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Transducers

In this article Dr Tim Jackson continues to discuss transducers in systems and explains Sensors and Actuators.
A person using a smartphone to control smart home devices such as lights, the temperature and a washing machine.
© Pixabay

We’ll split this article into two sections – Sensors and Actuators.

All the while that we’re talking about sensors, let’s not forget that since transduction is all about generating one type of signal from another, for example electrical from mechanical, we can use similar devices in Energy Harvesting too.

Sensors and big data

We’ve been looking at sensing vibration to produce an electrical signal which can be amplified for sound reinforcement. Sensors provide signals that contain information – data – and we want to think about what that means from a systems perspective.

A smart building

To do that, let’s think now about a much bigger scale application – a smart building. In doing so we can start to see connections between hardware and embedded computing and software and systems and see how Computer Engineering and Electronics go hand in hand.

You might already have an app on your phone that allows you to control the lights, the heating, air-conditioning in your home. You could think about this from a systems perspective, identifying the system processes that are taking place in the ways we did previously.

From what physical quantities do we wish to generate data and what form do we wish to generate it in? We could monitor temperature, light levels, carbon dioxide levels, air flow, water flow and electricity consumed by lights, by heating, by individual items such as fridges, computer, and laboratory equipment. We could have movement sensors to detect activity in rooms. We could measure building vibrations, the intensity of sunlight on the building.

Having decided what we want to measure, we could weigh up various types of sensors. We’re going to have to specify what form of signal we want it to produce. In our practical example for this week, the pick-up for the double bass, we want an analogue signal at a particular voltage level. In the building example, the transmission and processing and storage of the data require a different kind of signal. What kind of signals do we want, and why? You can consider answers to these questions in the next step of this week’s course.

Data

How are we going to transmit the data to a central processing system? It could be analogue or digital data. It could be sent over cables or wirelessly. Which is most secure? What are the relative merits and drawbacks of each method?

We might want people to modify their behaviour so that they become part of the building management system. In that case, what real-time information do we want to display to users? How would we display it?

A large dataset will be generated. What processing do we want to do? What information do we want? As Engineers we need to know how to extract information from a data set, how to determine the significance of changes and trends, how to set up the analysis tools that allow us to find the answers to questions and make decisions based on intelligent use of data. This means we need to know about statistics, data analysis and the presentation of data.

The data might be utilised to make decisions. Can we turn off power to heating, cooling and refrigeration systems when electricity demand is high, because a smart supply grid will reward us for doing so. For how long can we have the power off while maintaining function or comfort? We could turn the lights off in a room if nobody is present. We can make sure there is adequate ventilation in a room depending on occupancy. We can make sure the heating or cooling systems are never on in a room when the windows are open. In the event of fire, we can ensure all the fire exit doors are automatically unlocked.

We also have to think about data storage. First, will we store the data? If we will, we might go for a cloud-based solution, so that anybody can access the data. Why would we prefer data storage in the cloud? Who will want the data? How secure will it be? For how long do we need to archive it?

Actuators

food cooking in a frying pan Have you ever burned the dinner while cooking and set off your smoke alarm?

The sounder in the smoke alarm is an actuator. An actuator is a transducer used to create some mechanical effect from an electrical signal. If the electrical signal is periodic in time at an audio frequency, the actuator can make sounds that provide us with an audible warning.

The actuator is a piezoelectric material. Now we need a definition. A piezoelectric material is defined as one across which an electrical potential (voltage) develops when it is deformed. A smoke alarm uses the reverse of the piezoelectric behaviour, to generate sound from a time-dependent voltage.

Piezoelectric materials can generate higher frequencies too, although we can’t hear them, and we need other kinds of electronics to make use of them.

Fish and medicine

A fishing boat

Two common examples in very different industries are ultrasonic imaging and therapy in medicine and underwater sonar systems used in the fishing industry to locate fish.

In both cases, pulses of ultrasound are generated, transmitted, and then received (using the same piezoelectric effect). The time taken for the pulses to return, the strength of the returning pulses and the phase of the waves making up the returning pulses all contain information about the objects reflecting the pulses.

A great deal of mathematical manipulation of the transmitted and received pulses is needed to extract the information. Such signal processing is another important aspect of Electronic and Electrical Engineering.

On a much, much smaller scale, piezoelectric materials may also be used in micro-robotics, which might be used for inspection and repair in places that are hard or dangerous to access. Such places could include the underground infrastructure that supplies water and removes sewage in cities, collapsed buildings after an earthquake or the location of a dangerous accident such as a collapsed mine. Integrated into composites, piezoelectric materials could be used to make “smart materials” so that, for example, a microrobot could have a flapping wing, or a vehicle could change shape to maximise its aerodynamic performance.

Summary

In this article we have seen how the properties of a material can be exploited to use it as a transducer, and that transducers can be used in sensing mode or actuating mode. We’ve also considered how sensors can be used to generate data in a system.

We’ll look at some of these ideas in the next activity, and then move on to a close look at the use of transducers for generating the input to an audio system. Effective use of transducers requires consideration of mechanical construction. In our case, we want to attach the sensor to the body of a double bass and make sure that the only vibrations sensed are those of the instrument. We don’t want movements of the wires and cables to be converted into sound. We also have to design an electronic circuit to safely and efficiently gather the electrical signals.

© University of Birmingham / UKESF
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