6 Systems Represented by Differential and Difference Equations
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1 6 Systems Represented by ifferential and ifference Equations An important class of linear, time-invariant systems consists of systems represented by linear constant-coefficient differential equations in continuous time and linear constant-coefficient difference equations in discrete time. Continuous-time linear, time-invariant systems that satisfy differential equations are very common; they include electrical circuits composed of resistors, inductors, and capacitors and mechanical systems composed of masses, springs, and dashpots. In discrete time a wide variety of data filtering, time series analysis, and digital filtering systems and algorithms are described by difference equations. In this lecture, we review the time-domain solution for linear constantcoefficient differential equations and show how the same basic strategy applies to difference equations. While this review is presented somewhat quickly, it is assumed that you have had some prior exposure to differential equations and their time-domain solution, perhaps in the context of circuits or mechanical systems. In any case, in Lecture 9 after we have developed the Fourier transform, we will see some more efficient (at least mathematically) ways of obtaining the solution. In considering the time-domain solution to linear constant-coefficient differential and difference equations, we should recognize a number of important features. Foremost is the fact that the differential or difference equation by itself specifies a family of responses only for a given input x(t). In particular we can always add to any solution another solution that satisfies the homogeneous equation corresponding to x(t) or x(n) being zero. Thus, for unique specification of a system, in addition to the differential or difference equation some auxiliary conditions (for example, a set of initial conditions) are needed that will specify the arbitrary constants present in the homogeneous solution. In Lecture 5 we showed that a linear, time-invariant system has the property that if the input is zero for all time, then the output will also be zero for all time. Consequently, a linear, time-invariant system specified by a linear constant-coefficient differential or difference equation must have its auxiliary
2 Signals and Systems 6-2 conditions consistent with that property. If, in fact, the system is causal in addition to being linear and time-invariant, then the auxiliary conditions will correspond to the requirement of initial rest; that is, if the input is zero prior to some time, then the output must be zero at least until the same time. In the context of RLC circuits, for example, this would correspond to an assumption of no initial capacitor voltages or inductor currents prior to the time at which the input becomes nonzero. An important distinction between linear constant-coefficient differential equations associated with continuous-time systems and linear constant-coefficient difference equations associated with discrete-time systems is that for causal systems the difference equation can be reformulated as an explicit relationship that states how successive values of the output can be computed from previously computed output values and the input. This recursive procedure for calculating the response of a difference equation is extremely useful in implementing causal systems. However, it is important to recognize that either in algebraic terms or in terms of block diagrams, a difference equation can often be rearranged into other forms leading to implementations that may have particular advantages. For example, as illustrated in the lecture, the most direct representation of a difference equation in terms of a block diagram or algorithm is often not the most efficient. Since the order in which linear, time-invariant systems are cascaded is not important to the overall inputoutput response, the most direct representation can be rearranged so that its implementation requires significantly less memory or, equivalently, delay registers. In addition, there are many other rearrangements, each having particular advantages and disadvantages. Similar kinds of rearrangements of the block diagrams also apply to the block diagram realizations of linear constant-coefficient differential equations for continuous-time systems. Suggested Reading Section 3.5, Systems escribed by ifferential and ifference Equations, pages Section 3.6, Block-iagram Representations of LTI Systems escribed by ifferential and ifference Equations, pages
3 ifferential and ifference Equations LINEAR CONSTANT-COEFFICIENT IFFERENTIAL EQUATION Nth Order: N E: a k k=0 dk y(t) dtk M k=0 dkx(t) dt k 6.1 Nth-order linear constant-coefficient differential and difference equations. LINEAR CONSTANT-COEFFICIENT IFFERENCE EQUATION Nth Order: N E k=0 ak y[n-k] M =E k=0 bk x[n-k] N Ek=0 N k=0 dky(t) M a = -E dtk k=o dkyh(t) k k 0 dt dkx(t) k dtk (1) (Homogeneous Equation) (2) 6.2 Family of solutions for a linear constantcoefficient differential equation. Given x(t), if y (t) satisfies (1) then so does y,(t) + yh(t) where yh (t) satisfies (2) yp(t) A Particular solution yh (t) = Homogeneous solution
4 Signals and Systems 6-4 HOMOGENEOUS SOLUTION 6.3 Form of the homogeneous solution. N dkyh(t) 0 ak dtk k0o "guess" solution of the form Yh (t) = Aest N E ak A s k est = 0 k=0 N k=0 ak s k = 0 N roots s i i = 1,..., N Yh(t) = A 1 esit + A 2 es2t ANeSNt 6.4 Requirements on the auxiliary conditions for a linear constantcoefficient differential equation to correspond to a linear system or to a causal LTI system. Need N auxiliary conditions, e.g. y(t), dy(t) dt N -1 V(t), "" '..N - 1 at t = t e Linear system <=> auxiliary conditions = 0 ecausal, LTI <=> initial rest: if x(t) = 0 t <to then y(t) = 0 t<t 0
5 ifferential and ifference Equations MARKERBOAR 6.1 C% :SOk" 4 t'ov% ts ct I ' ikt LL CLo ukt) S CO L Lt) C L o + LV Ct CO ~& dt~ e + a o 'K 1 t~~43l&l* Ot A e 6.5 Family of solutions for a Nth-order linear constant-coefficient difference equation.
6 Signals and Systems Form of the homogeneous solution. 6.7 Requirements on the auxiliary conditions for a linear constantcoefficient difference equation to correspond to a linear system or to a causal LTI system.
7 ifferential and ifference Equations 6-7 ENCE EQUATION 6.8 Recursive causal solution to a linear constant-coefficient difference equation. MARKERBOAR 6.2
8 Signals and Systems 6-8 x [n] - y [n] 6.9 evelopment of the x [n1- A y [n -1) block diagram representation of the recursive solution. elays associated with the input and output. x [n-2] y [n-2] x [n-n] y[n-n] x[n] b- I y[n] b 6.10 x[n-] Incorporation of the 1 y[n-1) coefficient multiplication. x [n-2] b-a 2 y [n -2) x [n -N] y [n -N]
9 ifferential and ifference Equations x [n y [n] 6.11 Forming the sums of the weighted, delayed sequences. x [n [n-n] 6.12 Complete block diagram. This form is often referred to as the direct form I implementation.
10 Signals and Systems Interchanging the order in which the two segments of the block diagram of Transparency 6.12 are cascaded. y n 6.14 Result of combining the two chains of delays in Transparency This form is often referred to as the direct form II implementation.
11 ifferential and ifference Equations 6-11 MARKERBOAR 6.3 (a) 6.15 irect form I block diagram representation of a linear constant-coefficient differential equation.
12 Signals and Systems 6-12 / N bn 6.16 Resulting block diagram when the order of the two subsystems in Transparency 6.15 is reversed. x (t y( t) 6.17 The result of combining the two chains of integrators in Transparency This form is often referred to as the direct form II.
13 CA ~ <Vt ifferential and ifference Equations MARKERBOAR 6.3 (b) ci vt~ cii~l*~ <5 7~ tskt4y&~4t) S I K C ej$adit*w 6, icl sti t 0' - Needt wkber vat. L~i I 5 -t Lii kinit A C-&Aflmde%5 7.TI %46 ((K A
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