Introduction to Mechatronics

1. MET402 MECHATRONICS AS PER KTU-2019 SYLLABUS SUKESH O P Assistant Professor Dept. of Mechanical Engg. Jyothi Engineering College, sukeshop@jecc.ac.in/9633103837 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 1 MODULE-1 1.1 Introduction

2. GOOGLE CLASSROOM CODE 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 2

3. MET402 MECHATRONICS 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 3

4. SYLLABUS Introduction to Mechatronics, sensors, Actuators, Micro Electro Mechanical Systems (MEMS), Mechatronics in Computer Numerical Control (CNC) machines, Mechatronics in Robotics- (CNC) machines, Mechatronics in Robotics- Electrical drives, Force and tactile sensors, Image processing techniques, Case studies of Mechatronics systems. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 4

5. TEXT BOOK 1. Bolton W., Mechatronics: Electronic Control Systems in Mechanical and Electrical Engineering, Person Education Limited, New Delhi, 2007 2. Ramachandran K. P., G. K. Vijayaraghavan, M. S. Balasundaram, 2. Ramachandran K. P., G. K. Vijayaraghavan, M. S. Balasundaram, Mechatronics: Integrated Mechanical Electronic Systems, Wiley India Pvt. Ltd., New Delhi, 2008. 3. Saeed B. Niku, Introduction to Robotics: Analysis, Systems, Applications, Person Education, Inc., New Delhi, 2006. Don’t use Airwalk Publications- Mechatronics Textbook if you need to score passmark in this subject 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 5

6. MODULE-I Introduction to Mechatronics: Structure of Mechatronics system. Sensors - Characteristics - Temperature, flow, pressure sensors. Displacement, position and proximity sensing by magnetic, optical, ultrasonic, inductive, capacitive and eddy current methods. Encoders: incremental and absolute, gray coded optical, ultrasonic, inductive, capacitive and eddy current methods. Encoders: incremental and absolute, gray coded encoder. Resolvers and synchros. Piezoelectric sensors. Acoustic Emission sensors. Principle and types of vibration sensors. Actuators: Mechanical actuators, Electrical actuators, Hydraulic and Pneumatic actuators 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 6

7. MODULE-II Directional control valves, pressure control valves, process control valves. Rotary actuators. Development of simple hydraulic and pneumatic circuits using standard Symbols. Micro Electro Mechanical Systems (MEMS): Fabrication: Deposition, Lithography, Micromachining methods for MEMS, Micro Electro Mechanical Systems (MEMS): Fabrication: Deposition, Lithography, Micromachining methods for MEMS, Deep Reactive Ion Etching (DRIE) and LIGA processes. Principle, fabrication and working of MEMS based pressure sensor, accelerometer and gyroscope. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 7

8. MODULE-III Mechatronics in Computer Numerical Control (CNC) machines: Design of modern CNC machines - Mechatronics elements - Machine structure: guide ways, drives. Bearings: anti friction bearings, hydrostatic bearing and hydrodynamic bearing. hydrostatic bearing and hydrodynamic bearing. Re-circulating ball screws, pre-loading methods. Re-circulating roller screws. Measuring system for NC machines - direct and indirect measuring system. System modeling - Mathematical models and basic building blocks of general mechanical, electrical, fluid and thermal systems. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 8

9. MODULE-IV Typical elements of open and closed loop control systems. Adaptive controllers for machine tools. Programmable Logic Controllers (PLC) –Basic structure, input/ output processing. Programming: Timers, Internal Relays, Counters and Shift registers. Development of input/ output processing. Programming: Timers, Internal Relays, Counters and Shift registers. Development of simple ladder programs for specific purposes. Case studies of Mechatronics systems: Automatic camera, bar code reader, pick and place robot, automatic car park barrier system, automobile engine management system. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 9

10. MODULE V Mechatronics in Robotics-Electrical drives: DC, AC, brushless, servo and stepper motors. Harmonic drive. Force and tactile sensors. Range finders: ultrasonic and light-based range finders Robotic vision system - and light-based range finders Robotic vision system - Image acquisition: Vidicon, charge coupled device (CCD) and charge injection device (CID) cameras. Image processing techniques: histogram processing: sliding, stretching, equalization and thresholding. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 10

11. MODULE-I Introduction to Mechatronics: Structure of Mechatronics system. Sensors - Characteristics - Temperature, flow, pressure sensors. Displacement, position and proximity sensing by magnetic, optical, ultrasonic, inductive, capacitive and eddy current ultrasonic, inductive, capacitive and eddy current methods. Encoders: incremental and absolute, gray coded encoder. Resolvers and synchros. Piezoelectric sensors. Acoustic Emission sensors. Principle and types of vibration sensors. Actuators: Mechanical actuators, Electrical actuators, Hydraulic and Pneumatic actuators 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 11

12. MODULE-1 Introduction to Mechatronics : Structure of Mechatronics system. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 12

13. REVOLUTION What are the revolutions ………. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 13

14. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 14

15. DIFFERENCE B/W AUTOMATION & MECHATRONICS Automation and Robotics Engineering is the use of control systems and information technologies to reduce reduce the the need need for for human human work work in the production of goods and services Mechatronics is considered to be equal parts mechanical engineering, electrical engineering, and mechanical engineering, electrical engineering, and software programming/engineering. Mechatronics specialists often work on projects related to industrial automation but tackle other projects too. And while mechatronics is an umbrella term covering many disciplines, industrial automation is more tightly focused. It seeks to let machines perform tasks that began as solely manual duties. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 15

16. INTRODUCTION TO MECHATRONICS The term “Mechatronics" was first assigned by Mr. Tetsuro Mori, a senior engineer of the Japanese company Yaskawa, in 1969. The word "mechatronics" was registered as trademark by the company in Japan with the registration number of "46-32714" in 1971. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 16

17. MECHATRONICS Mechatronics is a multidisciplinary field of science that includes a combination of mechanical engineering, electronics, computer engineering, telecommunications engineering, systems engineering and control engineering. engineering, systems engineering and control engineering. It specifically refers to multidisciplinary approach to product and Manufacturing system design. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 17

18. MECHATRONICS - Definition Mechatronics basically refers to mechanical electronic systems and normally described as a synergistic integration of mechanical engineering, electronics and intelligent computer control in design and manufacture of products and processes. Synergistic – means various parts products and processes. In other words : synergistic integration of mechanical engineering, electronic engineering, computer technology and control engineering in development of electromechanical products, through an integrated design approach. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 18

20. MECHATRONICS 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 20

22. MODEL OF A TYPICAL MECHATRONIC SYSTEM 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 22

23. MODULES OF A MECHATRONIC SYSTEM 1. Sensing  I. Sensors  II. Signal Conditioning  III. Analog-to-Digital and Digital-to-Analog Conversion 2. Control 2. Control  I. Open Loop and Closed Loop Control 3. Action  I. Drive Circuits  II. Actuators  III. Motors 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 23

24. MODULES IN MECHATRONIC SYSTEM  IM – Interface Module  ASM – Assembly Module  PM- Processor Module.  EM- Environment Module  EM- Environment Module  CM- Communication Module  MM- Measurement Module  AM- Actuation Module  SM- Software Module 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 24

25. MODULES IN MECHATRONIC SYSTEM Environment Environment module module This module is concerned with the parameter like forces, temperature, speed and their effect on boundary of the system. This also deals with the dynamics and existence of the system and the also deals with the dynamics and existence of the system and the function. Assembly Assembly Module Module Manufacturing mechanical and structural realization, part and system integration are the activities in this module. Input information is received from actuation module and output is given to measurement module. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 25

26. MODULES IN MECHATRONIC SYSTEM Measurement Module Measurement Module Sensors and micro devices, transducers are the some components of this module, which supply information output to components of this module, which supply information output to communication module. Gathers information about system status. Actuation Module Actuation Module Hydraulic , pneumatic and electric actuators, piezo-electric devices, microcontrollers are the systems identified few in this module. This module recieves information from the communication module for execution. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 26

27. MODULES IN MECHATRONIC SYSTEM Communication Communication Module Module this is concerned with transmission of information b/w modules within the system. The input and output information's reveal the nature of signal and the system. The input and output information's reveal the nature of signal and distance over which it has to be transmitted and operating environment. This module mainly interacts with the processor module. Processor Processor Module Module This is formed by micro processors, embedded and electronic circuits. This extracts information from communication module about measurement parameters, demand settings system parameters to be processed. This module interacts with interface module and the software module for information processing. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 27

28. MODULES IN MECHATRONIC SYSTEM Software Software Module Module this module contains instructions for opening, defined algorithms, operation control programs of processor module. The nature and forms of operation control programs of processor module. The nature and forms of instruction are linked to associate and interact with processor module. Interface Interface Module Module Between various levels in the system, are interfaced for transfer of information with interaction with processor module and the system representing the world. This provides man-machine interface for user information. The information is classified by nature od i/p x o/p. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 28

29. COMPONENTS OF A MECHATRONICS SYSTEM / STRUCTURE OF A MECHATRONICS SYSTEM 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 29

31. COMPONENTS OF A MECHATRONICS SYSTEM 1. Actuators: Produce motion or cause some action. DC motor, Stepper motors, servomotors, hydraulics, pneumatics 2. Sensors: detect the state of the system parameters, inputs and outputs. Switches, Potentiometer, Strain gauge, Thermocouple, digital encoder 3. Input signal conditioning and interfacing: provide connection b/w the control 3. Input signal conditioning and interfacing: provide connection b/w the control circuits and the I/P Discrete circuits, Amplifiers, Filters, A/D,D/D 4. Digital control architectures: Control the system. Logic circuits, microcontroller, PLC 5. Output signal conditioning and interfacing : provide connection b/w the control circuits and the O/P D/A, D/D, Amplifiers, Power transisters. 6. Graphical Display : Provide visual feedback to users.LEDs, Digital displays, LCD, CRT 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 31

32. LEVELS OF MECHATRONICS SYSTEM 1. 1. Primary Primary Level Level : Integrates electrical signaling with mechanical action at the basic control level. e.g.: fluid fluid valves valves and and relay relay switches switches. . 2. 2. Secondary Secondary Level Level : Integrates microelectronics into electrically controlled devices. e e. .g g. . cassette cassette tape tape player player. . SUKESH O P/ APME/MET402- MR-2023 controlled devices. e e. .g g. . cassette cassette tape tape player player. . 3. 3. Tertiary Tertiary Level Level : Incorporates advanced control strategy using microelectronics, microprocessors and other application specific integrated circuits. e e. .g g. . microprocessor microprocessor based based electrical electrical motor motor used used for for actuation actuation purpose purpose in in robots robots. . A large factory system that is also a distributed system but which links a number of major subsystems such as machining centers, robots for part handling, automated inspection stations etc, 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 32 SUKESH O P/ APME/MET402

33. LEVELS OF MECHATRONICS SYSTEM 4. 4. Quaternary Quaternary Level Level : This level attempts to improve smartness a step ahead by introducing intelligence ( artificial neural network and fuzzy logic ) and fault detection and isolation ( F.D.I.) capability into the system. A system that incorporates intelligent control or artificial intelligence, for ex: humanoid robot. SUKESH O P/ APME/ME407- MR-2020 intelligent control or artificial intelligence, for ex: humanoid robot. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 33 SUKESH O P/ APME/ME407

34. INTRODUCTION TO MECHATRONICS SYSTEMS ADVANTAGES OF MECHATRONICS SYSTEMS  Cost effective and Very good quality.  High degree of flexibility.  Greater productivity.  Higher quantity and producing reliability.  Greater extent of machine utilization.  Maintenance cost is less.  Machining of complex designs can be done. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 34

35.  High initial cost.  Skilled worker is required.  Fault detection s complex. INTRODUCTION TO MECHATRONICS SYSTEMS DISADVANTAGES OF MECHATRONICS SYSTEMS  Complicated design and system 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 35

36.  High quality product.  High reliability and Safety.  Low cost. INTRODUCTION TO MECHATRONICS SYSTEMS FEATURES/CHARACTERISTICS OF MECHATRONICS SYSTEMS  Low cost.  Portable.  Produced quickly.  Serviceability, maintainability and upgradability. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 36

37.  Automotives.  Flexible manufacturing systems(FMS).  Measurement systems. SUKESH O P/ APME/MET402- MR-2023 INTRODUCTION TO MECHATRONICS SYSTEMS APPLICATIONS OF MECHATRONICS SYSTEMS  Cd/DVD and setup boxes.  Robots employed in inspection and welding operations.  Scanners/photocopier/fax .  Automatic washing machines.  Air conditioners, elevator controls. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 37 SUKESH O P/ APME/MET402

38.  Better design of products.  Better process planning.  Reliable and quality oriented manufacturing. INTRODUCTION TO MECHATRONICS SYSTEMS SCOPE OF MECHATRONICS SYSTEMS  Reliable and quality oriented manufacturing.  Intelligent process and production control.  Manufacturing of complex parts.  More Accurate and more precision of jobs. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 38

39. SYSTEM SYSTEM System is a group of physical components combined to perform a specific function. All mechatronics devices consist of systems. A system can be considered as a box that has an input and an output. A control system can be considered as a device that is used to control the output of the system to a desired value. Ex: domestic air-conditioning 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 39

40. SYSTEM Electric Generator Output Input Mechanical rotation Electric power 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 40

41. MEASUREMENT SYSTEMS MEASUREMENT SYSTEMS Digital Tachometer Output Input Rotation of a shaft Number on the LED display SUKESH O P/ APME/ME407- MR-2020 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 41 shaft LED display SUKESH O P/ APME/ME407

42. INTRODUCTION TO MEASUREMENT SYSTEMS INTRODUCTION TO MEASUREMENT SYSTEMS Elements of measuring system 1. Transducer : is a sensing that converts a physical input into output, usually voltage. 2. Signal processor: performs filtering and amplification 2. Signal processor: performs filtering and amplification functions. 3. Recorder: records or displays the output of signal processor. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 42 Transducer Signal Processor Recorder

43. FUNCTIONS FUNCTIONS OF OF INSTRUMENTS INSTRUMENTS AND AND MEASUREMENT MEASUREMENT SYSTEMS SYSTEMS 1. 1. Indicating Indicating function function: : Examples :- (1) A pressure gauge is used for indicating pressure. (2) The deflection of a pointer of a speedometer indicates the speed of the automotive at that moment. 2. 2. Recording Recording function function: Examples :- (1) A potentiometer type of 2. 2. Recording Recording function function: Examples :- (1) A potentiometer type of recorder used for monitoring temperature records the instantaneous values of temperatures on a strip chart recorder. 3. 3. Controlling Controlling function function: : This is one of the most important functions specially in the field of industrial control processes. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 43

44. APPLICATIONS OF MEASUREMENT SYSTEMS APPLICATIONS OF MEASUREMENT SYSTEMS 1 1. . Monitoring Monitoring of of processes processes and and operations operations: : Example : (1) A voltmeter indicates the value of current or voltage being monitored(measured) at a particular instant. (2)Water and electric energy meters. 2 2. . Control Control of of processes processes and and operation operation: : Example : (1) Typical refrigeration system which employs a thermostatic control. (2) A temperature measuring device senses the room temperature thus providing the information necessary for proper functioning of the control system. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 44

45. APPLICATIONS OF MEASUREMENT SYSTEMS APPLICATIONS OF MEASUREMENT SYSTEMS 3. Experimental engineering analysis: 3. Experimental engineering analysis: (1) Determination of system parameters, variables and performance indices. SUKESH O P/ APME/MET402- MR-2023 (2) Testing the validity of theoretical predictions. (3) Solutions of mathematical relationships with the help of analogies. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 45 SUKESH O P/ APME/MET402

46. MEASUREMENT SYSTEM PERFORMANCE MEASUREMENT SYSTEM PERFORMANCE 1. Static characteristics a. Accuracy b. sensitivity c. Reproducibility d. Static error. 2. Dynamic characteristics a. speed of response b. Measuring lag. c. Fidelity d. Dynamic error 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 46

47. CONTROL SYSTEMS CONTROL SYSTEMS A control system is an arrangement of physical components connected or related in such a manner as to command, direct or regulate itself or another system. The basic functions of control systems are: The basic functions of control systems are: - to minimize the error b/w the actual and the desired output. - to minimize the time response to load changes in the system. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 47

48. REQUIREMENTS OF A CONTROL SYSTEM REQUIREMENTS OF A CONTROL SYSTEM 1. Stability : for any change in the input signal, the output of the system reads or makes its response at reasonable value. 2. Accuracy : the closeness of the measured value to the true 2. Accuracy : the closeness of the measured value to the true value is known as accuracy. 3. Response : the quickness with which an instrument responds to a change in the output signal is known us response. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 48

49. EXAMPLES OF CONTROL SYSTEM APPLICATIONS EXAMPLES OF CONTROL SYSTEM APPLICATIONS 1. Steering control of automobile. 2. Printwheel control system. 3. Industrial sewing machines. 3. Industrial sewing machines. 4. Sun-tracking control of solar collectors. 5. Speed control systems. 6. Temperature control of an electric furnace. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 49

50. ELEMENTS OF A CONTROL SYSTEM ELEMENTS OF A CONTROL SYSTEM 1. Control variable The quantity or condition of the controlled system which can be directly measured and controlled is called Controlled variable. variable. 2. Indirectly controlled variable The quantity or condition related to controlled variable, but cannot be directly measured is called Indirectly controlled variable 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 50

51. ELEMENTS OF A CONTROL SYSTEM ELEMENTS OF A CONTROL SYSTEM 3 3. . Command Command : : The input which can be independently varied is called Command. 4 4. . Reference Reference input input: : A standard signal used for comparison in the close-loop system. close-loop system. 5 5. . Actuating Actuating signal signal: : The difference between the feedback signal is called Actuating signal. 6 6. . Disturbance Disturbance: : Any signal other than the reference which affects the system performance is called disturbance. 7 7. . System System error error: : The difference between the actual value and ideal value is called System error. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 51

52. TYPES OF CONTROL SYSTEMS TYPES OF CONTROL SYSTEMS Open-loop control systems or Non-feedback control systems. Closed-loop control systems or Feedback control systems. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 52

53. OPEN OPEN- -LOOP CONTROL SYSTEMS LOOP CONTROL SYSTEMS 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 53

54. ADVANTAGES AND DISADVANTAGES OF OLS ADVANTAGES AND DISADVANTAGES OF OLS ADV: Simple construction. Easy maintenance. Less cost. Has better reliability and stability. LIMITATIONS Presence of non-linearities causes malfunctioning. The error cannot be corrected. The control action depends upon input command. Its not suitable for rough works. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 54

55. CLOSED CLOSED- -LOOP CONTROL SYSTEMS LOOP CONTROL SYSTEMS 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 55

56. ADVANTAGES AND DISADVANTAGES OF CLS ADV More accurate Control action basically depends upon feedback. SUKESH O P/ APME/MET402- MR-2023 Control action basically depends upon feedback. Change in system component is automaticaly taken care of. DISADV: The system is complicated and expensive. The system may become unstable. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 56

57. Some examples: Washing machine The electric switch Feedforward control system Microwave oven Air conditioner Liquid level control Feedback control system 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 57

58. Open-loop 1. Less accurate 2. Generally build easily 3. Stability can be ensured. 4. The control adjustment depends Closed-loop 1. More accurate. 2. Generally complicated and costly 3. May become unstable at times. 4. The control adjustment depends upon human judgment and estimate. 5. Any change is system component cannot be taken care of automatically. 3. May become unstable at times. 4. The control adjustment depends on output and feedback element. 5. Change in system component is automatically taken care of. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 58

59. FEED BACK PRINCIPLE FEED BACK PRINCIPLE The required level of control in open-loop systems depends only on human judgment. So, the performance of a control system can be improved by upgrading the skill of the operator and the nature of the measurement. Only with experience is one able to predict the results obtained. obtained. Ex: Ironbox 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 59

60. BASIC ELEMENTS OF A FEEDBACK SYSTEM BASIC ELEMENTS OF A FEEDBACK SYSTEM 1 1. . Forward Forward path path: : The forward path consist of 1. 1. Error Error- -detecting detecting device device: : it is a device that receives the output signal and compares it with a standard value. It also gives the command o/p signal at each &every also gives the command o/p signal at each &every instant. 2. 2. Amplifier Amplifier : : it amplifies the o/p signal to a suitable/ required scale. 3. 3. Compensating Compensating network network: : it improves the overall performance of the system. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 60

61. BASIC ELEMENTS OF A FEEDBACK SYSTEM BASIC ELEMENTS OF A FEEDBACK SYSTEM 2 2. . Feedback Feedback system system: : This is the path that sends the information about the o/p signal at each and every instant to the error-detecting device. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 61

62. CLASSIFICATION OF FEEDBACK CONTROL SYSTEMS CLASSIFICATION OF FEEDBACK CONTROL SYSTEMS 1. Regulatory systems. 2. Follow-up system. 3. Servo-mechanism systems. SUKESH O P/ APME/MET402- MR-2023 3. Servo-mechanism systems. 4. Continuous data feedback systems. 5. Sampled or discrete data control systems. 4/20/2023 62

63. CLASSIFICATION OF FEEDBACK CONTROL SYSTEMS 1 1. . Regulatory Regulatory systems systems: : this feedback control system is used when the input signal is constant, for ex: Refrigerator, Iron box 2 2. . Follow Follow- -up up system system: : this feedback control system is used when the input signal changes at each and every instant and where the input signal changes at each and every instant and where the output follows the input signal closely, Ex: Cam and follower mechanism 3 3. . Servo Servo mechanism mechanism system system: : This feedback control system is used where the mechanical quantity output with time derivatives is used. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 63

64. CLASSIFICATION OF FEEDBACK CONTROL SYSTEMS CLASSIFICATION OF FEEDBACK CONTROL SYSTEMS 4 4. . Continuous Continuous data data feedback feedback systems systems: : This feedback control system is used where the input signal has functions of the continuous time variable. Ex: Potentiometers. SUKESH O P/ APME/MET402- MR-2023 Ex: Potentiometers. 5 5. . Sampled Sampled or or discrete discrete data data control control systems systems: : This feedback control system is mainly used in input signals that have pulses or have numerical codes. Ex: A/D converter and Digital to Analog(D/A) converter. 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 64 SUKESH O P/ APME/MET402

65. 13-2-23, 4TH HOUR Absentees: 3,7,13,19,32,33,37,49,57,59,63,64,66, 14-02-2023, 2nd hour 14-02-2023, 2 hour Absentees : 7,13,18,30,40,53,64,66, 4th hour Absentees: 7,13,18,30,40,53,57,59,64,66 4/20/2023 SUKESH O P/ APME/MET402- MR-2023 65

Introduction to Mechatronics

Introduction to Mechatronics

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