Los sistemas de control son agrupados en tres tipos básicos: Hechos por el hombre, naturales, o mixtos..

Man made

Electrical, electronic, pneumatic or mechanical systems that capture signals of the state of the system and coordinate one or more responses, depending on their control loop. Upon detecting a deviation from the pre-established parameters of the normal operation of the system, they act through sensors and actuators to bring the system back to its normal operating conditions. A clear example of this is a thermostat, which consecutively captures temperature signals: When the temperature goes out of range by rising or falling, it acts by turning on a cooling or heating system.

Natural

They include biological systems as components of the control system: The senses (measurements), the muscles (drives), and the brain in its frontal lobe (controller). For example, human body movements such as the act of pointing to an object, walking or speaking.

The brain itself is a complete control system:

• - Input: The senses are processed in the posterior and lateral part, occupying most of the brain mass.

• - Output: Muscle movements are processed in its central part and the motor cortex.

• - Control: The frontal lobe is responsible for executive actions.

Where the brain is the hardware and the mind is the software of the system.

Mixed

Components are man-made and the others are natural. The control system of a man driving his vehicle is found. This system is made up of the driver and the vehicle, which becomes an extension of their muscular actions.

The destination that the driver has is the reference of the system, it is the parameter that his mind takes, and with his brain he will make the calculations, process the signals from his senses and the muscular actions necessary to reach his destination.

Another example could be the decisions that a politician makes before an election. This system is made up of your brain, senses, muscles, and your entire mind. The exit is manifested in the promises that the politician announces, the degree of acceptance of the proposal by the population, it is the feedback of the system that will adjust its next actions in search of its objective or reference.

Predictive control by model

They are control systems that work with a predictive system, and not an active one like the traditional one (they execute the solution to the problem before it begins to affect the process). In this way, they improve the efficiency of the process by quickly counteracting the effects. These can be control systems:

1. • Signaling: Traffic light control.

2. • Temperature: Control of heating a home.

3. • Liquid level: Control of water pumps in a building.

4. • Vertical or load transportation: Control of elevators or forklifts, conveyor belts.

5. • Transfer of components: Control of transfer of files, documents, multimedia components, etc.

6. • Position: Motion control of a servomotor.

7. • Electrical power: Control of the electrical power provided.

Other classifications

1. • Causality (causal and non-causal): It is causal if there is a causal relationship between the outputs and inputs of the system, more explicitly, between the output and the future values ​​of the input.

2. • Inputs and outputs of the system:

1. One input and one output or SISO (single input, single output).

2. Single input and multiple outputs or SIMO (single input, multiple output).

3. Multiple inputs and one output or MISO (multiple input, single output).

4. Multiple input and multiple output or MIMO (multiple input, multiple output).

3. • Differential equation of the system (linear and non-linear).

4. • In function of time:

1. Continuous time, if the system model is a differential equation, and therefore time is considered infinitely divisible. Continuous time variables are also called analog.

2. Discrete time, if the system is defined by a difference equation. Time is considered divided into periods of constant value. The values ​​of the variables are digital (binary, hexadecimal systems, etc.), and their value is only known in each period.

3. Discrete events, if the system evolves according to variables whose value is known when a certain event occurs.

5. • Relationship between the variables of the systems (coupled and uncoupled): They are coupled when the variables of one of them are related to those of the other system, and uncoupled if the variables of both systems have no relationship.

6. • Relationship of variables with time and space (stationary and non-stationary): They are stationary when their variables are constant in time and space, and non-stationary when their variables are not constant in time or space.

7. • Relationship between the response of the system and the variation of the input (stable and unstable): It is stable when a bounded response of the output is produced in response to any bounded input signal, and unstable when there is at least one bounded input that produces an unbounded response of the output.

1. • Control: selection of the inputs of a system so that the states or outputs change according to a desired way. The elements are:

• It always exists to verify the achievement of the objectives established in the planning.

• Measurement. To control, it is essential to measure and quantify the results.

• Detect deviations. One of the functions inherent to control is to discover the differences that arise between execution and planning.

• Establish corrective measures. The object of control is to foresee and correct errors.

• Control factors; Quantity, Time, cost, Quality. Controller: (Electronics). It is an electronic device that emulates the ability of human beings to exercise control. Through four control actions: compare, calculate, adjust and limit. Process: progressively continuous natural operation or development, marked by a series of gradual changes that follow one another in a relatively fixed manner and that lead to a determined result or purpose. Progressive artificial or voluntary operation that consists of a series of controlled actions or movements, systematically directed towards a given result or purpose. Examples: chemical, economic and biological processes. Supervision: act of observing the work and tasks of another (individual or machine) who may not know the subject in depth.

2. • Input Current Signal: Considered as a stimulus applied to a system from an external energy source with the purpose of the system producing a specific response.

3. • Output Current Signal: Response obtained by the system that may or may not be related to the response implied by the input.

4. • Manipulated Variable: It is the element whose magnitude is modified to achieve the desired response. That is, the input of the process is manipulated.

5. • Controlled Variable: It is the element that you want to control. It can be said that it is the output of the process.

6. • Conversion: The variations or changes that occur in the variable are generated through receivers.

7. • External Variations: These are the factors that influence the action of producing a corrective order change.

8. • Energy Source: It is what delivers the energy necessary to generate any type of activity within the system.

9. • Feedback: Feedback is an important characteristic of closed-loop control systems. It is a sequential cause and effect relationship between state variables "State variable (dynamic system)"). Depending on the corrective action taken by the system, it may or may not support a decision. When a return occurs in the system, it is said that there is negative feedback; If the system supports the initial decision, it is said that there is positive feedback.

10. • Phase variables: These are the variables that result from the transformation of the original system to the controllable canonical form. From here we also obtain the controllability matrix whose rank must be of complete order to control the system.

The problems considered in control systems engineering are basically treated through two fundamental steps:

1. • The analysis.

2. • The design.

That analysis investigates the characteristics of an existing system. While in the design, the components are chosen to create a control system that subsequently executes a particular task.

There are two design methods:

1. • Design by analysis.

2. • Design by synthesis.

The representation of problems in control systems is carried out through three basic representations or models:

1. • Differential, integral, derivative equations and other mathematical relationships.

2. • Block diagrams.

3. • Graphs in analysis flow.

Block diagrams and flow charts are graphic representations that aim to shorten the corrective process of the system, regardless of whether it is characterized schematically or through mathematical equations.

Differential equations and other mathematical relationships are used when detailed relationships of the system are required. Each control system can be represented theoretically by its mathematical equations. The use of mathematical operations is evident in all controllers of the type: Proportional Controller (P), Proportional Controller, Integral (PI)") and Proportional, Integral and Derivative Controller (PID),[2]​ which, due to the combination and superposition of mathematical calculations, helps control circuits, assemblies and industrial systems, in order to help in their improvement.

• - System.

• - System dynamics.

• - Complex system.

• - Dynamic system.

• - Control theory.

• - Feedback.

• - Cybernetics.

• - Systems theory.

• - Systems engineering.

• - Systemic thinking.

• - Time series.

• - Traction control.

• - Industrial control system.

• - Fire control system.

• - European railway control system.

• - Traffic Area Control System.

• - Control theory.

• - Remote controlled weapon system.

• - Numerical control.

• - Early warning and airborne control.

• - Respiration control system.

• - Control engineering.

• - Automatic control Regulators in open loop and closed loop.

Contenido

Los sistemas de control pueden ser de lazo abierto o de lazo cerrado basado en que la acción de control sea independiente o no de la salida del sistema que se desea controlar.

Open loop control system

It is that system in which the output has no effect on the control system, this means that there is no feedback from said output to the controller so that it can adjust the control action.

• - Example 1: A washing machine that performs washing cycles based on time, without considering the degree of cleanliness of the clothes.

• - Example 2: A toaster that toasts bread based on time, without considering whether the bread is already toasted enough or not.

These systems are characterized by:

• - Be simple and easy to maintain.

• - Have an output that is not compared to the input.

• - Be affected by tangible or intangible disturbances.

• - Have a precision dependent on the calibration of the system.

• - Be effective in automatic control systems.

Closed loop control system

They are systems in which the control action is a function of the output signal; That is, in closed loop control systems or control systems with feedback, the output to be controlled is fed back to compare it with the input (desired value) and thus generate an error that the controller receives to decide the action to take on the process, in order to reduce said error and therefore, bring the output of the system to the desired value.

• - Example 1: A thermo-water tank water heater that we use for bathing.

• - Example 2: A highly sensitive level regulator for a tank. The movement of the buoy produces more or less obstruction in a jet of low-pressure air or gas. This translates into pressure changes that affect the membrane of the flow valve, causing it to open more the closer it is to the maximum level.

These systems are characterized by:

• - Be complex and broad in number of parameters.

• - The output is compared with the input to perform system control.

• - Be more stable to disturbances and internal variations.

Los sistemas de control son agrupados en tres tipos básicos: Hechos por el hombre, naturales, o mixtos..

Man made

Electrical, electronic, pneumatic or mechanical systems that capture signals of the state of the system and coordinate one or more responses, depending on their control loop. Upon detecting a deviation from the pre-established parameters of the normal operation of the system, they act through sensors and actuators to bring the system back to its normal operating conditions. A clear example of this is a thermostat, which consecutively captures temperature signals: When the temperature goes out of range by rising or falling, it acts by turning on a cooling or heating system.

Natural

They include biological systems as components of the control system: The senses (measurements), the muscles (drives), and the brain in its frontal lobe (controller). For example, human body movements such as the act of pointing to an object, walking or speaking.

The brain itself is a complete control system:

• - Input: The senses are processed in the posterior and lateral part, occupying most of the brain mass.

• - Output: Muscle movements are processed in its central part and the motor cortex.

• - Control: The frontal lobe is responsible for executive actions.

Where the brain is the hardware and the mind is the software of the system.

Mixed

Components are man-made and the others are natural. The control system of a man driving his vehicle is found. This system is made up of the driver and the vehicle, which becomes an extension of their muscular actions.

The destination that the driver has is the reference of the system, it is the parameter that his mind takes, and with his brain he will make the calculations, process the signals from his senses and the muscular actions necessary to reach his destination.

Another example could be the decisions that a politician makes before an election. This system is made up of your brain, senses, muscles, and your entire mind. The exit is manifested in the promises that the politician announces, the degree of acceptance of the proposal by the population, it is the feedback of the system that will adjust its next actions in search of its objective or reference.

Predictive control by model

They are control systems that work with a predictive system, and not an active one like the traditional one (they execute the solution to the problem before it begins to affect the process). In this way, they improve the efficiency of the process by quickly counteracting the effects. These can be control systems:

1. • Signaling: Traffic light control.

2. • Temperature: Control of heating a home.

3. • Liquid level: Control of water pumps in a building.

4. • Vertical or load transportation: Control of elevators or forklifts, conveyor belts.

5. • Transfer of components: Control of transfer of files, documents, multimedia components, etc.

6. • Position: Motion control of a servomotor.

7. • Electrical power: Control of the electrical power provided.

Other classifications

1. • Causality (causal and non-causal): It is causal if there is a causal relationship between the outputs and inputs of the system, more explicitly, between the output and the future values ​​of the input.

2. • Inputs and outputs of the system:

1. One input and one output or SISO (single input, single output).

2. Single input and multiple outputs or SIMO (single input, multiple output).

3. Multiple inputs and one output or MISO (multiple input, single output).

4. Multiple input and multiple output or MIMO (multiple input, multiple output).

3. • Differential equation of the system (linear and non-linear).

4. • In function of time:

1. Continuous time, if the system model is a differential equation, and therefore time is considered infinitely divisible. Continuous time variables are also called analog.

2. Discrete time, if the system is defined by a difference equation. Time is considered divided into periods of constant value. The values ​​of the variables are digital (binary, hexadecimal systems, etc.), and their value is only known in each period.

3. Discrete events, if the system evolves according to variables whose value is known when a certain event occurs.

5. • Relationship between the variables of the systems (coupled and uncoupled): They are coupled when the variables of one of them are related to those of the other system, and uncoupled if the variables of both systems have no relationship.

6. • Relationship of variables with time and space (stationary and non-stationary): They are stationary when their variables are constant in time and space, and non-stationary when their variables are not constant in time or space.

7. • Relationship between the response of the system and the variation of the input (stable and unstable): It is stable when a bounded response of the output is produced in response to any bounded input signal, and unstable when there is at least one bounded input that produces an unbounded response of the output.

1. • Control: selection of the inputs of a system so that the states or outputs change according to a desired way. The elements are:

• It always exists to verify the achievement of the objectives established in the planning.

• Measurement. To control, it is essential to measure and quantify the results.

• Detect deviations. One of the functions inherent to control is to discover the differences that arise between execution and planning.

• Establish corrective measures. The object of control is to foresee and correct errors.

• Control factors; Quantity, Time, cost, Quality. Controller: (Electronics). It is an electronic device that emulates the ability of human beings to exercise control. Through four control actions: compare, calculate, adjust and limit. Process: progressively continuous natural operation or development, marked by a series of gradual changes that follow one another in a relatively fixed manner and that lead to a determined result or purpose. Progressive artificial or voluntary operation that consists of a series of controlled actions or movements, systematically directed towards a given result or purpose. Examples: chemical, economic and biological processes. Supervision: act of observing the work and tasks of another (individual or machine) who may not know the subject in depth.

2. • Input Current Signal: Considered as a stimulus applied to a system from an external energy source with the purpose of the system producing a specific response.

3. • Output Current Signal: Response obtained by the system that may or may not be related to the response implied by the input.

4. • Manipulated Variable: It is the element whose magnitude is modified to achieve the desired response. That is, the input of the process is manipulated.

5. • Controlled Variable: It is the element that you want to control. It can be said that it is the output of the process.

6. • Conversion: The variations or changes that occur in the variable are generated through receivers.

7. • External Variations: These are the factors that influence the action of producing a corrective order change.

8. • Energy Source: It is what delivers the energy necessary to generate any type of activity within the system.

9. • Feedback: Feedback is an important characteristic of closed-loop control systems. It is a sequential cause and effect relationship between state variables "State variable (dynamic system)"). Depending on the corrective action taken by the system, it may or may not support a decision. When a return occurs in the system, it is said that there is negative feedback; If the system supports the initial decision, it is said that there is positive feedback.

10. • Phase variables: These are the variables that result from the transformation of the original system to the controllable canonical form. From here we also obtain the controllability matrix whose rank must be of complete order to control the system.

The problems considered in control systems engineering are basically treated through two fundamental steps:

1. • The analysis.

2. • The design.

That analysis investigates the characteristics of an existing system. While in the design, the components are chosen to create a control system that subsequently executes a particular task.

There are two design methods:

1. • Design by analysis.

2. • Design by synthesis.

The representation of problems in control systems is carried out through three basic representations or models:

1. • Differential, integral, derivative equations and other mathematical relationships.

2. • Block diagrams.

3. • Graphs in analysis flow.

Block diagrams and flow charts are graphic representations that aim to shorten the corrective process of the system, regardless of whether it is characterized schematically or through mathematical equations.

Differential equations and other mathematical relationships are used when detailed relationships of the system are required. Each control system can be represented theoretically by its mathematical equations. The use of mathematical operations is evident in all controllers of the type: Proportional Controller (P), Proportional Controller, Integral (PI)") and Proportional, Integral and Derivative Controller (PID),[2]​ which, due to the combination and superposition of mathematical calculations, helps control circuits, assemblies and industrial systems, in order to help in their improvement.

• - System.

• - System dynamics.

• - Complex system.

• - Dynamic system.

• - Control theory.

• - Feedback.

• - Cybernetics.

• - Systems theory.

• - Systems engineering.

• - Systemic thinking.

• - Time series.

• - Traction control.

• - Industrial control system.

• - Fire control system.

• - European railway control system.

• - Traffic Area Control System.

• - Control theory.

• - Remote controlled weapon system.

• - Numerical control.

• - Early warning and airborne control.

• - Respiration control system.

• - Control engineering.

• - Automatic control Regulators in open loop and closed loop.