INDUSTRIAL AUTOMATION AND CONTROLLER CHAPTER 5

1. Chapter 5
Automation
SM
AP,EED, SurTech
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2. PLC (Programmable logic controllers)
• Overview
 PLC stands for Programmable Logic Controller, which is a digital computer used for automation of industrial
processes. It is a ruggedized computer that is designed to control machinery and processes in factories and
other industrial settings.
 PLCs are used for a variety of applications, including controlling assembly lines, automating equipment,
managing power grids, and more. They are widely used in industries such as manufacturing, energy,
automotive, aerospace, and food processing.
 The basic components of a PLC include a processor, input and output modules, communication modules,
and a power supply. The processor is the brain of the PLC, and it executes the program that controls the
inputs and outputs. Input modules are used to collect data from sensors and other devices, while output
modules are used to send signals to actuators and other equipment. Communication modules allow the PLC
to communicate with other devices and systems, such as sensors, HMIs (Human Machine Interfaces), or
SCADA (Supervisory Control and Data Acquisition) systems.
 PLCs are programmed using ladder logic, which is a graphical programming language that uses symbols to
represent electrical circuits. This language is intuitive and easy to use for engineers and technicians, making
it popular in industrial automation.
 Overall, PLCs provide a reliable and efficient solution for automating industrial processes, helping to improve
safety, increase productivity, and reduce costs.
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3. • Operation and Architecture
 PLCs operate by executing a program that controls the inputs and outputs of a system. The program is written in ladder logic or other programming
languages and is stored in the PLC's memory. When the program is executed, the PLC reads the input signals from sensors and other devices, processes
the data using the program, and sends output signals to control actuators and other equipment.
 The architecture of a PLC consists of several components:
1. Processor: The processor is the main component of the PLC, responsible for executing the program and controlling the inputs and outputs.
2. Input and output modules: These modules are used to interface with the real world. Input modules are used to collect data from sensors and other
devices, while output modules are used to send signals to actuators and other equipment.
3. Memory: PLCs have several types of memory, including program memory, data memory, and retentive memory. Program memory stores the
program that controls the system, while data memory stores temporary data used by the program. Retentive memory stores data that needs to be
retained even when the PLC is turned off.
4. Communication modules: Communication modules allow the PLC to communicate with other devices and systems, such as sensors, HMIs, or SCADA
systems. They enable the PLC to receive and send data to other devices, making it possible to integrate the PLC with other systems.
5. Power supply: The power supply provides power to the PLC's components, ensuring that the system operates reliably and safely.
 Overall, the architecture of a PLC is designed to provide a robust and reliable solution for controlling industrial processes. The various components work
together to ensure that the system operates smoothly and efficiently, helping to improve safety, productivity, and profitability.
PLC (Programmable logic controllers)
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5. PLC (Programmable logic controllers)
• PLC Programming
 PLC programming involves writing a program in a language such as ladder logic or other programming languages, which is then loaded into the PLC's
memory. Here are the basic steps for programming a PLC:
1. Define the control requirements: Identify the control requirements for the system and determine the inputs and outputs that will be used to control
the system.
2. Choose a programming language: Select a programming language such as ladder logic, structured text, or function block diagram that is appropriate
for the application.
3. Create the program: Write the program using the chosen programming language. The program should define the logic that controls the inputs and
outputs of the system.
4. Test the program: Test the program to ensure that it works correctly. This can be done by simulating the inputs and outputs, or by connecting the PLC
to the system and monitoring the behavior of the system.
5. Download the program to the PLC: Once the program has been tested and is working correctly, download it to the PLC's memory using a
programming cable and software.
6. Monitor and troubleshoot: Monitor the system to ensure that it is operating as expected. If there are any issues, use troubleshooting tools to
identify and fix the problem.
7. Document the program: Document the program by creating documentation that explains how the system is controlled and how the program works.
 Overall, PLC programming involves defining the control requirements, creating a program that controls the inputs and outputs of the system, and testing
and debugging the program to ensure that it works correctly. The program is then loaded into the PLC's memory, and the system is monitored and
maintained to ensure that it continues to operate correctly.
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6. PLC (Programmable logic controllers)
• PLC Application Examples:
 PLC (Programmable Logic Controller) is a versatile automation tool that can be used to control a wide range of industrial and commercial applications. Here are some examples
of PLC applications:
1. Assembly lines: PLCs are widely used to control assembly lines in manufacturing plants. They can be programmed to control the speed of conveyor belts, turn on and off
machines, and detect defects in products.
2. Food processing: PLCs can be used in food processing plants to control temperature, humidity, and pressure levels in storage and processing areas. They can also control
mixing and cooking processes and monitor the quality of food products.
3. Traffic signals: Traffic signals can be controlled by PLCs to regulate the flow of traffic and prevent accidents. They can be programmed to respond to changes in traffic
volume and to adjust the timing of signals accordingly.
4. Water treatment plants: PLCs can be used to control the water treatment process in plants. They can monitor water levels, adjust the flow of water, and control the
amount of chemicals added to the water.
5. HVAC systems: PLCs can be used to control heating, ventilation, and air conditioning (HVAC) systems in buildings. They can adjust temperature, humidity, and air flow
levels to maintain a comfortable and healthy indoor environment.
6. Packaging machines: PLCs can be used to control packaging machines in factories. They can regulate the speed of conveyor belts, control the flow of materials, and ensure
that products are packaged correctly.
7. Elevators: PLCs can be used to control elevators in buildings. They can control the movement of the elevator car, detect malfunctions, and ensure that the elevator is safe
and reliable.
8. Robotics: PLCs can be used to control robots in manufacturing plants. They can control the movement of robot arms, adjust the speed and force of movements, and detect
malfunctions.
9. Power plants: PLCs can be used to control power plants. They can monitor the performance of generators, adjust power output levels, and detect malfunctions.
10. Oil and gas refineries: PLCs can be used to control oil and gas refineries. They can monitor the flow of materials, adjust temperature and pressure levels, and detect
malfunctions.
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7. DCS (Distributed control systems)
• Overview
 DCS (Distributed Control System) is a type of industrial control system that is used to automate and control complex
processes in manufacturing, chemical processing, power generation, and other industries. DCS is designed to handle
large-scale, complex, and geographically distributed systems.
 A DCS system consists of multiple controllers that are connected to a central computer or server. Each controller is
responsible for a specific section of the plant or process, and they work together to ensure that the entire system is
operating efficiently. The controllers are connected to sensors, actuators, and other devices that monitor and control
the process variables, such as temperature, pressure, flow rate, and level.
 DCS systems typically include a human-machine interface (HMI) that allows operators to monitor the system and
make adjustments as needed. The HMI displays real-time data from the system, such as process variables, alarms, and
trends. Operators can use the HMI to adjust set points, change operating modes, and respond to alarms and alerts.
 One of the key advantages of DCS is its distributed architecture, which allows the system to be scaled and expanded
as needed. DCS systems can also be configured for redundancy, which means that multiple controllers can be used to
ensure that the system continues to operate even if one or more controllers fail.
 DCS systems can also be integrated with other systems, such as enterprise resource planning (ERP) systems and
supervisory control and data acquisition (SCADA) systems. This integration allows data to be shared between systems,
which can help improve efficiency, reduce downtime, and increase productivity.
 Overall, DCS systems are a powerful tool for controlling and automating complex processes in industrial settings. They
offer a high level of flexibility, scalability, and integration, which makes them an ideal solution for a wide range of
industries and applications.
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8. DCS (Distributed control systems)
• Advantage
• DCS (Distributed Control System) has several advantages in industrial settings. Here are some of the main advantages:
 Improved process control: DCS systems are designed to provide precise control over complex industrial processes. They can monitor and control
multiple process variables, such as temperature, pressure, flow rate, and level, simultaneously. This ensures that the process is operating efficiently and
within desired parameters, which can improve product quality and reduce waste.
 Scalability: DCS systems are designed to be scalable, which means that they can be expanded or upgraded as needed to accommodate changes in the
process or plant. This allows companies to start with a smaller system and add more controllers, I/O points, and software modules as their needs
change.
 Redundancy: DCS systems can be configured for redundancy, which means that multiple controllers can be used to ensure that the system continues to
operate even if one or more controllers fail. This can help prevent downtime and ensure that the process remains safe and reliable.
 Flexibility: DCS systems are highly flexible and can be configured to meet the specific needs of a particular process or plant. They can be customized with
software modules and I/O cards to perform specific functions, such as motor control, discrete I/O, or advanced process control.
 Centralized management: DCS systems provide centralized management and monitoring of the process. Operators can monitor the process variables
and make adjustments as needed from a central location. This improves efficiency and reduces the risk of errors or accidents caused by manual
interventions.
 Data collection and analysis: DCS systems collect large amounts of data from the process, which can be used for analysis and optimization. This data can
be used to identify trends, predict future performance, and improve the efficiency and reliability of the process.
 Overall, DCS systems are a powerful tool for controlling and automating industrial processes. They offer several advantages, including improved process
control, scalability, redundancy, flexibility, centralized management, and data collection and analysis.
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9. DCS (Distributed control systems)
• Functional requirements of Distributed control systems
 Distributed control systems (DCS) are used in a variety of industries to automate and control processes. The functional requirements of a DCS can vary
depending on the specific application, but some common requirements include:
1. Process control: The ability to monitor and control a process, such as a chemical reaction or manufacturing process.
2. Communication: The ability to communicate with various components of the system, such as sensors, actuators, and other control devices.
3. Data acquisition: The ability to collect data from various sensors and other sources, and make it available for analysis and monitoring.
4. Alarming: The ability to notify operators when a process parameter goes out of a specified range or when an equipment failure occurs.
5. Trending and reporting: The ability to track and analyze data over time, and generate reports for analysis and decision-making.
6. System security: The ability to secure the system from unauthorized access, hacking, or other security breaches.
7. Redundancy: The ability to provide backup systems and components to ensure that the system continues to operate in the event of a failure.
8. Scalability: The ability to add or remove components as needed to adjust to changing process requirements.
9. Interoperability: The ability to work with other systems and devices, such as programmable logic controllers (PLCs) or supervisory control and data
acquisition (SCADA) systems.
10. Configuration management: The ability to manage system configurations, including software and hardware changes, and to ensure that changes are
properly documented and controlled.
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10. DCS (Distributed control systems)
• Communication for distributed control
 Communication is a crucial component in distributed control systems, which involve multiple interconnected devices or components that work together
to achieve a common goal. In such systems, communication is necessary to enable coordination, collaboration, and decision-making among the different
components.
 To facilitate effective communication in distributed control systems, several considerations should be taken into account. These include:
• Protocol selection: Choosing the appropriate communication protocol is critical to ensure seamless communication between the different components.
Factors such as bandwidth, latency, reliability, and security should be considered when selecting the communication protocol.
• Network topology: The topology of the network used for communication should be carefully designed to minimize latency and ensure reliable
communication. Topologies such as star, ring, bus, and mesh can be used depending on the specific requirements of the system.
• Message format: The format of the messages exchanged between the different components should be standardized to ensure interoperability and
compatibility between different systems.
• Error handling: Mechanisms for error detection and correction should be built into the communication system to ensure that data integrity is
maintained even in the presence of errors.
• Security: Distributed control systems are often used in critical applications where security is paramount. Thus, measures such as encryption,
authentication, and access control should be implemented to ensure the confidentiality and integrity of the communication.
• Overall, effective communication is critical for the success of distributed control systems. By carefully considering the above factors, designers can create
communication systems that are reliable, efficient, and secure.
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11. DCS (Distributed control systems)
• DCS Application examples
 Distributed Control Systems (DCS) are widely used in many industries where large-scale processes or operations need to be
controlled and monitored remotely. Here are some examples of DCS applications:
1. Oil and Gas Industry: DCS systems are used to control and monitor oil and gas refining, production, and distribution
processes. The system enables the remote control of pumps, compressors, and valves for flow control, pressure control,
and temperature control.
2. Chemical Industry: DCS systems are used in the chemical industry to control and monitor batch and continuous production
processes. The system enables the remote control of reactors, pumps, valves, and other equipment to optimize the
production process and improve product quality.
3. Power Generation: DCS systems are used in power generation plants to control and monitor the operation of boilers,
turbines, generators, and other equipment. The system enables remote monitoring of performance, diagnosis of faults, and
maintenance planning.
4. Water Treatment: DCS systems are used in water treatment plants to control and monitor the purification process. The
system enables the remote control of pumps, valves, and filters for efficient treatment of water and wastewater.
5. Food and Beverage Industry: DCS systems are used in the food and beverage industry to control and monitor the
production process. The system enables the remote control of mixers, blenders, and other equipment to ensure consistent
quality and quantity of products.
6. Overall, DCS systems are used in various industries where large-scale processes need to be controlled and monitored
remotely. These systems improve efficiency, reduce downtime, and improve product quality and consistency.
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12. SCADA (supervisory control and data
acquisition)
• Overview
SCADA (supervisory control and data acquisition) is a system used in
industrial automation to monitor and control remote equipment and
processes in real-time. SCADA systems are typically used in large-scale
industrial operations such as manufacturing, energy, water treatment,
and transportation.
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13. SCADA (supervisory control and data
acquisition)
• The main components of a SCADA system include:
1. Remote Terminal Units (RTUs) or Programmable Logic Controllers (PLCs): These
are devices that are installed at the remote locations of the process being
monitored or controlled. They collect data from sensors and other equipment,
and can also send control signals to equipment.
2. Human Machine Interface (HMI): This is the interface between the operator
and the SCADA system. The HMI displays real-time data and alerts, and enables
operators to control the process through commands.
3. Communication infrastructure: SCADA systems require a reliable
communication network to connect the remote RTUs/PLCs with the HMI. This
is typically achieved through wired or wireless networks such as Ethernet,
radio, or satellite.
4. Data Historian: This is a database that stores all the data collected by the
RTUs/PLCs. This data can be used for analysis, trending, and reporting.
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14. SCADA (supervisory control and data
acquisition)
• SCADA systems offer several benefits including:
1. Real-time monitoring and control of industrial processes.
2. Improved operational efficiency, by automating routine tasks and reducing
downtime.
3. Enhanced safety, by allowing operators to remotely monitor and control
equipment from a safe location.
4. Better decision-making, by providing accurate and timely data to operators.
5. Remote access, which allows operators to monitor and control processes from
anywhere, at any time.
• Overall, SCADA systems play a critical role in modern industrial automation, and
are used in various industries to improve efficiency, safety, and productivity.
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15. SCADA (supervisory control and data
acquisition)
• SCADA architecture and communication
SCADA (Supervisory Control and Data Acquisition) systems have a typical architecture that consists of several
components working together to monitor and control remote processes. The architecture of a SCADA system
includes:
1. Field devices: These devices are sensors, actuators, and other control equipment that are installed in the field
or remote locations. They collect data from the process being monitored and send control signals to the
equipment.
2. Remote Terminal Units (RTUs): RTUs are microprocessor-based devices that collect and transmit data from field
devices to the SCADA system. They also receive control commands from the SCADA system and execute them
on field devices.
3. Programmable Logic Controllers (PLCs): PLCs are specialized computers that are used to control equipment and
processes in real-time. They collect data from field devices and send control signals to the equipment. PLCs are
often used in small to medium-sized systems.
4. SCADA master station: The master station is the central component of the SCADA system. It is responsible for
collecting, processing, and displaying data from RTUs and PLCs. It also sends control signals to RTUs and PLCs.
5. Communication infrastructure: The communication infrastructure is the network that connects the RTUs, PLCs,
and the master station. This network can be wired or wireless and can use different communication protocols
depending on the specific requirements of the system.
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16. SCADA (supervisory control and data
acquisition)
Communication in SCADA systems is critical for efficient monitoring and control of
remote processes. Communication in SCADA systems is typically achieved through:
1. Wired communication: This includes the use of technologies such as Ethernet, RS-
232, and RS-485. Wired communication is more reliable and secure than wireless
communication, but it may be limited by the distance and availability of cables.
2. Wireless communication: This includes technologies such as radio, cellular, and
satellite communication. Wireless communication is more flexible and can cover
longer distances, but it may be less reliable and secure than wired communication.
• The communication protocol used in SCADA systems depends on the specific
requirements of the system. Common protocols include Modbus, DNP3, IEC 61850, and
OPC-UA. The protocol used in the system should be chosen based on the specific
requirements for data transmission speed, reliability, and security.
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17. SCADA (supervisory control and data
acquisition)
• Application
• SCADA (Supervisory Control and Data Acquisition) systems are used in various industries to monitor and control remote processes. Here are some
examples of SCADA applications:
1. Power generation and distribution: SCADA systems are used in power plants to monitor and control the generation and distribution of electricity.
They can monitor the performance of generators, turbines, and other equipment, and can adjust their operation to maintain optimal efficiency and
reliability. SCADA systems can also monitor the power grid and detect faults, allowing operators to quickly respond and restore power.
2. Water treatment: SCADA systems are used in water treatment plants to monitor and control the purification process. They can monitor water levels,
flow rates, and chemical concentrations, and can adjust the treatment process to ensure water quality and safety. SCADA systems can also detect
leaks and equipment failures, allowing operators to take corrective action.
3. Oil and gas industry: SCADA systems are used in oil and gas production and refining to monitor and control remote sites. They can monitor
equipment performance, detect leaks, and adjust the operation of valves, pumps, and other equipment. SCADA systems can also improve safety by
monitoring for potential hazards and quickly responding to emergencies.
4. Manufacturing: SCADA systems are used in manufacturing plants to monitor and control production processes. They can monitor production rates,
detect equipment failures, and adjust production parameters to ensure optimal efficiency and quality. SCADA systems can also monitor inventory
levels and track product quality.
5. Transportation: SCADA systems are used in transportation systems such as railways and subways to monitor and control train movements. They can
monitor train schedules, detect equipment failures, and adjust train speeds to maintain optimal efficiency and safety. SCADA systems can also
monitor the movement of passengers and detect potential security threats.
• Overall, SCADA systems are used in various industries to monitor and control remote processes, improving efficiency, safety, and reliability.
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18. Advanced control techniques
• Feed Forward Control
• Feedforward control is a control strategy used in industrial automation systems to improve process control and reduce the
impact of disturbances on the process output. It is a predictive control strategy that uses a mathematical model of the process
to anticipate the effect of disturbances and adjust the control variables to compensate for them.
• In a feedforward control system, the controller receives two inputs: the setpoint and the disturbance signal. The setpoint is the
desired value for the process output, while the disturbance signal is a measurement of the external factors that affect the
process, such as changes in temperature, pressure, or flow rates. The controller uses a mathematical model of the process to
predict the effect of the disturbance on the process output and adjust the control variables accordingly to compensate for it.
The controller then sends the adjusted control signal to the actuator to maintain the process output at the desired setpoint.
• Feedforward control has several advantages over other control strategies. It allows for rapid response to disturbances and can
improve the performance of the control system by reducing the impact of disturbances on the process output. It can also
reduce the need for corrective actions and manual intervention by the operator, improving the efficiency of the process.
• One of the main limitations of feedforward control is that it relies on an accurate mathematical model of the process. The
accuracy of the model can be affected by changes in process conditions, such as variations in operating conditions or
equipment degradation. Therefore, regular model validation and tuning is necessary to ensure the accuracy of the model.
• Overall, feedforward control is a powerful control strategy that can improve the performance of industrial automation systems
by reducing the impact of disturbances on the process output and improving the efficiency of the process.
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19. Advanced control techniques
• Ratio Control
 Ratio control is a control strategy used in industrial automation systems to maintain a specific ratio between two process
variables. It is commonly used in processes where two or more flows need to be controlled in a specific ratio, such as mixing of
multiple fluids or the combustion of fuel and air in a boiler.
 In a ratio control system, the process variables are typically measured using flow meters or other sensors. The controller
compares the ratio of the two process variables with the desired ratio and adjusts the control signals to the valves or other
actuators to maintain the desired ratio. The controller may also use feedback control to adjust the process variables if the ratio
deviates from the desired value.
 There are several advantages to using ratio control. It allows for precise control of the ratio between the process variables,
which can improve the quality and consistency of the end product. It can also improve the efficiency of the process by
minimizing waste and reducing the energy consumption required to maintain the desired ratio.
 However, there are also some limitations to ratio control. It can be more complex than other control strategies and may
require more sophisticated hardware and software. Additionally, the accuracy of the flow sensors and other measuring devices
can affect the accuracy of the ratio control system.
 Overall, ratio control is a useful control strategy for processes where maintaining a specific ratio between two process variables
is critical. It can improve process efficiency and product quality and is commonly used in industrial automation systems.
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20. Advanced control techniques
• Cascade Control
 Cascade control is a control strategy used in industrial automation systems to improve the control of complex processes. It involves
using two or more controllers in a hierarchical structure, with the output of the first controller used as the setpoint for the second
controller.
 In a cascade control system, the primary controller receives a setpoint and a process variable signal and generates an output signal
to the secondary controller. The secondary controller then receives the output signal from the primary controller as the setpoint
and a process variable signal and generates an output signal to the final control element, such as a valve or motor.
 The primary controller is typically responsible for controlling a slow process variable, such as temperature, while the secondary
controller is responsible for controlling a fast process variable, such as flow rate or pressure, that affects the primary variable. The
primary controller provides a stable setpoint for the secondary controller, which can respond quickly to changes in the fast variable
and make adjustments to maintain the setpoint.
 Cascade control has several advantages over other control strategies. It can improve the stability and performance of the control
system, particularly for processes with long time delays or complex dynamics. It can also reduce the impact of disturbances on the
process output and improve the response time to setpoint changes.
 However, cascade control can also be more complex and difficult to implement than other control strategies. It requires careful
tuning of the controller parameters and can be sensitive to changes in process conditions.
 Overall, cascade control is a useful control strategy for complex processes where stability and performance are critical. It can
improve the response time and reduce the impact of disturbances on the process output, making it a popular choice in industrial
automation systems.
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21. • Adaptive Control
Adaptive control is a control strategy used in industrial automation systems that continuously adjusts the control
algorithm based on changes in the process or disturbances. It involves using a mathematical model of the process
that is updated in real-time based on the measurements of the process variables.
In an adaptive control system, the controller uses a mathematical model of the process that is continuously
updated based on the measurements of the process variables. The controller compares the model predictions
with the actual process output and adjusts the control signals to maintain the desired setpoint. The controller may
also adjust the model parameters to improve the accuracy of the model and the performance of the control
system.
Adaptive control has several advantages over other control strategies. It can improve the performance of the
control system in processes with varying operating conditions or disturbances. It can also reduce the need for
manual tuning of the controller parameters, making it more efficient and easier to maintain.
However, there are also some limitations to adaptive control. The accuracy of the mathematical model can be
affected by changes in the process or disturbances, which can lead to errors in the control algorithm. Additionally,
the complexity of the adaptive control system can make it more difficult to implement and maintain.
Overall, adaptive control is a useful control strategy for processes with varying operating conditions or
disturbances. It can improve the performance and efficiency of the control system and reduce the need for
manual tuning of the controller parameters.
Advanced control techniques
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22. • Duplex or split range control
 Duplex or split-range control is a control strategy used in industrial automation systems to control a process using two or more
control valves or actuators. It involves splitting the control signal and sending a portion of it to each of the valves, with each
valve controlling a different range of the process variable.
 In a duplex or split-range control system, the process variable is measured and compared to the desired setpoint. The
controller then generates a control signal that is split into two or more signals, with each signal sent to a different valve or
actuator. Each valve or actuator is responsible for controlling a different range of the process variable, allowing for more
precise control of the process.
 For example, in a temperature control system, two control valves could be used to control the heating and cooling of the
process. The controller would split the control signal into two signals, one for the heating valve and one for the cooling valve.
Each valve would be responsible for controlling a different range of the temperature, allowing for precise control of the
temperature setpoint.
 Duplex or split-range control has several advantages over other control strategies. It can provide more precise control of the
process variable, particularly in processes with non-linear or complex dynamics. It can also improve the response time of the
control system and reduce the impact of disturbances on the process output.
 However, duplex or split-range control can also be more complex and difficult to implement than other control strategies. It
requires careful tuning of the controller parameters and can be sensitive to changes in process conditions.
 Overall, duplex or split-range control is a useful control strategy for processes that require precise control of the process
variable. It can improve the performance and efficiency of the control system and reduce the impact of disturbances on the
process output.
Advanced control techniques
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23. Advanced control techniques
• Override control
 Override control is a control strategy used in industrial automation systems to temporarily change the behavior of a
control loop to respond to a specific event or condition. It involves modifying the control output of the controller to
override the normal control action.
 In an override control system, a separate control signal is used to override the primary control signal when a specific
event or condition occurs. The override signal can be triggered manually by an operator or automatically by a process
variable or an alarm.
 For example, in a temperature control system, an override control signal could be used to turn off the heating system
if the temperature exceeds a certain limit. The override signal would temporarily override the normal control action
of the controller and shut off the heating system until the temperature returns to a safe level.
 Override control has several advantages over other control strategies. It can provide a quick response to unexpected
events or conditions, allowing the control system to adapt to changing process conditions. It can also provide a safety
feature in the event of an emergency, allowing the operator to take immediate action to prevent damage or injury.
 However, override control can also be more complex and difficult to implement than other control strategies. It
requires careful design and testing to ensure that the override signal does not cause instability or damage to the
process.
 Overall, override control is a useful control strategy for processes that require a quick response to unexpected events
or conditions. It can improve the safety and performance of the control system and provide an important safety
feature in the event of an emergency.
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24. Advanced control techniques
• Internal mode control
Internal Model Control (IMC) is a control strategy used in industrial automation systems that uses a
mathematical model of the process to design the controller. The controller includes an internal model of
the process, which is used to predict the future behavior of the process and adjust the control signals
accordingly.
In an IMC system, the controller is designed using a model of the process that includes its dynamics and
transfer functions. The controller includes an internal model of the process that is used to predict the
future behavior of the process. The control signals are adjusted based on the predicted behavior of the
process, which improves the accuracy and stability of the control system.
The IMC approach has several advantages over other control strategies. It provides better control of the
process by including a more accurate model of the process dynamics. It is also more robust to changes
in the process and disturbances, as the internal model can adapt to these changes.
However, IMC can also be more complex and difficult to implement than other control strategies. It
requires accurate modeling of the process and careful design of the controller. The performance of the
IMC system can also be affected by modeling errors or inaccuracies.
Overall, IMC is a useful control strategy for processes that require high accuracy and stability. It can
improve the performance and efficiency of the control system and reduce the impact of disturbances
on the process output.
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