Industry Insights

The Modern Automation Engineer

Why today’s automation roles need more than PLC programming alone, and how practical system confidence is becoming one of the most valuable skills in industry.

Simple answer

A modern automation engineer understands the whole control system, not just the PLC program.

PLC programming still matters. But modern automation work also involves physical devices, wiring, industrial networks, HMIs, safety systems, commissioning, diagnostics and clear communication with production, maintenance and engineering teams.

Why it matters

Industry needs people who can solve real system problems.

A machine fault may look like a software issue, but the cause could be a missing input, a safety condition, a networked device, a wiring problem, a failed sensor, an HMI setting or a process issue. Modern automation confidence means knowing how to narrow that down safely.

The changing role

The automation role is getting broader because systems are getting more connected.

There was a time when many people thought of industrial automation as mainly PLC programming. That view is now too narrow. PLCs remain central to many machines, but they rarely work alone. They sit alongside HMIs, remote I/O, sensors, drives, safety devices, industrial Ethernet networks and diagnostic tools.

UK apprenticeship standards reflect this broader reality. The Automation and Control Engineering Technician standard describes a competent technician as someone able to install, maintain, fault find and optimise both hardware and software for automation systems. That is a useful phrase because it captures the real balance of the role: software matters, but so does the physical system around it.

This does not mean every apprentice, electrician, technician or maintenance engineer needs to become a senior controls specialist. It means more people need a practical understanding of how automated systems behave, how to test them safely and how to communicate clearly when something does not work as expected.

Beyond PLC code

PLC programming is important, but it is only one layer of the system.

A PLC program can be perfectly written and the machine still might not run. An input may not be wired correctly. A sensor may be misaligned. A safety relay may be preventing restart. A remote I/O device may not be communicating. An HMI button may be mapped to the wrong tag. A drive may be faulted. A process condition may not be satisfied.

That is why automation engineers and technicians need to think in layers. The program is one layer. The electrical circuit is another. The field devices, network, safety system and operator interface all add more layers. Real fault finding means moving between those layers without guessing.

01

Software logic

Understanding PLC logic, sequences, timers, interlocks, states, alarms and HMI interaction.

02

Physical signals

Reading inputs, outputs, analogue values, device states, wiring behaviour and control voltage symptoms.

03

System context

Knowing how safety, networks, drives, remote I/O, documentation and production conditions affect the machine.

What employers value

The most useful automation skills are practical, connected and evidence-led.

Different jobs need different depths of knowledge. A controls engineer designing a system needs a deeper skillset than an apprentice learning the basics. A maintenance technician may not need to write complex code from scratch, but they may still need to understand machine states, inputs, outputs, reset conditions and safe testing.

The direction of travel is clear. Engineering employers increasingly talk about automation, cyber security, data engineering and software engineering as important areas for growth. The wider workforce also needs strong analytical thinking, technology literacy, curiosity and lifelong learning as technology changes.

01

PLC and HMI awareness

Understanding how logic, tags, screens, alarms and operator actions connect to physical equipment.

02

Industrial networks

Recognising that PLCs, HMIs, remote I/O, drives and sensors often communicate across industrial networks.

03

Safety thinking

Respecting emergency stops, safety relays, isolation, safe reset behaviour and controlled testing.

04

Diagnostics

Using evidence to narrow faults down instead of replacing parts or changing code based on guesswork.

05

Documentation

Reading drawings, I/O lists, device manuals, wiring references and notes well enough to make sensible decisions.

06

Communication

Explaining faults clearly to operators, engineers, lecturers, suppliers or colleagues so the right action happens faster.

Real-world example

A simple fault can involve more than one discipline.

Imagine a conveyor will not start. A beginner might immediately look at the PLC program and ask whether the code is wrong. A more confident engineer works through the system.

01
Check the request

Did the HMI or pushbutton actually send the start signal to the PLC?

02
Check the permissives

Are the emergency stop, guard, overload, drive ready and reset conditions healthy?

03
Check the output

Is the PLC output turning on, and is the physical device or drive responding?

04
Check the evidence

Do the drawings, diagnostic messages, device LEDs and live values tell the same story?

That is the difference between knowing a PLC exists and understanding a control system. Modern automation work rewards people who can connect those clues calmly and safely.

Education and training

Technical education needs to help learners join the dots.

For colleges, apprenticeship teams and training providers, the challenge is not simply to add more content. It is to make automation feel connected. A learner should be able to see how a PLC input relates to a real device, how an HMI command reaches the controller, why a safety condition stops a sequence and how a fault can be proven step by step.

This is where practical learning becomes important. A well-designed training environment can make difficult ideas visible. Learners can press buttons, change logic, watch inputs, trigger outputs, inspect HMI behaviour and practise fault-finding without the pressure of a live production line.

The goal is not to turn every learner into an expert straight away. The goal is to build enough confidence that automation stops feeling like a black box.

Practical takeaway

Modern automation learning should feel like a system, not a collection of separate topics.

PLCs, HMIs, wiring, signals, safety and diagnostics should be taught as connected parts of the same industrial picture.

Common misconceptions

The modern automation role is often misunderstood.

“Automation engineering is just PLC programming.”

PLC programming is a core skill, but real automation work also includes hardware, signals, networks, HMIs, safety, commissioning, documentation and fault finding.

“Only controls engineers need automation knowledge.”

Controls engineers need deeper expertise, but maintenance engineers, electricians, apprentices and technicians often need practical awareness of PLC-controlled systems.

“Connected systems make learning too complicated.”

Connected systems can feel intimidating, but good practical learning makes the system clearer by showing how each part affects the next.

Frequently asked questions

Modern automation engineer FAQs

What does a modern automation engineer do?

A modern automation engineer works with hardware and software used to control industrial systems. Depending on the role, this can include PLCs, HMIs, industrial networks, sensors, drives, safety systems, commissioning, diagnostics, documentation and system optimisation.

Is PLC programming still important?

Yes. PLC programming remains a core automation skill. The important point is that it is not the only skill. Engineers also need to understand how code connects to physical devices, wiring, signals, safety conditions and operator behaviour.

Do all engineers need to become automation specialists?

No. Different roles need different levels of depth. However, many engineers and technicians benefit from practical awareness of PLC-controlled systems because automated equipment is common across modern industry.

Why are industrial networks becoming more important?

Industrial networks are becoming more important because PLCs, HMIs, remote I/O, drives, safety devices and data systems increasingly need to communicate. Basic network awareness helps engineers understand device communication and common fault symptoms.

What should learners focus on first?

Learners should start by understanding the basic control loop: input, logic, output and feedback. From there, they can develop capability with HMIs, diagnostics, safety circuits, remote I/O and connected devices.

How can employers build automation capability?

Employers can give teams structured access to industry-standard automation hardware, safe practice environments and clear learning pathways that connect software, wiring, signals and fault-finding.

Evidence base

Sources used for this article.

This article uses UK-focused engineering and skills evidence, apprenticeship role definitions and wider workforce research. External links open the original source material for readers who want to check the evidence in more detail.

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