This paper proposes a novel method for the analysis and simulation of integrated circuits (ICs) with the potential to greatly shorten the IC design cycle. The circuits are assumed to be subjected to input signals that have widely separated rates of variation, e.g., in communication systems, an RF carrier modulated by a low-frequency information signal. The proposed technique involves two stages. Initially, a particular order result for the circuit response is obtained using a multiresolution collocation scheme involving cubic spline wavelet decomposition. A more accurate solution is then obtained by adding another layer to the wavelet series approximation. However, the novel technique presented here enables the reuse of results acquired in the first stage to obtain the second-stage result. Therefore, vast gains in efficiency are obtained. Furthermore, a nonlinear model-order reduction technique can readily be used in both stages making the calculations even more efficient. Results will highlight the efficacy of the proposed approac

Brennan, Conor

Condon, Marissa

Dautbegovic, Emira

English

This paper proposes a new and efficient approach for the analysis and simulation of circuits subject to input signals with widely separated rates of variation. Such signals arise in communication circuits when an RF carrier is modulated by a low-frequency information signal. The proposed technique initially involves converting the ordinary differential equation system, that describes the nonlinear circuit, to a partial differential equation system. The resultant system is then semidiscretised using a multiresolution collocation scheme, involving cubic spline wavelet decomposition. A reduced equation system is subsequently formed, using a nonlinear model reduction strategy. This enables an efficient solution process using trapezoidal numerical integration. Results highlight the efficacy of the proposed approach

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An efficient nonlinear circuit simulation technique

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TUIFR-30 An efficient nonlinear circuit simulation technique Emira Dautbegovic, Marissa Condon and Conor Brennan School of Electronic Engineering, Dublin City University, Dublin 9, IRELAND (emira.dautbegovic@eeng.dcu.ie, marissa.condon@dcu.ie, brennanc@eeng.dcu.ie) Abslrrrcl - The paper proposes a new and eilicient approach for the analysis and simulation of circuits subject to input signals with widely separated rates of variation. Such signals arise in communication circuits when an RF carrier is modulated by a low-freqncney information signal. The proposed technique will initially involve converting the ordinaly differential eqnalion system that describes the nonlinear eircnit to a partial differential equation system. The resultant syslem is then scmidiscretised using a multiresolntion collocation scheme involving cubic spline wavelet decomposition. A reduced cqnation system is subsequently formed using a nonlinear model rednetion strategy. This enables an eilicient solution process using trapezoidal numerical integration. Results will highlight the efticacy ofthe proposed approach. 1. INTRODUCTION Harmonic balance [l-31 and Time-Domain Integration [4] are the two most widely employed circuit simulation techniques in circuit simulators for the analysis of high- frequency nonlinear circuits. Harmonic balance is most effective for periodic or quasi-periodic steady-state analysis of mildly nonlinear circuits and thus is of limited use for the complex modulation formats encountered in today’s high-speed systems or for systems involving strong nonlinearities. Time-domain integration on the otherhand is only practical for baseband systems. For the simulation of circuits with digitally modulated high- frequency carriers with long hit sequences, time-domain integration is excessively slow. As a result, there is a need for some form of general purpose technique which can simulate state-of-the-art systems which are subject to transient high-frequency signals or complex modulated RF carriers. Several envelope transient analysis approaches have recently been proposed whereby a mixed-mode technique is implemented [ M I .  The essence of these approaches is that the slowly-varying envelope of a signal is treated by time-domain integration and that the high-frequency carrier is treated by Harmonic Balance. However, existing techniques have limitations, for example, restrictions in the bandwidth of the excitation signal [SI and the limitations of harmonic balance with respect to strong nonlinearities. Roychowdhury in [7] proposes converting the differential-algebraic equations that describe the circuit to multi-time partial differential equations and applying time-domain methods directly to solve the resultant systems. Pedro [8] also employs a multi-time partial differential equation approach but uses a combination of Harmonic Balance and Time-Domain Integration to solve the resultant system. The approach presented in this paper also employs the multi-time partial differential equation approach. The proposed technique is a variation and improvement of that presented in [9]. A modification of the wavelet-based collocatiou approach proposed hy Cai and Wang in [IO] forms the core of the technique and unlike Christoffersen and Steer [I I], the cubic spline wavelet basis is employed to solve the multi-time partial differential equation representation of the system rather than the original ordinary differential equation representation. However, the technique presented in [9] is greatly enhanced in this paper in that a nonlinear model reduction strategy similar to that in [I21 is employed within the proposed envelope simulation technique to obtain very high efficiencies. The paper proceeds to compare, for a test system, the result that is obtained with a full wavelet system as is employed in [9] to the result which is obtained when the model reduction strategy is utilised. The accuracy will be seen to be excellent while significant gains in computational speed are achieved. A result is also given when a lower- order wavelet scheme is employed. This result will confirm that for comparable computation time significant gains in accuracy may he achieved by employing the approach proposed in this paper as opposed to simply using a lower-order full wavelet scheme. The particular circuit selected is deliberately chosen as it is strongly nonlinear in nature. The ability to simulate the behaviour of this circuit with such accuracy will give further recommendation for employing a wavelet-based simulation technique as opposed to a Harmonic-Balance based approach. 11. MULTITIME PARTIAL DIFFERENTIAL EOUATION APPROACH . Consider a signal x(f) which is composed of a carrier modulated by an envelope where the envelope signal is 623 0-7803-8333-8/04/~20.00 0 2004 IEEE 2004 IEEE Radio Frcquency Intcgratcd Circuits Symposium Authorized licensed use limited to: DUBLIN CITY UNIVERSITY. Downloaded on July 14,2010 at 15:05:20 UTC from IEEE Xplore.  Restrictions apply. assumed to be uncorrelated with the carrier. The signal may be represented in two independent time variables as follows: lI relates to the low-frequency envelope and t2 relates to the high-frequency carrier. Now consider a general nonlinear circuit described by: where b(t) is the excitation vector, x(1) are the state variables and f is a nonlinear function. The corresponding multitime partial differential equation system can be written as shown in [7] as: d t ) = 3 t I , t ? )  ( 1 )  W = / ( X ( t ) ) + b ( / )  (2) This multitime partial differential equation can be solved using exclusively time-domain approaches as employed by Roychowdhury [7] or using a combination of time-step integration for the envelope and Harmonic Balance for the carrier as in [SI. However, for strongly nonlinear circuits, the use of harmonic balance for the inner loop can prove limited. In this paper, the multitime partial differential equation system is solved using a pseudo-wavelet collocation method derived from that proposed by Cai and Wang [IO]. However, the crucial step introduced in this contribution is the application of a nonlinear model reduction process within the simulation technique. This leads to very significant gains in efficiency but without a complementary loss in accuracy. 111. WAVELET COLLOCATION SCHEME The technique involves approximating the unknown limction i ( t , , t 2 )  with a wavelet series in the t2 dimension where is scaled such that ti E [0, L], D4. I.e. ;.I ( f l  2 f 2 )  =7-1,-3(11 )1/l(/2 )+:-l,-2 ( / I  )1/2 ( l 2 )  + % - I  (11 )@b(f2 )+ L-4 '-1.h ('1 )@k ( '2 )+'-l,L-3 ([I )@b ( L - 1 2 )  k=O (4) k l  where @(l) and I&) are scaling and wavelet functions respectively and q(t)are spline functions introduced to approximate boundary-nonhornogeneities as described in [IO]. X(lI)are the unknown coefficients which are a function of 1, only. The total number of unknown coefficients is N = 2 L + 3 where J determines the level of wavelet Coefficients taken into account when approximating 3 1 ,  , 1 2 ) .  From this point forward,PL ( 1 )  shall be referred lo as wavelets where it is understood that these comprise the scaling functions, @(1) ,  the wavelet functions, &I) and the nonhomogeneity functions, q(/). Eqn. 3 is then collocated on collocation points in l2 to result in a semidiscretised equation system. The interpolation points are those as chosen in [IO]. At this juncture, the technique differs significantly from that presented in (91. Instead of directly solving for the unknown state-variables and output y(1) at each time-step in tlr a nonlinear model reduction strategy is employed. The particular model reduction strategy chosen is based on that presented by Gunupudi and Nakhla in [12]. Thus instead of solving an nFh order system at each time-step to obtain the unknown state-variables and the output quantity yfl), a reduced-order system of transformed coefficients is solved. Once the transformed coefficients are determined for the entire time range of interest, the original N coefficients, ?( I , )  and consequently, the value ofthe state variables and the output quantity ye) may be obtained in one single post-processing step. The entire solution process is described in detail in the following section. IV. MODEL REDUCTION TECHNIQUE The expression in (4), if written for all collocation points in t2, may be expressed as follows at a specific point in time 1,: where E is a constant N-dimensional square matrix whose columns comprise the values of the N wavelet functions, 'f'k (t2), at N collocation points. The matrix is evaluated once at the outset of the algorithm. .kJN(lI )  is an N- dimensional column vector of the unknown state-variables and E(/,) is an N-dimensional column vector of the unknown wavelet coefficients at the collocation points in t2 at a specific instant in t,. Substitution of (4) and (5) in (3) yields: i J N  ([I = ) (5) (6) where D is an N dimensional matrix whose columns are formed from the derivatives of the wavelet functions in (4) evaluated at each of the N collocation points in f2 . Again, D is evaluated only once at the outset of the a1gorithm.f. and b N  are column vectors comprising the values off and ba t  the collocation points. d? dl I E - = -E + fN (3 + bN 624 Authorized licensed use limited to: DUBLIN CITY UNIVERSITY. Downloaded on July 14,2010 at 15:05:20 UTC from IEEE Xplore.  Restrictions apply. At this point, the vector of coefficients, E(/,), is expanded in a Taylor series as follows: where fyis the initial time and where the coefficients, a i ,  may be computed recursively as in [12]. A Krylov space is formed for a; : where 9 is the order of the reduced system and is significantly less than N .  An orthogonal decomposition of K results in: where QTQ = I, , I, is the 9 dimensional identity matrix. Q is then employed to perform a congruent transformation K = [ a o  a, ..' a,] (8) K =QR (9)  Of(5): F=QF (10) Thus a new reduced equation system is formed as: d2 dl I Q'EQ-=-Q'DQ$+Q' fN(Qi)+QTbN where i = QTEQ , D = QT DQ and 8, = Q'b, . This new system, (1 I), of dimension 9 may then be solved to determine $over the entire time domain of interest. A trapezoidal-rule integration scheme is employed because of its superior stability qualities. Once the 9 Coefficients, x , have been determined, 2 ( t , )  and consequently, i J N ( l , ) = E Z ( ( , ) ,  may be obtained in one single post- processing step. The above solution process is thus significantly more efficient than solving directly for iJN(~!)  at each time step as was done in [9]. - V. SAMPLE SYSTEM The example considered consists of the highly nonlinear diode rectifier circuit as shown in Fig. 1. The source is: (11) 216 2m where T; corresponds to the envelope period and T3 corresponds to the carrier period. b ( f )  = sin(-)sin(-) TI Tz Fig. 1 Diode rectifier circuit Fig. 2a shows the output from an ordinary differential equation solver with a very short time step in order to obtain a highly accurate version of the output voltage to act as a benchmark for the purposes of confirming the accuracy of the proposed new simulation technique. Fig. 2b shows the output from the wavelet scheme where no model reduction is performed. For this case, L=2O and J=2 in eqn. 4. This results in a system for which N=83. This is obviously a very high-order wavelet scheme and thus is very accurate. Fig. 2c shows the corresponding result with the same wavelet scheme but in this case the model reduction step in included. The system is reduced with 9, the reduction level, set equal to 5. The accuracy is seen to be excellent while concomitantly achieving major computational savings. In particular, a 5Ih order system is now solved instead of an 83'd order system. Finally Fig. 2d shows the result when a lower order full wavelet scheme is employed. In this case, L=5 and J = O  in eqn. 4. This results in an N=8Ih order system of equations which has similar computational requirements to reduced wavelet scheme with q=5. As can be seen from Fig. 2d, there is a significant loss in accuracy. This result clearly confirms that the approach presented in this paper is significantly better than simply employing a full lower- order wavelet scheme especially when circumstances require high computational efficiency. 9 0.2 LPL 0.0  I0.0 0.1 0.2 0.3 0.4 0.5 0.6 tine m Fig.2a Result from ODE solver with a very short timestep 625 Authorized licensed use limited to: DUBLIN CITY UNIVERSITY. Downloaded on July 14,2010 at 15:05:20 UTC from IEEE Xplore.  Restrictions apply. O 5  r off between accuracy and efficiency can be achieved by simply adjusting the wavelet level Jand  reduction level q. c -Fig. 0.4 I 0 2  00 1LJ!L 00 01 02 03 04  O S  06 tnne mr 2b Result fiom a full wavelet scheme 00 00 01 02 03 04  O S  06 a4 L Fig. 2c Result from the proposed new technique 0 4  O S E thnemr Fig. 2d Result with lower-order full wavelet scheme VI. CONCLUSION I h e  paper has presented a highly efficient wavelet based simulation technique for high-h-equency circuits. The scheme involves converting the ordinary differential equation system describing the nonlinear circuit to a partial differential equation system. This system is solved using a combination of a nonlinear model reduction strategy and a cubic spline wavelet collocation scheme. The results h-om a highly nonlinear system indicate the efficiency and accuracy of the proposed approach. The important feature of this method is that the desired trade- ACKNOWLEDGMENT The authors wish to acknowledge the support of IBM for this work. REFERENCES [I j Kundert, K.S. and Sangiovanni-Vincentelli A.: 'Simulation of nonlinear circuits in the frequency domain', IEEE Trans. CAD, vol. CAD-5, pp. 521-535,1986 [Z] Long, D., Melville, R., Ashby, K. and Horion, R.: 'Full-chip harmonic balance', Proc. IEEE Custom Integrated Circuifs Conf, May 1997 131 Nakhla, M. and Vlach, J.: 'A piecewise harmonic balance technique for determination of periodic response of nonlinear systems', IEEE Trans. Circuits Sysf., vol. CAS-23, pp. 85-91, Feb. 1976 (41 Nagel, L.W.: 'SPICE2, A computer program lo simulate semiconductor circuits', Tech. Rep. ERL-MS20, Univ. California, Berkeley, 1975. [5] Ngoya, E. and Larcheveque, R.: 'Envelope transient analysis: A new method for the transient and steady-state analysis of microwave communications circuits and systems' IEEE MTSymp.  Dig., San Francisco, Jun. 1996 [6] Shamtt, D.: New method of analysis of communication systems', IEEE M7T-S Nonlinear CAD Workshop, Jun. 1996 [7] Roychowdhury, J.S.: 'Analysing circuits with widely separated timescales using numerical PDE methods', IEEE Trans. Circuits ondSystems, May 2001 [SI Pedro, 1. C. and Carvalho, N.B.: 'Simulation of RF circuits driven by modulated signals without bandwidth constraints', IMS 2002, Seattle. [9] Condon, M. and Dautbegovic E.: 'A novel envelope simulation technique for high-frequency nonlinear circuits', Proc. EuMW2003, Munich. [IO] Cai, W. and Wang, J.Z.: 'Adaptive multi-resolution collocation methods for initial boundary value problems of nonlinear PDEs', S U M  Journal Numerical Analysis, Vol. 33, No. 3, 1996 [ 111 Christoffersen, C.E. and Steer, M.B.: 'State-variable- based transient circuit simulation using wavelets', IEEE Microwave and Wireless Components Letters, Vol. 11, No. 4, April 2001 [I21 Gunupudi, P.K. and Nakhla, M.S.: 'Model reduction of nonlinear circuits using Klylov-subspace techniques', Proc. DAC99, pp. 13-16.1999. 626 Authorized licensed use limited to: DUBLIN CITY UNIVERSITY. Downloaded on July 14,2010 at 15:05:20 UTC from IEEE Xplore.  Restrictions apply. 

Authorized licensed use limited to: DUBLIN CITY UNIVERSITY.

Envelope transient analysis: A new method for the transient and steady-state analysis of microwave communications circuits and systems'

Full-chip harmonic balance',

State-variablebased transient circuit simulation using wavelets',

Name not available

E. Dautbegovic

M. Condon

C. Brennan

Crossref

(M’02) was born in Dublin, Ireland, in 1972. He received the B.A. (Mod.) degree in mathematics and Ph.D. degree from the

(M’98) received the B.E. degree (with honors) and Ph.D. degree from the National University of Ireland,

[12] P.K.GunupudiandM.S.Nakhla,“Modelreductionofnonlinearcircuits using Krylov-subspace techniques,” in

[9] M.CondonandE.Dautbegovic,“Anovelenvelopesimulationtechnique for high-frequency nonlinear circuits,” in

An efﬁcient nonlinear circuit simulation technique,”

Authorized licensed use limited to: DUBLIN CITY UNIVERSITY. Downloaded on July 14,2010 at 15:16:43 UTC from IEEE Xplore. Restrictions apply.

Condon is a reviewer for the

Envelope transient analysis: A new method for the transient and steady-state analysis of microwave communications circuits and systems,”

Full-chip harmonic balance,” in

New method of analysis of communication systems,” presented at the

Numerical Analysis: A Practical Approach, 3rd ed.

She is currently a Ph.D. Researcher with the RF Modeling and Simulation Group, School of Electronic Engineering,

Simulation of nonlinear circuits in the frequency domain,”

SPICE2: A computer program to simulate semiconductor circuits,”

State-variable-based transient circuit simulation using wavelets,”

Theory Appl.,

to 2002, he was a Post-Doctoral Researcher with the Radio Propagation Group, Department of Electrical Engineering, University of Dublin Trinity College. In

An efficient nonlinear circuit simulation technique

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