Advertisement

Electronic Systems

Electronic Systems

An Electronic System is a physical interconnection of components, or parts, that gathers various amounts of information together

Electronic systems do this with the aid of input devices such as sensors, that respond in some way to this information and then uses electrical energy in the form of an output action to control a physical process or perform some type of mathematical operation on the signal.

But electronic control systems can also be regarded as a process that transforms one signal into another so as to give the desired system response. Then we can say that a simple electronic system consists of an input, a process, and an output with the input variable to the system and the output variable from the system both being signals.

There are many ways to represent a system, for example: mathematically, descriptively, pictorially or schematically. Electronic systems are generally represented schematically as a series of interconnected blocks and signals with each block having its own set of inputs and outputs.

As a result, even the most complex of electronic control systems can be represented by a combination of simple blocks, with each block containing or representing an individual component or complete sub-system. The representing of an electronic system or process control system as a number of interconnected blocks or boxes is known commonly as “block-diagram representation”.

Block Diagram Representation of a Simple Electronic System

simple electronic system

Electronic Systems have both Inputs and Outputs with the output or outputs being produced by processing the inputs. Also, the input signal(s) may cause the process to change or may itself cause the operation of the system to change. Therefore the input(s) to a system is the “cause” of the change, while the resulting action that occurs on the systems output due to this cause being present is called the “effect”, with the effect being a consequence of the cause.

In other words, an electronic system can be classed as “causal” in nature as there is a direct relationship between its input and its output. Electronic systems analysis and process control theory are generally based upon this Cause and Effect analysis.

So for example in an audio system, a microphone (input device) causes sound waves to be converted into electrical signals for the amplifier to amplify (a process), and a loudspeaker (output device) produces sound waves as an effect of being driven by the amplifiers electrical signals.

But an electronic system need not be a simple or single operation. It can also be an interconnection of several sub-systems all working together within the same overall system.

Our audio system could for example, involve the connection of a CD player, or a DVD player, an MP3 player, or a radio receiver all being multiple inputs to the same amplifier which in turn drives one or more sets of stereo or home theatre type surround loudspeakers.

But an electronic system can not just be a collection of inputs and outputs, it must “do something”, even if it is just to monitor a switch or to turn “ON” a light. We know that sensors are input devices that detect or turn real world measurements into electronic signals which can then be processed. These electrical signals can be in the form of either voltages or currents within a circuit. The opposite or output device is called an actuator, that converts the processed signal into some operation or action, usually in the form of mechanical movement.

Types of Electronic System

Electronic systems operate on either continuous-time (CT) signals or discrete-time (DT) signals. A continuous-time system is one in which the input signals are defined along a continuum of time, such as an analogue signal which “continues” over time producing a continuous-time signal.

But a continuous-time signal can also vary in magnitude or be periodic in nature with a time period T. As a result, continuous-time electronic systems tend to be purely analogue systems producing a linear operation with both their input and output signals referenced over a set period of time.

continuous time signal

For example, the temperature of a room can be classed as a continuous time signal which can be measured between two values or set points, for example from cold to hot or from Monday to Friday. We can represent a continuous-time signal by using the independent variable for time t, and where x(t) represents the input signal and y(t) represents the output signal over a period of time t.

Generally, most of the signals present in the physical world which we can use tend to be continuous-time signals. For example, voltage, current, temperature, pressure, velocity, etc.

On the other hand, a discrete-time system is one in which the input signals are not continuous but a sequence or a series of signal values defined in “discrete” points of time. This results in a discrete-time output generally represented as a sequence of values or numbers.

Generally a discrete signal is specified only at discrete intervals, values or equally spaced points in time. So for example, the temperature of a room measured at 1pm, at 2pm, at 3pm and again at 4pm without regards for the actual room temperature in between these points at say, 1:30pm or at 2:45pm.

discrete time signal

However, a continuous-time signal, x(t) can be represented as a discrete set of signals only at discrete intervals or “moments in time”. Discrete signals are not measured versus time, but instead are plotted at discrete time intervals, where n is the sampling interval. As a result discrete-time signals are usually denoted as x(n) representing the input and y(n) representing the output.

Then we can represent the input and output signals of a system as x and y respectively with the signal, or signals themselves being represented by the variable, t, which usually represents time for a continuous system and the variable n, which represents an integer value for a discrete system as shown.

Continuous-time and Discrete-time System

continuous-time and discrete-time

Interconnection of Systems

One of the practical aspects of electronic systems and block-diagram representation is that they can be combined together in either a series or parallel combinations to form much bigger systems. Many larger real systems are built using the interconnection of several sub-systems and by using block diagrams to represent each subsystem, we can build a graphical representation of the whole system being analysed.

When subsystems are combined to form a series circuit, the overall output at y(t) will be equivalent to the multiplication of the input signal x(t) as shown as the subsystems are cascaded together.

Series Connected System

series block diagram

For a series connected continuous-time system, the output signal y(t) of the first subsystem, “A” becomes the input signal of the second subsystem, “B” whose output becomes the input of the third subsystem, “C” and so on through the series chain giving A x B x C, etc.

Then the original input signal is cascaded through a series connected system, so for two series connected subsystems, the equivalent single output will be equal to the multiplication of the systems, ie, y(t) = G1(s) x G2(s). Where G represents the transfer function of the subsystem.

Note that the term “Transfer Function” of a system refers to and is defined as being the mathematical relationship between the systems input and its output, or output/input and hence describes the behaviour of the system.

Also, for a series connected system, the order in which a series operation is performed does not matter with regards to the input and output signals as: G1(s) x G2(s) is the same as G2(s) x G1(s). An example of a simple series connected circuit could be a single microphone feeding an amplifier followed by a speaker.

Parallel Connected Electronic System

parallel electronic system

For a parallel connected continuous-time system, each subsystem receives the same input signal, and their individual outputs are summed together to produce an overall output, y(t). Then for two parallel connected subsystems, the equivalent single output will be the sum of the two individual inputs, ie, y(t) = G1(s) + G2(s).

An example of a simple parallel connected circuit could be several microphones feeding into a mixing desk which in turn feeds an amplifier and speaker system.

Electronic Feedback Systems

Another important interconnection of systems which is used extensively in control systems, is the “feedback configuration”. In feedback systems, a fraction of the output signal is “fed back” and either added to or subtracted from the original input signal. The result is that the output of the system is continually altering or updating its input with the purpose of modifying the response of a system to improve stability. A feedback system is also commonly referred to as a “Closed-loop System” as shown.

Closed-Loop Feedback System

closed loop feedback system

Feedback systems are used a lot in most practical electronic system designs to help stabilise the system and to increase its control. If the feedback loop reduces the value of the original signal, the feedback loop is known as “negative feedback”. If the feedback loop adds to the value of the original signal, the feedback loop is known as “positive feedback”.

An example of a simple feedback system could be a thermostatically controlled heating system in the home. If the home is too hot, the feedback loop will switch “OFF” the heating system to make it cooler. If the home is too cold, the feedback loop will switch “ON” the heating system to make it warmer. In this instance, the system comprises of the heating system, the air temperature and the thermostatically controlled feedback loop.

Transfer Function of Electronic Systems

electronic system

Any subsystem can be represented as a simple block with an input and output as shown. Generally, the input is designated as: θi and the output as: θo. The ratio of output over input represents the gain, ( G ) of the subsystem and is therefore defined as: G = θo/θi

In this case, G represents the Transfer Function of the system or subsystem. When discussing electronic systems in terms of their transfer function, the complex operator, s is used, then the equation for the gain is rewritten as: G(s) = θo(s)/θi(s)

Electronic Systems Summary

We have seen that a simple Electronic System consists of an input, a process, an output and possibly feedback. Electronic systems can be represented using interconnected block diagrams where the lines between each block or subsystem represents both the flow and direction of a signal through the system.

Block diagrams need not represent a simple single system but can represent very complex systems made from many interconnected subsystems. These subsystems can be connected together in series, parallel or combinations of both depending upon the flow of the signals.

We have also seen that electronic signals and systems can be of continuous-time or discrete-time in nature and may be analogue, digital or both. Feedback loops can be used be used to increase or reduce the performance of a particular system by providing better stability and control. Control is the process of making a system variable adhere to a particular value, called the reference value.

In the next tutorial about Electronic Systems, we will look at a types of electronic control system called an Open-loop System which generates an output signal, y(t) based on its present input values and as such does not monitor its output or make adjustments based on the condition of its output.

65 Comments

Leave a Reply to balaji Cancel reply
Error! Please fill all fields.

  • Renny.Mulen

    Electronic components

  • Rejwan sordar

    I love thes Page

  • Denis Cooke

    This tutorial is great. I just wish I could download it to read offline.

    Thanks very much
    Denis Cooke

  • Donald Fager

    What an insightful article on electronic systems! I must admit, as someone who has always been fascinated by the intricate workings of modern technology, this piece hit the mark for me.

  • Deng Adoor Deng

    It’s just a nice and wanted one

  • mikal luna

    As a hobby, I enjoy exploring new research in the world and trying to improve myself, like

  • Polar Joubert

    I need teaching materials on basic electronics for igcse

  • Santhosh kumar

    Want the moreover detailed information updated on the Tamil language

  • Aslam ali

    Hii

  • Fatai Oluwasina Sanusi

    I am a learner

  • Fekadu birhanu

    Assignment brake ll
    Brake valve
    component
    opration
    diagram/ section

  • Lalgul

    invl

  • Jimoh olarewaju

    I want to know more about control system

  • Irshad Ahmad Zawak

    Scenario: Design an operating system for an Intelligent Ventilator System which should be used in Covid-19 patient’s beds and should control the oxygen and other required aids for Covid patients without doctor’s interaction.
    Required aids:
    • Automatically detecting the oxygen Level of the Patients.
    • Alerting Doctors regarding the patient’s situation.
    • Making the ventilator ready for the patient.
    • Setting required ventilation and oxygen pressure based on the patient situation.
    • Alarming the doctors if the patient is dead in order to evacuate the current patient and to make beds free to other patients.
    • Alerting the doctors if oxygen finishes.
    • Repeat
    Queston No.1: Consider if you are given the hardware for above system including the sensors and other machines required for running Intelligent Ventilator System, which type of operating system would you design for it and why? (6 Marks)
    Queston No.2: After selecting the operating system type for above system, based on your OS choice which operating system structure will you use and why? (6 Marks)
    Queston No.3: After selecting the operating system structure for above system, based on your Structure choice which type or types of user interface, and Operating System services will you use and why?
    (6 Marks)
    Question No.4: Consider if you have a program to execute on a specific CPU, and it has 6 different processes each executing on CPU (only one process at a time can be under execution in a single processor). Below are the processes timing and instructions with I/O. (7 Marks)
    • Process A 1st in Queue: It has 10 instructions, to execute, and it has a I/O delay 3 sec on 5th instruction
    • Process B 2nd in Queue: It has 5 instructions, to execute, without I/O delays.
    • Process C 3rd in Queue: It has 6 instructions, to execute, and it has a I/O delay 2 sec on 5th instruction
    • Process D 4th in Queue: It has 3 instructions, to execute, and it has no I/O delay.
    • Process E 5th in Queue: It has 2 instructions, to execute, and it has a I/O delay 4 sec on 2th instruction
    • Process F 6th in Queue: It has 7 instructions, to execute, and it has no I/O delay.
    Now your task is to schedule these processes on a single CPU which can run only one process at a time. Consider each instruction take one second for execution on the CPU, now design an algorithm which can schedule these processes to execute it on CPU in the shortest time possible.
    Optional Question:
    Queston No.5: Create a Flow chart of the System Calls of the above program when it requests for I/O, when I/O returns or responds to that System Call?
    if any one solve these question in two hours i would very happy from them

  • Bhn

    An amazing explanation thank you so much ☺️

  • Areej Rani

    It’s elaborative

  • Ebrahim

    Good explanation

  • Mughal

    very good tutorial
    I wana Know how a pressure controller works and its signal trafficking

  • SURA BACHA

    please, define what is electronics and communication management?