SIGNIFICANCE OF BLOCK DIAGRAM AND SIGNAL FLOW GRAPH IN CONTROL SYSTEM
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SIGNIFICANCE OF BLOCK DIAGRAM AND SIGNAL FLOW GRAPH IN CONTROL SYSTEM
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SIGNIFICANCE OF BLOCK DIAGRAM AND SIGNAL FLOW GRAPH IN CONTROL SYSTEM
- 1. SIGNIFICANCE OF BLOCK DIAGRAM AND SIGNAL FLOW GRAPH IN CONTROL SYSTEM
- 2. CONTENT BLOCK DIAGRAM BLOCK DIAGRAM REDUCTION WHY SIGNAL FLOW GRAFH MANSON’S GAIN FORMULA SIGNIFICANCE OF B.D. &SFG CONCLUSION REFERENCES
- 3. BLOCK DIAGRAMS A block diagram of a system is a pictorial representation of the functions performed by each component and of the flow of signals. Such diagram depicts the interrelationships that exist among the various components. Differing from a purely abstract mathematical representation, a block diagram has the advantage of indicating more realistically the signal flows of the actual system.
- 4. • In a block diagram all system variables are linked to each other through functional blocks. • The functional block or simply block is a symbol for the mathematical operation on the input signal to the block that produces the output. • The transfer functions of the components are usually entered in the corresponding blocks, which are connected by arrows to indicate the direction of the flow of signals. The arrowhead pointing toward the block indicates the input. the arrowhead leading away from the block represents the output. Such arrows are referred to as signals.
- 5. Summing point and branch (pickoff) point Summing Point. A circle with a cross is the symbol that indicates a summing operation. The plus or minus sign at each arrowhead indicates whether that signal is to be added or subtracted. Branch Point. A branch point is a point from which the signal from a block goes concurrently to other blocks or summing points. Summing point Block diagram of a Closed-loop system
- 6. Three basic forms G1 G2 G2 G1 G1 H1 G1 G2 G1 G2 G1 G1 H11+ cascade parallel feedback
- 7. 2 block diagram reduction 2 block diagram transformations behind a block x1 y G ± x2 ± x1 x2 y G G Ahead a block ± x1 x2 y G x1 y G ± x21/G 1. Moving a summing point to be:
- 8. 2. block diagram reduction 2. Moving a pickoff point to be: behind a block G x1 x2 y G x1 x2 y 1/G ahead a block G x1 x2 y G G x1 x2 y
- 9. 2. block diagram reduction 3. Interchanging the neighboring— Summing points x3 x1 x2 y+ - x1 x3 y+ - x2 Pickoff points y x1 x2 y x1 x2
- 10. 2. block diagram reduction 4. Combining the blocks according to three basic forms. Notes: 1. Neighboring summing point and pickoff point can not be interchanged! 2. The summing point or pickoff point should be moved to the same kind! 3. Reduce the blocks according to three basic forms! Examples:
- 11. Moving pickoff point G1 G2 G3 G4 H3 H2 H1 a b G4 1 G1 G2 G3 G4 H3 H2 H1 Example 2.1
- 12. G2 H1 G1 G3 Moving summing point Move to the same kind G1 G2 G3 H1 G1 Example 2.2
- 13. G1 G4 H3 G2 G3 H1 Disassembling the actions H1 H3 G1 G4 G2 G3 H3H1 Example 2.19
- 14. SIGNAL FLOW GRAPHS (SFG) Why SFG? Block Diagrams are adequate for representation, but cumbersome. The “flow graph gain formula” (Mason) allows the system transfer function to be directly computed without manipulation or reduction of the diagram. SFG looks compact
- 15. 3. Signal-Flow Graph Block diagram reduction ——is not convenient to a complicated system. Signal-Flow graph —is a very available approach to determine the relationship between the input and output variables of a sys- tem, only needing a Mason’s formula without the complex reduc- tion procedures. 3.1 Signal-Flow Graph only utilize two graphical symbols for describing the relation- ship between system variables。 Nodes, representing the signals or variables. Branches, representing the relationship and gain Between two variables. G
- 16. b 3. Signal-Flow Graph Example 3.1 34 203 312 2101 hxx gxfxx exdxx cxbxaxx x4x3x2x1 x0 h f g e d c a 3.2 some terms of Signal-Flow Graph Path — a branch or a continuous sequence of branches traversing from one node to another node. Path gain — the product of all branch gains along the path.
- 17. Signal-Flow Graph Loop —— a closed path that originates and terminates on the same node, and along the path no node is met twice. 3.2.3 Mason’s gain formula Loop gain —— the product of all branch gains along the loop. Touching loops —— more than one loops sharing one or more common nodes. Non-touching loops — more than one loops they do not have a common node. 321 1 1 )( )( )( LLL P sR sC sG m k kk
- 18. Manson’s gain formula oops.touching l3 non- tion ofll combinaducts of ae gain prosum of thL oops.touching l2 non- ion ofl combinatucts of algain prodsum of theL sloop gaindifferentsum of allL Δre zero inrd path, ak-th forwatouch the s, whichranch gainmake the bf pcofactor o inrd path gak-th forwap 3 kk k . . : 2 1 321 1 1 LLL P sR sC sG m k kk )( )( )(
- 19. Signal-Flow Graph Example 3.3 )(1; 1 )()(1 22 11 cdbfhP adghP bgegecdb x4x3x2x1 x0 h f g e d c b a bgegecdb cdbfhadgh x x G 1 )1( 0 4 321 1 1 )( )( )( LLL P sR sC sG m k kk
- 20. 1.SIMPLE AMPLIFIER 2.containing a two-port network
- 21. • Position servo and signal flow graph
- 22. CONCLUSION • The B.D. & SFG modeling may provide control engineers with a better understanding of the composition and interconnection of component of system • It can be used together with transfer function, to describe the cause-effect relationships throughout the system
- 23. TEXT BOOK CONTROL SYSTEM:- by I.J.NAGARATH LINEAR CONTROL SYSTEM:- D. Roy Choudhury Google.com