Modeling & Simulation of Dynamic Systems

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Modeling & Simulation of Dynamic Systems Lecture-2 Block Diagram & Signal Flow Graph Representation of Control Systems Dr. Imtiaz Hussain email: imtiaz.hussain@faculty.muet.edu.pk URL :http://imtiazhussainkalwar.weebly.com/

Introduction A Block Diagram is a shorthand pictorial representation of the cause-and-effect relationship of a system. The interior of the rectangle representing the block usually contains a description of or the name of the element, or the symbol for the mathematical operation to be performed on the input to yield the output. The arrows represent the direction of information or signal flow.

Introduction The operations of addition and subtraction have a special representation. The block becomes a small circle, called a summing point, with the appropriate plus or minus sign associated with the arrows entering the circle. The output is the algebraic sum of the inputs. Any number of inputs may enter a summing point. Some books put a cross in the circle.

Introduction In order to have the same signal or variable be an input to more than one block or summing point, a takeoff point is used. This permits the signal to proceed unaltered along several different paths to several destinations.

Example-1 Consider the following equations in which x1, x2,. . . , xn, are variables, and a1, a2,. . . , an , are general coefficients or mathematical operators.

Exercise-1 Draw the Block Diagrams of the following equations.

Canonical Form of A Feedback Control System

Characteristic Equation The control ratio is the closed loop transfer function of the system. The denominator of closed loop transfer function determines the characteristic equation of the system. Which is usually determined as:

Example-2 Open loop transfer function Feed Forward Transfer function control ratio feedback ratio error ratio closed loop transfer function characteristic equation closed loop poles and zeros if K=10.

Reduction techniques 1. Combining blocks in cascade 2. Combining blocks in parallel

Reduction techniques 3. Moving a summing point behind a block

3. Moving a summing point ahead of a block 4. Moving a pickoff point behind a block 5. Moving a pickoff point ahead of a block

6. Eliminating a feedback loop 7. Swap with two neighboring summing points

Example-3 For the system represented by the following block diagram determine: Open loop transfer function Feed Forward Transfer function control ratio feedback ratio error ratio closed loop transfer function characteristic equation closed loop poles and zeros if K=10.

Example-3 First we will reduce the given block diagram to canonical form

Example-3

Example-3 Open loop transfer function Feed Forward Transfer function control ratio feedback ratio error ratio closed loop transfer function characteristic equation closed loop poles and zeros if K=10.

Exercise-2 For the system represented by the following block diagram determine: Open loop transfer function Feed Forward Transfer function control ratio feedback ratio error ratio closed loop transfer function characteristic equation closed loop poles and zeros if K=100.

Example-4 _ + _ + +

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Example-5 Find the transfer function of the following block diagrams

Example-5 Solution: 1. Moving pickoff point A behind block

Example-5 2. Eliminate loop I and Simplify feedback Not feedback

Example-5 3. Eliminate loop II & IIII

Example-5 2. Eliminate loop I & Simplify

Example-5 3. Eliminate loop II

Superposition of Multiple Inputs

Multiple Input System. Determine the output C due to inputs R and U using the Superposition Method. Example-6

Example-6

Example-6

Exercise-3: Multi-Input Multi-Output System Exercise-3: Multi-Input Multi-Output System. Determine C1 and C2 due to R1 and R2.

Introduction Alternative method to block diagram representation, developed by Samuel Jefferson Mason. Advantage: the availability of a flow graph gain formula, also called Mason’s gain formula. A signal-flow graph consists of a network in which nodes are connected by directed branches. It depicts the flow of signals from one point of a system to another and gives the relationships among the signals.

Fundamentals of Signal Flow Graphs Consider a simple equation below and draw its signal flow graph: The signal flow graph of the equation is shown below; Every variable in a signal flow graph is designed by a Node. Every transmission function in a signal flow graph is designed by a Branch. Branches are always unidirectional. The arrow in the branch denotes the direction of the signal flow.

Signal-Flow Graph Models Example-7: R1 and R2 are inputs and Y1 and Y2 are outputs

Signal-Flow Graph Models Exercise-4: r1 and r2 are inputs and x1 and x2 are outputs

Signal-Flow Graph Models Example-8: xo is input and x4 is output b x4 x3 x2 x1 x0 h f g e d c a

Construct the signal flow graph for the following set of simultaneous equations. There are four variables in the equations (i.e., x1,x2,x3,and x4) therefore four nodes are required to construct the signal flow graph. Arrange these four nodes from left to right and connect them with the associated branches. Another way to arrange this graph is shown in the figure.

Terminologies An input node or source contain only the outgoing branches. i.e., X1 An output node or sink contain only the incoming branches. i.e., X4 A path is a continuous, unidirectional succession of branches along which no node is passed more than ones. i.e., A forward path is a path from the input node to the output node. i.e., X1 to X2 to X3 to X4 , and X1 to X2 to X4 , are forward paths. A feedback path or feedback loop is a path which originates and terminates on the same node. i.e.; X2 to X3 and back to X2 is a feedback path. X1 to X2 to X3 to X4 X1 to X2 to X4 X2 to X3 to X4

Terminologies A self-loop is a feedback loop consisting of a single branch. i.e.; A33 is a self loop. The gain of a branch is the transmission function of that branch. The path gain is the product of branch gains encountered in traversing a path. i.e. the gain of forwards path X1 to X2 to X3 to X4 is A21A32A43 The loop gain is the product of the branch gains of the loop. i.e., the loop gain of the feedback loop from X2 to X3 and back to X2 is A32A23. Two loops, paths, or loop and a path are said to be non-touching if they have no nodes in common.

Consider the signal flow graph below and identify the following Example-9: Input node. Output node. Forward paths. Feedback paths (loops). Determine the loop gains of the feedback loops. Determine the path gains of the forward paths. Non-touching loops

Consider the signal flow graph below and identify the following Example-9: There are two forward path gains;

Consider the signal flow graph below and identify the following Example-9: There are four loops

Consider the signal flow graph below and identify the following Example-9: Nontouching loop gains;

Consider the signal flow graph below and identify the following Example-10: Input node. Output node. Forward paths. Feedback paths. Self loop. Determine the loop gains of the feedback loops. Determine the path gains of the forward paths.

Input and output Nodes Example-10: Input node Output node

(c) Forward Paths Example-10:

(d) Feedback Paths or Loops Example-10:

(d) Feedback Paths or Loops Example-10:

(d) Feedback Paths or Loops Example-10:

(d) Feedback Paths or Loops Example-10:

(e) Self Loop(s) Example-10:

(f) Loop Gains of the Feedback Loops Example-10:

(g) Path Gains of the Forward Paths Example-10:

Mason’s Rule (Mason, 1953) The block diagram reduction technique requires successive application of fundamental relationships in order to arrive at the system transfer function. On the other hand, Mason’s rule for reducing a signal-flow graph to a single transfer function requires the application of one formula. The formula was derived by S. J. Mason when he related the signal-flow graph to the simultaneous equations that can be written from the graph.

Mason’s Rule: The transfer function, C(s)/R(s), of a system represented by a signal-flow graph is; Where n = number of forward paths. Pi = the i th forward-path gain. ∆ = Determinant of the system ∆i = Determinant of the ith forward path ∆ is called the signal flow graph determinant or characteristic function. Since ∆=0 is the system characteristic equation.

Mason’s Rule: ∆ = 1- (sum of all individual loop gains) + (sum of the products of the gains of all possible two loops that do not touch each other) – (sum of the products of the gains of all possible three loops that do not touch each other) + … and so forth with sums of higher number of non-touching loop gains ∆i = value of Δ for the part of the block diagram that does not touch the i-th forward path (Δi = 1 if there are no non-touching loops to the i-th path.)

Systematic approach Calculate forward path gain Pi for each forward path i. Calculate all loop transfer functions Consider non-touching loops 2 at a time Consider non-touching loops 3 at a time etc Calculate Δ from steps 2,3,4 and 5 Calculate Δi as portion of Δ not touching forward path i

Example-11: Apply Mason’s Rule to calculate the transfer function of the system represented by following Signal Flow Graph Therefore, There are three feedback loops

∆ = 1- (sum of all individual loop gains) Example-11: Apply Mason’s Rule to calculate the transfer function of the system represented by following Signal Flow Graph ∆ = 1- (sum of all individual loop gains) There are no non-touching loops, therefore

∆1 = 1- (sum of all individual loop gains)+... ∆1 = 1 Example-11: Apply Mason’s Rule to calculate the transfer function of the system represented by following Signal Flow Graph ∆1 = 1- (sum of all individual loop gains)+... Eliminate forward path-1 ∆1 = 1 ∆2 = 1- (sum of all individual loop gains)+... Eliminate forward path-2 ∆2 = 1

Example-11: Continue

Exercise-5: Apply Mason’s Rule to calculate the transfer function of the system represented by following Signal Flow Graph

Exercise-6 Find the transfer function, C(s)/R(s), for the signal-flow graph in figure below.

Example-12: Apply Mason’s Rule to calculate the transfer function of the system represented by following Signal Flow Graph There are three forward paths, therefore n=3.

Example-12: Forward Paths

Example-12: Loop Gains of the Feedback Loops

Example-12: two non-touching loops

Example-12: Three non-touching loops

From Block Diagram to Signal-Flow Graph Models Example-13: - C(s) R(s) G1 G2 H2 H1 G4 G3 H3 E(s) X1 X2 X3 -H1 R(s) 1 E(s) G1 X1 G2 X2 G3 X3 G4 C(s) -H3 -H2

From Block Diagram to Signal-Flow Graph Models Example-13: R(s) -H2 1 G4 G3 G2 G1 C(s) -H1 -H3 X1 X2 X3 E(s)

Exercise-7 G1 G2 + - C(s) R(s) E(s) Y2 Y1 X1 X2

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