affected by

the 



J drops. This observation leads to define a system

of two non-linear equations in the two unknown A and







()

Acos

cos

Asin

1sin .



 



 





















μTT

nth nJJ

μTT

nth nJ

μTT

nth nJJ

μTT

nth nJJ

eTTX

eTT+X

F



(11)

In order to achieve an approximate solution of system

(11) we expand the trigonometric function containing



J in Mac Laurin series, limited to the first order and

obtain:



cos .

cos( )sin







 

Jnthn J

Jnthn

IFT TX

=IFT TX

Since in most of practical cases tank quality factor Q

is at least greater than 5 we further observe that



cos coscos1

arctg QQ





 







 



 







(13)

thus we may reformulate (12) neglecting terms due to

pulse in the sum at denominator to solve the general pa-

rameter



J for both the eigenvector as







cos

nth n

IFT T

IFTT











 



 



(14)

where 



1 and 



2 account the phase discontinuities due

to the bias current pulse, respectively, for the first and

the second eigenvector.

Since, by the definition, eigenvectors are periodic, and,

due to the symmetry of the adopted model in the two

halves of period they cover the same phase angle, we

may infer that phase discontinuities caused by the bias

current pulse must be equal, i.e.





 (15).

From these observations, substituting the condition (15)

in Equation (14) and expanding 



J drops, it is straight-

forward to obtain the value of the phase displacement

between the eigenvectors u1 and u2, at least out of the

orbit portion when pulsed current is active as





nth n

TT2









. (16)

We want to remark that in Equation (16)



is only a

function of the threshold crossing time, of the delay of

current pulse application, and of the tank quality factor

(related to parameter



5. Optimal Phase Displacement between

Eigenvectors

Phase displacement between eigenvectors becomes here

the main tool toward the paper goal to offer design in-

sights for the reduction of phase noise which, in our

treatment, means to minimize projection of noise on the

first eigenvector. To this aim we are now going to dem-

onstrate optimum conditions on phase displacement be-

tween eigenvectors, in order to reduce noise due to bias,

parasitic resistance and jitter on accumulation of delay

time T1.

We assume perturbations to be realizations of white

Gaussian noise processes with zero time average. This is

not a restrictive assumption. In fact, also noise sources

(12)

S. PERTICAROLI ET AL.

316

with non-delta autocorrelations, i.e. 1





with





,

may be taken into account through the projections on the

eigenvectors. Referring to [5], in particular Sections 6

and 7, the power density of a flicker noise source is ob-

tained as an infinite sum of autocorrelation spectra of

statistically independent Ornstein-Uhlenbeck processes

(that are also Gaussian processes). Since we are dealing

with a parallel RLC tank, perturbations are introduced as

parallel noise current sources. Such noise current sources

cause a variation of the capacitor voltage, hence we

model the normalized noise perturbation through a con-

stant vector



















 . (17)

In order to determine the PDS we need to calculate the

projection of vector b on the base formed by the two ei-

genvectors. Integration along the orbit of the square value

of the projection on u1 leads to the c1 coefficient of Demir

[7], while projection on u2 must be multiplied before in-

tegration by a properly evaluated exponential factor [11].

We first search for the condition which zeroes the pro-

jection on u1 of noise due to the bias current, usually the

largest source of noise in integrated technologies. Bias

current noise is cyclostationary because it arises only

during the bias pulse. Assuming again T2<<T we may

consider constant the projection angle during the pulse,

then integration reduces to the multiplication of the pro-

jection by time T2. We notice that noise projection has to

be performed after the turning on of the bias current, after

the eigenvector discontinuity in Tth + T1 has occurred. As

depicted in Figures 5 and 6, the additional component is

in the direction [1 0]T, thus the necessary and sufficient

condition which ensures that once added the Interface

matrix component the eigenvector has null current com-

ponent is

 

21 21



 





th th

uT TbuT T0

. (18)

Following the definition of u2 in Equation (6) and sub-

stituting in its expression the phase displacement of

Equation (16), condition (18) is equivalent to:



()

()2 2

nth

nthnth n

nth

TTT T









 









(19)

Equation (19) states that, in possible implementations

of pulsed bias oscillators, the |Vth| threshold should be

chosen around the zero crossing of the oscillation voltage.

We may further search for the minimization of the

contribution arising from parasitic resistance, which re-

mains active all along the orbit. We recall that, from

Equation (16) and following condition T2<<T which led

to (15) phase displacement between eigenvectors remains

constant along the entire evolution except for region

where the pulsed current bias is active.

However, since we assumed bias active for a short time

compared to period, the projections of noise on the two

eigenvectors, respectively u1p and u2p, are given by

sin( )

() sin( )

sin( )

() sin( )























(20)

then we obtain the integral of the square of the projec-

tions

122

222

() dsin ()d2

sin()sin()

() dsin ()d2

sin ()sin ()























ut ttt

(21)

As expected the two terms in Equation (21) are equal.

The first one is the Demir c1 coefficient [7], while the

second is only a majorant term in the expression of phase

noise due to u2.

The actual period T depends on the angle β between

the eigenvectors, however in hypothesis Q > 5 it results

very close to Tn (the nominal period). This leads to state

that factor sin2(β) predominates the result of integration

and allows us to infer that minimization of phase noise

distribution due to a stationary noise source occurs if the

condition β = ±/2 holds.

Further considerations can be derived from this result

and from condition expressed in (19). For example, we

notice that a jitter noise contribution arises from the elec-

tronic circuit when we introduce the delay T1. This jitter

is proportional to the delay itself and inversely propor-

tional to the power used to accumulate the delay [18].

The choice to avoid any delay may be of interest in order

to save an additional source of noise and to reduce en-

ergy dissipation [19]. Imposing T1 = 0 in combination

with condition (21) we obtain that the optimum choice is

to set



ππ

224

 















nth nth

(22)

It results that condition on minimization of stationary

noise (21) together with condition on minimization of

accumulated jitter can be simultaneously satisfied only

for a very low quality factor (Q = 0.5). Then in any prac-

S. PERTICAROLI ET AL.317

tical case a suboptimal condition must be searched, e.g.

accepting a non zero delay time T1.

Hence the last optimum condition we can search for is

derived from minimization of both resistance noise and

bias current noise for a given quality factor Q and in pres-

ence of a delay time of the current pulse T1. Using results

from Equations (19) and (21) in Equation (16) we obtain

ππ 1

2 2arctg

222





 



nTQ

(23)

6. Numerical Comparison and Discussion

In order to evaluate the accuracy of the proposed analyti-

cal expressions we need to compare them with numerical

simulations. In fact, at the knowledge of the authors, there

is no measurement setup and/or post-processing that can

extract eigenvectors from measure of physical quantities

in a real circuital implementation.

Moreover there are no commercial circuit simulator

which can compute Floquet eigenvectors in presence of

discontinuities in space state. Then we developed a dedi-

cated Matlab simulator for the model defined in Section

III. The simulator derives the Monodromy matrix through

a shooting algorithm which use Interface matrices for the

treatment of discontinuities.

Even if the proposed analysis is not dependent on the

oscillation period, in the following simulations we fixed

frequency at fn =



n/(2



5 GHz. Along with frequency,

we choose to keep constant quality factor Q = 7.5, pulse

duration T2 = T/15 and amplitude Imax = 60 mA ensuring

the oscillator to be refilled by a fixed amount of energy

and to be perturbed by the same amount of noise power.

Moreover in case Vth ≠ 0 V we keep constant also the sum

Tth+T1, allowing to reach the same limit cycle of Vth = 0

V simulations set. The two case of study, respectively Vth

≠ 0 V and Vth ≠ 0 V, differ only in the starting point with

respect to period of T1 delay accumulation and in the

weight of jitter contribution which is proportional to T1.

All kind of noise sources are modeled as parallel current

generators that adds to the model in Figure 1. Stationary

noise is introduced as thermal noise of the parasitic resis-

tance depending on quality factor Q through 4kBTamb/R

[A2/Hz] relation (kB is Boltzmann constant Tamb is ambi-

ent temperature in Kelvin) whereas the cyclostationary

noise is introduced as shot noise (modeling eventual de-

vices) related to current Imax through 2qImax [A2/Hz] rela-

tion (q is electron charge). Jitter noise source is instead

considered as an additional time shift due to the accumu-

lation of both T1 and T2 delay and it is added to the one

due to evolution of the initial variation until time of thre-

shold crossing Tth (8). Jitter source is the result of the

charging of a capacitor through a dissipative media (again

assume a MOS device) so it has been modeled through

8kBTamb



1(KMOS/ID

3)0.5 [s] relation where is



transistor

noise constant, KMOS and ID are respectively the large sig-

nal current gain and drain current of MOS device. We

choose to fix drain current to ID = Imax/10 = 6 mA. In fact

the eventual auxiliary circuit suited for the introduction of

desired delay must necessarily have a lower power con-

sumption with respect the refilling process of the tank in a

real design.

In Figure 8 the phase displacement β is reported in

function of T1 normalized to period T in two cases Vth = 0

V and Vth = 0.75 V.

Amplitude and period of oscillation, as stated before,

vary in function of pulse position between [2.45 V, 3.11

V] and [4.8 GHz, 5.2 GHz] respectively.

It can be observed a good match between simulated

and calculated (16) trend with a maximum absolute error

of about 13 in the evaluated range for case Vth = 0.75 V.

Former considerations on factor sin2(β) in case Vth = 0

V suggest that in correspondence of T1/T ≈ 0.223 when



≈ /2 a minimization of noise projection on the first

eigenvector should occur. Moreover for T1/T ≈ 0.223 the

maximum of amplitude and the nominal frequency are

obtained. In case V

th = 0.75 V the enhancement of time

shift (8) due to late starting point Tth of delay accumula-

tion overwhelm any reduction of jitter weight due to

shorter T1.

In Figure 9 the simulated PDS of the oscillator is re-

ported for three typical frequency offsets (100 KHz,

1 MHz and 10 MHz) from the fundamental in function of

Figure 8. Eigenvectors phase displacement out of the fast

region simulated (dotted trace) and calculated (continue

trace) in function of normalized pulse position T1 for T2 =

T/15, Q = 7.5 in cases Vth = 0 V and |Vth| = 0.75 V.

S. PERTICAROLI ET AL.

318

Figure 9. Simulated PDS evaluated at three different offset

from fundamental frequency in function of normali zed pulse

position T1 for T2 = T/15, Q = 7 .5 in cases Vth = 0 V (continue

trace) and |Vth| = 0.75 V (dotted trace).

T1 in case of Vth = 0 V and Vth = 0.75V.

PDS has been computed following [11]. It can be ob-

served that the continue trace related to the lowest offset,

where the major contribution to PDS arises from projec-

tion on first eigenvector, exhibits the minimum exactly in

correspondence of the prediction made by means of



≈

/2 criterion for Vth = 0 V. At higher offsets contributions

arising from projections on cross-correlations between

eigenvectors and on second eigenvector become prepon-

derant and the minima shift toward earlier T1/T ratio for

both Vth cases. However it can be noticed that the Vth = 0

V case achieves the better performance at the lowest off-

set whereas the Vth = 0.75 V case reaches the best results

at large offsets for quite all T1/T ratio.

In order to justify this observed trend we propose to

monitor noise introduced through first eigenvector (refer-

ring to u1p(t) noise projection) in term of injected level of

energy from all noise sources on first eigenvector.

In Figure 10 the energy injected along the normalized

period on first eigenvector by perturbation vector b is

reported in cases Vth = 0 V and Vth = 0.75 V for T1/T =

0.24, T2 = T/15, Q = 7.5. It can be noticed that the zero

of injected energy occurs during the current bias pulse

only in case Vth = 0 V. For any Vth ≠ 0 V the zero shifts

toward later time instant. Moreover, as a result of non

orthogonal phase displacement between eigenvectors in

case Vth ≠ 0 V the maxima of injected energy on first

eigenvector (when only stationary and jitter noise

sources are present) can be greatly increased, thus de-

grading phase noise especially at low offsets. This ob-

servation is congruent with former defined design crite-

rion (19) and validates the proposed analysis.

Figure 10. Simulated energy injected on first eigenvector by

perturbation vector b in cases Vth = 0 V (continue trace) and

|Vth| = 0.75 V (dotted trace) on left y-axis and capacitor volt-

age VC right y-axis along oscillation period for T1/T = 0.24,

T2 = T/15, Q = 7.5.

7. Concluding Remarks

The paper presented an approximated and compact deri-

vation of the mutual displacement of Floquet eigenvec-

tors in the class of parallel RLC tank oscillators with

pulsed current bias. Mutual displacement was proved to

be strongly connected with the chosen architecture and

consequently to determine phase noise distribution. As

appreciable result, the derived expression of displace-

ment is compact and straightforward, thus it can suggest

primary guide lines for designers in the field of oscilla-

tors architectures with time varying bias.

In particular we demonstrated conditions for minimi-

zation of stationary as well as cyclostationary noise. Also

the jitter noise introduced in the positioning of the pulsed

bias is taken into account and its relation with noise pro-

jections on the eigenvectors is determined. Minimization

conditions were formulated using parameters of the pro-

posed model for the pulsed bias class, allowing to di-

rectly infer the circuit design. Finally the analytical re-

sults are compared with a dedicated simulator, showing

that proposed criteria for noise reduction are congruent

with observed trend in the simulated PDS.

Future works will provide developments and exten-

sions of the proposed analytical noise treatment to VCOs

and PLLs systems.

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