Presentation is loading. Please wait.

Presentation is loading. Please wait.

I.4 - System Properties Stability, Passivity

Published byAlexina Chrystal Willis Modified over 8 years ago

Similar presentations

Presentation on theme: "I.4 - System Properties Stability, Passivity"— Presentation transcript:

1 I.4 - System Properties Stability, Passivity
Introduction to Model Order Reduction I.4 - System Properties Stability, Passivity Luca Daniel Thanks to Joel Phillips, Jacob White

2 Outline Review of Laplace Domain Transfer Function
Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

3 An Aside on Transfer Functions – Laplace Transform
Rewrite the ODE in transformed variables  Transfer Function

4 An Aside on Transfer Functions – Meaning of H(s)
For Stable Systems, H(jw) is the frequency response Sinusoid Sinusoid with shifted phase and amplitude

5 An Aside on Transfer Functions – EigenAnalysis
Apply Eigendecomposition

6 Outline Review of Laplace Domain Transfer Function
Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

7 Stability of State-Space Models
Consider a state-space model in isolation (it is not part of a larger system) Model Input Output For well-behaved (e.g., bounded) inputs, when will the outputs be well-behaved (e.g. bounded) as well?

8 Stability of State-Space Models
From systems theory, the model will be bounded-input/bounded-output (BIBO) stable if the transfer function has no poles in the open left half-plane. Recall The poles of occur where is singular Equivalently, for non-singular , has a partial-fraction expansion where the (poles) are the eigenvalues of For stability, these eigenvalues must not have positive real part; otherwise the impulse response will contain a growing exponential

9 Descriptor Systems What about ?
For , the poles come from the eigenvalue problem For non-singular E, we can transform to this form. For singular E, the poles occur when is singular. The poles are determined by the generalized eigenvalue problem

10 Outline Review of Laplace Domain Transfer Function
Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

11 Passivity Passive systems do not generate energy. We cannot extract out more energy than is stored. A passive system does not provide energy that is not in its storage elements.

12 Need to preserve passivity of passive interconnect
Analog or digital IP blocks PCB, package, IC interconnects - + - + D Q Z(f) C Picture by J. Phillips Picture by M. Chou Note: passive! Hence, need to guarantee passivity of the model otherwise can generate energy and the simulation will explode!! Would like to capture the results of the accurate interconnect field solver analysis into a small model for the impedance at some ports.

13 Interconnected Systems
In reality, reduced models are only useful when connected together with models of other components in a composite simulation Consider a state-space model connected to external circuitry (possibly with feedback!) ROM Can we assure that the simulation of the composite system will be well-behaved? At least preclude non-physical behavior of the reduced model?

14 Interconnecting Passive Systems
The interconnection of stable models is not necessarily stable. BUT the interconnection of passive models is a passive model (and hence also stable). Q D C - + Q D C - + Q D C - + Q D C - +

15 Outline Review of Laplace Domain Transfer Function
Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

16 Positive Realness & Passivity
For systems with immittance (impedance or admittance) matrix representation, positive-realness of the transfer function is equivalent to passivity ROM + + - -

17 Passivity condition on transfer function
For systems with immittance matrix representation, passivity is equivalent to positive-realness of the transfer function (no unstable poles) (impulse response is real) (no negative resistors)

18 Passivity condition on transfer function
For systems with immittance matrix representation, passivity is equivalent to positive-realness of the transfer function (no unstable poles) (impulse response is real) (no negative resistors) It means its real part is a positive for any frequency. Note: it is a global property!!!! FOR ANY FREQUENCY

19 Positive real transfer function in the complex plane for different frequencies
Active region Passive region

20 Sufficient conditions for passivity
i.e. E is negative semidefinite Note that these are NOT necessary conditions

21 Sufficient conditions for passivity
i.e. A is negative semidefinite Note that these are NOT necessary conditions

22 Example Finite Difference System from on Poisson Equation (heat problem)
Heat In We already know the Finite Difference matrices is positive semidefinite. Hence A or E=A-1 are negative semidefinite.

23 Sufficient conditions for passivity
i.e. E is positive semidefinite i.e. A is negative semidefinite Note that these are NOT necessary conditions (common misconception)

24 Example. hState-Space Model from MNA of R, L, C circuits
When using MNA For immittance systems in MNA form A is Negative Semidefinite E is Positive Semidefinite + + - -

25 Necessary and Sufficient Condition for Passivity The Positive Real (KYP) Lemma
A stable system (A,B,C,D) is positive real if and only if there exists X=XH0 such that the linear matrix inequality is satisfied If D=0 the system is positive real if

26 Positive-Real Lemma (other form)
Lur’e equations : The system is positive-real if and only if is positive semidefinite A dual set of equations can be written for a with A similar set of equations exists for bounded-real models

27 Outline Review of Laplace Domain Transfer Function
Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

28 Bounded Realness & Passivity
For systems with scattering matrix representation, bounded-realness of the transfer function is equivalent to passivity ROM

29 Passivity condition on transfer function
For systems with scattering matrix representation, passivity is equivalent to bounded-realness of the transfer function (no unstable poles) (impulse response is real) (no negative resistors)

30 Passivity condition on transfer function
For systems with scattering matrix representation, passivity is equivalent to bounded-realness of the transfer function (no unstable poles) (impulse response is real) (no negative resistors) It means ||H(s)||2 < 1 is bounded for any frequency. Note: it is a global property!!!! FOR ANY FREQUENCY

31 Bounded real transfer function in the complex plane for different frequencies
+j Transfer Function 1 -1 Passive region -j Active region

32 Summary. System Properties
Review of Laplace Domain Transfer Function Stability of State-Space Models Passivity of State-Space Models Positive-Realness Bounded-Realness

Download ppt "I.4 - System Properties Stability, Passivity"

Similar presentations

PROCESS MODELLING AND MODEL ANALYSIS © CAPE Centre, The University of Queensland Hungarian Academy of Sciences Analysis of Dynamic Process Models C13.

PROCESS MODELLING AND MODEL ANALYSIS © CAPE Centre, The University of Queensland Hungarian Academy of Sciences Analysis of Dynamic Process Models C13.
Leo Lam © 2010-2012 Signals and Systems EE235 Lecture 16.

Leo Lam © Signals and Systems EE235 Lecture 16.
Properties of State Variables

Properties of State Variables
Digital signal processing -G Ravi kishore. INTRODUCTION The goal of DSP is usually to measure, filter and/or compress continuous real-world analog signals.

Digital signal processing -G Ravi kishore. INTRODUCTION The goal of DSP is usually to measure, filter and/or compress continuous real-world analog signals.
Applications of Laplace Transforms Instructor: Chia-Ming Tsai Electronics Engineering National Chiao Tung University Hsinchu, Taiwan, R.O.C.

Applications of Laplace Transforms Instructor: Chia-Ming Tsai Electronics Engineering National Chiao Tung University Hsinchu, Taiwan, R.O.C.
CSE245: Computer-Aided Circuit Simulation and Verification Lecture Note 3 Model Order Reduction (1) Spring 2008 Prof. Chung-Kuan Cheng.

CSE245: Computer-Aided Circuit Simulation and Verification Lecture Note 3 Model Order Reduction (1) Spring 2008 Prof. Chung-Kuan Cheng.
CSE245: Computer-Aided Circuit Simulation and Verification Lecture Notes 3 Model Order Reduction (1) Spring 2008 Prof. Chung-Kuan Cheng.

CSE245: Computer-Aided Circuit Simulation and Verification Lecture Notes 3 Model Order Reduction (1) Spring 2008 Prof. Chung-Kuan Cheng.
UCSD CSE 245 Notes – SPRING 2006 CSE245: Computer-Aided Circuit Simulation and Verification Lecture Notes 3 Model Order Reduction (1) Spring 2006 Prof.

UCSD CSE 245 Notes – SPRING 2006 CSE245: Computer-Aided Circuit Simulation and Verification Lecture Notes 3 Model Order Reduction (1) Spring 2006 Prof.
Lecture 14: Laplace Transform Properties

Lecture 14: Laplace Transform Properties
Network Analysis and Synthesis

Network Analysis and Synthesis
6. Circuit Analysis by Laplace

6. Circuit Analysis by Laplace
Control Systems and Adaptive Process. Design, and control methods and strategies 1.

Control Systems and Adaptive Process. Design, and control methods and strategies 1.
5.7 Impulse Functions In some applications, it is necessary to deal with phenomena of an impulsive nature—for example, voltages or forces of large magnitude.

5.7 Impulse Functions In some applications, it is necessary to deal with phenomena of an impulsive nature—for example, voltages or forces of large magnitude.
1 Introduction to Model Order Reduction Luca Daniel Massachusetts Institute of Technology

1 Introduction to Model Order Reduction Luca Daniel Massachusetts Institute of Technology
EE513 Audio Signals and Systems Digital Signal Processing (Systems) Kevin D. Donohue Electrical and Computer Engineering University of Kentucky.

EE513 Audio Signals and Systems Digital Signal Processing (Systems) Kevin D. Donohue Electrical and Computer Engineering University of Kentucky.
Stability and Passivity of the Super Node Algorithm for EM modelling of ICs Maria Ugryumova Supervisor : Wil Schilders Technical University Eindhoven,

Stability and Passivity of the Super Node Algorithm for EM modelling of ICs Maria Ugryumova Supervisor : Wil Schilders Technical University Eindhoven,
ECE 8443 – Pattern Recognition EE 3512 – Signals: Continuous and Discrete Objectives: Stability and the s-Plane Stability of an RC Circuit 1 st and 2 nd.

ECE 8443 – Pattern Recognition EE 3512 – Signals: Continuous and Discrete Objectives: Stability and the s-Plane Stability of an RC Circuit 1 st and 2 nd.
In Engineering --- Designing a Pneumatic Pump Introduction System characterization Model development –Models 1, 2, 3, 4, 5 & 6 Model analysis –Time domain.

In Engineering --- Designing a Pneumatic Pump Introduction System characterization Model development –Models 1, 2, 3, 4, 5 & 6 Model analysis –Time domain.
Automatic Control Theory-

Automatic Control Theory-
SE 207: Modeling and Simulation Introduction to Laplace Transform

SE 207: Modeling and Simulation Introduction to Laplace Transform

Similar presentations

Ads by Google