Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems....
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![Page 1: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/1.jpg)
Lecture 16:
State Observer (Estimator)
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Objectives
• Define the observability of dynamic systems.
• Design state estimators (observers).
• Select the eigenvalues of the observer.
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Observability
Definition: A system is observable if the knowledge of the input u(0), u(1), …, u(n-1) and the output y(0), y(1),…,y(n-1) is sufficient to determine the initial state x(0).
Condition for observability:To derive the condition under which the system is observable, let us consider, for simplicity, the unforced system (no input):
)()(
),()1(
kCxky
kxkx
3
![Page 4: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/4.jpg)
• Note that x(0) has n unknowns. This requires n equations to have a unique solution.
• For single output systems, the matrix Δo, called the observability matrix, is of size n x n. For the system to be observable, Δo must be invertible or, more generally, be of full rank n.
)0(
)1(
)2(
)1(
)0(
)0(
)0(
)0(
)0(
)1(
)2(
)1(
)0(
x(0))(
x(0))(
1
2
1
2 x
C
C
C
C
ny
y
y
y
xC
xC
xC
Cx
ny
y
y
y
Cky
kx
known
n
known
n
k
k
o
4
![Page 5: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/5.jpg)
Example 1
Given the following discrete-time system
Check if the system is observable.
This means that x(0) can not be uniquely estimated (calculated) from input-output data sequence. That is different initial states will result in the same output sequence.
)(5.01)(
)(01
3.01.1)1(
kxky
kxkx
observablenot is system1 rank 3.06.0
5.01
C
Co
5
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State estimation
• In designing state feedback controller, we assumed that all states are measured.
• In most applications, measuring the entire state vector is impossible or prohibitively expensive.
• To implement state feedback control, an estimate of the state vector can be used.
• The state can be estimated from the input and output measurements by using a state estimator or observer. A state estimator is a mathematical construct (implemented as a part of the controller program) that helps estimate the states of a system.
)(ˆ kx
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Observer: simple idea
Consider the following system:
To estimate all the states, one could in theory use a system with the same state equation:
Here, we assume perfect knowledge of the system dynamics (i.e. the matrices Φ, Γ).
),()(ˆ)1(ˆ kukxkx
)()(
),()()1(
kCxky
kukxkx
7
![Page 8: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/8.jpg)
Simple observer: drawback• Let us examine the error dynamics of the simple observer by
subtracting the observer dynamics from the system dynamics, i.e.
• The state error dynamics are determined by the state matrix Φ. This matrix cannot be chosen arbitrarily.
• For an unstable system, the observer will be unstable and cannot track the state of the system.
xxxkxkx
kxkxkxkx
kukxkx
kukxkx
eee ˆwhere),()1(
)()(ˆ)1(ˆ)1(
)()(ˆ)1(ˆ
)()()1(
8
![Page 9: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/9.jpg)
Observer: a better idea
A practical alternative is to provide the estimator with the measured output in addition to the input as shown. This corrects the state estimate.
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• The observer will calculate the difference between the measured and the estimated output of the system and use this difference as additional input in its state equation as:
• Subtracting the observer state equation from the system dynamics yields the estimation error dynamics
))(ˆ)(()()(ˆ)1(ˆ
))(ˆ)(()()(ˆ)1(ˆ
kxCkCxLkukxkx
kykyLkukxkx
)()()1( kxLCkx ee
o
10
Observer: a better idea
![Page 11: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/11.jpg)
• The error dynamics are now governed by the eigenvalues of the observer matrix Φo.
• Thus, the gain matrix L can be designed so that Φo has eigenvalues with fast modes to guarantee fast convergence of the estimated state to the true state (i.e. to make the error in estimated state goes to zero quickly).
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Observer: a better idea
![Page 12: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/12.jpg)
Theorem: State Estimation
If the pair (Φ, C) is observable, then there exists a matrix L that arbitrarily assigns the observer poles (eigenvalues of the matrix Φo = Φ - LC) to any set {λi, i = 1, . . . , n}.
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Selecting estimator pole locations
Typically, estimator pole locations are selected so that the estimator responds two to six times faster than the controlled plant.
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Example 2
Given the following discrete-time system
Check if the system is observable and controllable. If so, design a state feedback controller as well as a state observer such that:
• The eigenvalues of the state feedback system is ½ and -½• The eigenvalues of the observer is ¼ and -¼.
)(01)(
)(1
0)(
10
10)1(
kxky
kukxkx
14
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Solution
• Check if the system is observable and controllable:
• The controllability matrix
• The observability marix
observable is system2 rank 10
01
C
Co
lecontrollab is system2rank 11
10
c
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14/11,4/1
4/1)1(
4/11
1
4/11
0
10
10
0
0
)2/1)(2/1()(
2121
212
2
2
21
221
kkKkk
kk
kk
kk
KI
16
Solution: computing the state feedback gain matrix K
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16/15
116/15,1
16/1)1(
16/11
1
)4/1)(4/1(0110
10
0
0
)4/1)(4/1()(
2
121
2211
2
2
2
1
2
1
l
lLll
lll
l
l
l
l
LCI
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Solution: observer design (computing the matrix L)
![Page 18: Lecture 16: State Observer (Estimator) 1. Objectives Define the observability of dynamic systems. Design state estimators (observers). Select the eigenvalues.](https://reader036.fdocuments.us/reader036/viewer/2022082821/5697c0141a28abf838ccd7eb/html5/thumbnails/18.jpg)
• Given the observer state matrix
• We transpose the matrix to obtain
• By this way we can use the same MATLAB command “place” as follows
Lt = place(phi’,C’,p); L = Lt’; % note that the output need to be transposed
TTTTo LC
Observer design using MATLB
LCo
18