Block Diagram Reduction Rules
Last Updated :
21 Feb, 2024
As we know a complex control system is difficult to analyze as various factors are associated with it. In this article, we will see how to easily analyze a control system, and it is only possible by using block diagram reduction rules. This representation of a system involves summing points, functional blocks, etc., connected through branches which makes the analysis easy, simple, and step by step, crystal clear.
We will start our Article with Methods of Block Diagram Reduction Rules, and Then we will go through all the rules of Block Reduction, At last, we will Solve a Problem block diagram reduction technique.
Methods of Block Diagram Reduction Rules
In a Control system, for the analysis of any system, there are two methods
- Transfer Function Approach
- State Variable Approach
Transfer Function Approach : The ratio of the Laplace transform of the output variable to the Laplace transform of the input variable assuming all the initial conditions to be zero is called Transfer Function.
State Variable Approach : The advantage of the Transfer Function Approach is that it gives a simple mathematical algebraic equation and it directly gives poles and zeroes of the system. The stability of the system and output of the system for any input can be directly determined from this approach.
Transfer Function Block DiagramTransfer Function G(S) = L[c(t)]/L[r(t)] all the initial conditions are zeroes.
G(s) = C(s) / R(s)
It is not always convenient to determine the complete transfer function for the very complex control system. Therefore function of each element of the control system is depicted in the form of a block diagram.
The symbol representation in short form gives a relation of output to input in the control system. The complete system can be formed by connecting each block as per the need of the system.
In this Article, We Will explore various block diagram reduction rules, discuss the advantages and disadvantages of this technique, and examine its applications. Additionally, a solved example will be presented to illustrate the practical application of block diagram reduction rules in simplifying complex systems.
Block Diagram Reduction Rules
To form a control system the block are arranged together as required and the steps followed to obtain the transfer function are called Block Diagram Reduction Method.
Following are the rules to be followed during finding the transfer function of the system
Rule 1 : when more than one block is cascaded than overall transfer function is multiplication of all the transfer function .
G1(s) = C1(s)/ R(s) ; G2(s) = C2(s) / C1(s) ; G3(s) = C(s) / C2(s)
C(s) / R(s) = G1(s) . G2(s) . G3(s)
Blocks in cascade 
Block in Equivalence Rule 2 : When two or more input signal enters into system that point is known as Summing Point and the output coming out from summing point will be the sum of all the input entered through summing point .
Summing Point Rule 3 : When there are two or more summing point than we can change the position of summing point with each other as shown below in fig .
.png)
Interchange of summing pointRule 4 : When one or more blocks are connected in parallel to other block than the final equivalent transfer function can be find as following
C(s) = R(s) G1(s) + R(s) G2(s) + R(s) G3(s)
C(s) = R(s) [ G1(s) + G2(s) + G3(s) ]
C(s) /R(s) = G1(s) + G2(s) + G3(s)
.png)
Blocks in Parallel
Equivalence BlocksRule 5 : When take off point is shifted from position before block to a position after block than a block is added having gain equals to reciprocal of current gain as shown below.
.png)
Shifting of take-off point from A to BRule 6 : When take off point is shifted from a position after block to a position before the block than a block is added having gain equals to current gain as shown below .
.png)
Shifting the off point from B to ARule 7 : When a summing point is shifted from a position before a block to position after the block , a block is added to summing point having gain equals to current gain .
Shifting of Summing Point from A to B Rule 8 : When a summing point is shifted from a position after a block to a position before the block , a block is added having gain equals to reciprocal of current gain .
Shifting of Summing Point from B to ARule 9 : when a take off point is shifted from a position before a summing point to position after the summing point , it takes place as shown in below fig.
Shifting of take-off point before summing point to after summing point Rule 10 : Shifting a take off point from a position after a summing point to position before summing point is shown in below fig.
Shifting of take-off point after summing point to before summing point Rule 11 : Elimination of summing point in closed loop system is done as shown in below fig .
Elimination of the Summing Point in Closed Loop Control System
Advantages of Block Diagram Reduction Rule
Following are some of the advantages of Block Diagram Reduction
- It helps to construct easily block diagrams of complex control systems.
- We can be able to analyze the performance of each block individually.
- We can easily obtain the transfer function of the given control system.
- We can easily find out the stability of the control system through the type of feedback in the system.
- We can observe the functional operation of the Block diagram through it.
Disadvantage of Block Diagram Reduction Rule
Following are some of the Disadvantages of Block Diagram Reduction
- For a complex control system it takes a lot of time.
- During the reduction of the block diagram some important functions of the system may be eliminated.
- There is no information about how the system is constructed physically.
- It does not tell about the source of energy in the system.
Applications of Block Diagram Reduction
Following are some of the Applications of Block Diagram Reduction
- Used in Hardware design.
- Used in electric System Design.
- Used in Software Design.
- Used in Process Flow Diagram.
- Used to determine the transfer function of the system
- Used to find the stability of the system.
Conclusion
The block Diagram reduction rule is a very helpful method for the determination of the transfer function of a complex system. It helps to simplify the complex control system into a simple control system so that we can analyze the stability and other performance of the system easily. It is like a handy way for engineers to troubleshoot and do the observation of complex systems by connecting a simple simple blocks to form a complete system.
Solved Problems on Block Diagram Reduction
Reduce the following block diagram using the block diagram reduction rule
Figure 1Solution :
Step 1 : G1 and G2 are connected in parallel , find its equivalent block G1 + G2
Figure 2Step 2 : Elimination of summing point before G1 + G2 having negative feedback H1 in closed loop system.
Figure 3Step 3 : Move summing point after G4 to before G4.
Figure 4Step 4 : Exchange the position of both the summing point before G4
Figure 5Step 5 : G3 /G4 and (G1 +G2) / (1+G1H1+G2H2) both blocks are connected in parallel . Find equivalent block .
Figure 6Step 6 : Eliminate summing point before G4 having negative feedback in closed loop system.
Figure 7Step 7 : Find the equivalent of both the cascaded block .
Single block diagram representation as shown below.
Figure 8
Similar Reads
Control System Tutorial In this Control System tutorial, we will analyze and understand the concept and applications of a Control System with the help of detailed modules. This tutorial covers each module from the basics to advanced, including features, examples, classifications, applications, advantages, disadvantages, an
9 min read
Introduction to Control Systems
What is Control System? Definition, Types, and ExamplesControl systems are used in a wide range of applications they are the essential parts of many modern devices and systems. In simple terms, Control systems are used to control the behavior of devices or any process. In this article, we will be discussing the topic of Control Systems. We will cover th
9 min read
Types of Control SystemsEvery activity in our daily lives is affected by some form of control system. The concept of a control system also plays an important role in the working of space vehicles, satellites, guided missiles, etc. Such control systems are now an integral part of modern industrialization, industrial process
7 min read
Components of Control SystemsWith the advancement of technology, Human dependency on control system have increased over years and are being used everywhere, playing significant role in our daily lives. Contributing to different applications, they made the work easier by reducing human effort and involvement. They are used to co
8 min read
Classification of Control SystemsIn electronics, control systems are grouped into different types, and each has its unique features and uses. They are Important in electronics engineering for regulating dynamic systems, ensuring stability, accuracy, and top performance in various applications. Understanding their classifications he
15+ min read
Uses of Control SystemControl systems have become a necessary part of our day-to-day lives. There is hardly any field where the control systems are not used. They play a very major role in many sectors by making the process much simpler. They are used in fields like transportation, healthcare, aerospace, etc. In this art
8 min read
Advantages and Disadvantages of Control SystemsControl systems play a significant role in our daily lives, impacting various applications that often go unnoticed by us. They are used to control the behavior of devices and systems to accomplish the desired task. They are made up of many components and the major components are usually sensors, con
8 min read
Classification
Open Loop Control SystemControl systems are of wide use which can be understood in a better way by the following real-life examples which we use every now and then some of the examples are Regulating the speed of a fan with regulator, Oven temperature control, Washing machine cycle selection based on the type of clothes, R
9 min read
Closed-Loop Control SystemIn this article, we're going to discuss about closed loop control system. A closed-loop control system is an electronic device that automatically regulates a system to maintain a desired state or set point without human interaction. The advantages of closed-loop control systems lie in their ability
8 min read
Linear and Non-Linear Control SystemA control system is like a manager for machines. It tells them what to do so they work the way we want. There are different kinds of control systems, like ones that follow a straight line and others that don't. They're all about making sure things work the way we need them to. In this, we will discu
7 min read
Time-Variant and Invariant Control SystemControl systems play an important role in engineering, they help in regulating and controlling a process or a system to obtain controlled output. There are different types of control systems such as Linear and non-linear systems, Causal and Non-causal systems. Time variant and Time invariant control
6 min read
Continuous Time and Discrete Time Control SystemsIn Electronic Engineering, Continuous-time and Discrete-time control systems are essential ideas that are vital to the design and optimization of a wide range of electronic systems and devices. Continuous-time control systems operate on signals that vary continuously over time, where both the input
7 min read
SISO and MIMO Control SystemsIn Electronic Engineering, there are Two Key approaches in the field of control engineering are SISO (Single Input Single Output) and MIMO (Multiple Input Multiple Output) control systems, which are essential to the design and analysis of dynamic systems. SISO systems are designed to control or modi
8 min read
Difference between Feedback and Feed Forward control systemsControl systems play an essential role in regulating processes to ensure stability and productivity, primarily through the use of feedback and feedforward control mechanisms. Feedback control systems respond to output deviations and provide precise corrections but may be slower. Feedforward control
5 min read
Difference between Open-Loop Control System and Closed-Loop Control SystemControl System is a system in which the behavior of the system is determined by a differential equation. It manages the devices and the systems using control loops. There are Open-Loop Control System and Closed-Loop Control System. Open-Loop Control System is used in applications in which no feedbac
3 min read
Feedback
Block Diagram in Control System
Block Diagram AlgebraIn this article, We will discuss about block diagram and its components. We will also discuss about the various rules involved in block diagram algebra along with its equivalent block diagram. In addition to these we will also discuss about the application, advantages and disadvantages. Table of Con
8 min read
Block Diagram Reduction - Control SystemA control system may consist of several components. To show the function performed by each component in control engineering, we commonly use a diagram called the block diagram. A block diagram of a system is a pictorial representation of the functions performed by each component and of the flow of s
8 min read
Block Diagram Reduction RulesAs we know a complex control system is difficult to analyze as various factors are associated with it. In this article, we will see how to easily analyze a control system, and it is only possible by using block diagram reduction rules. This representation of a system involves summing points, functio
7 min read
Basic Elements of Signal Flow GraphSignal Flow Graphs are a crucial component of control systems. Furthermore, the control system is one of the most significant subjects in Electronics. It is primarily covered in the sixth semester of the B.Tech syllabus, though individual universities may alter it based on their syllabus hierarchy.
10 min read
Conversion of Block Diagrams into Signal Flow GraphsIn this article, we will discuss the method of converting the block diagram into a signal flow graph in a control system. We will first discuss about signal flow graph and its terminologies. We also discuss the construction of signal flow graphs from linear equations. We will then discuss about bloc
7 min read
Mason's Gain Formula in Control SystemMason's Gain Formula, also known as Mason's Rule or the Signal Flow Graph Method, is a technique used in control systems and electrical engineering. It provides a systematic way to analyze the transfer function of a linear time-invariant (LTI) system, especially those with multiple feedback loops an
7 min read
Time Response and Time Domain Analysis
Standard Test SignalsThe standard signals are often used in control systems, signal processing, communication and various engineering applications. These are predefined signals with known characteristics. To clarify standard test signals, their uses and application in the control systems. In this article, we will be goi
15+ min read
Unit Step Signal in Control SystemA Control System is a system which manages commands and regulates or directs the behaviour of other devices using control loops. A control system is a device which provides the desired response by controlling the output. A control system can also be defined as a system with a combination of mechanic
9 min read
Unit Ramp SignalThe unit ramp signal is a fundamental and insightful instrument that engineers and researchers both will use in the field of control systems. In order to clarify the meaning, uses, and implications of the unit ramp signal in control system, this article sets out to explore its complexities. The unit
7 min read
Steady State Errors for Unity Feedback SystemsIn this Article, We will be going through Steady State Errors for Unity Feedback Systems in control systems, First, we will start our Article with an introduction to Steady State Errors, then we will through its two types, and then we will see mathematical Expression for calculating the Steady-State
11 min read
Stability Analysis
Frequency Domain Analysis
Compensators in Control System
CompensatorsAll of the topics covered in the Control System Tutorial, including the Introduction to Control Systems, Classification, Transfer Function, Signal Flow Graphs, Mason Gain Formula, Block Diagram, State Space Model, and more, are included in our tutorial. The compensator is an extra part that is intro
10 min read
Lag CompensatorA compensator is a device or component that is used to obtain the desired performance, stability, and behavior of the system. It is the part of the feedback device in a control system and is used to stabilize the system and regulate the other system with its ability of conditioning the input or outp
7 min read
Lead Compensator in control systemCompensators, which have a wide range of functionality and variants, are an essential component of Control Systems. Furthermore, the control system is an important subject in the engineering curriculum, and it incorporates many important electronics components. To understand the Lead Compensator, we
7 min read
Controllers in Control System