Everything You Need To Know About Thermal Imaging Cameras

What are thermal imaging cameras?

Thermal imaging cameras are handheld electronic devices with an integrated visual display, designed for detecting heat energy.

The key component of a thermal camera is a heat sensor attached to a special type of lens, which is then adapted to work alongside standard image-capture technologies. This allows engineers to quickly identify regions of excessive temperature or sources of wasted heat energy, such as overheating components or potential thermal insulation gaps in building inspection.

Visible light forms only a small part of the electromagnetic spectrum, and the only part we can actually see. When pointed at an object or area, the sensor on a thermal detection camera allows the user to view the otherwise invisible infrared spectrum, which exists at wavelengths between visible light and microwaves.

This is often rendered as a colour map in modern IR cameras, although black-and-white displays are still preferred for certain applications due to their reduced visual ‘busyness’ and improved capture of fine detail.

On a colour thermographic display, warmer components or regions will show up as reds, oranges and yellows, while cooler parts will typically be shown as purples and blues (green usually indicates areas that are roughly at room temperature). Because they measure infrared radiation, and not visible light, thermal cameras are also useful for identifying heat sources in very dark or otherwise obscured environments.

Quality thermal imaging cameras are often sold in the UK in a selection of user-friendly ergonomic designs and offer temperature detection capabilities spanning a broad range of heat sensitivities. This makes them a 

valuable companion to emergency response units, medics, product manufacturers, engineers and maintenance workers across a wide variety of industries - as well as an increasingly affordable option for many different types of hobbyists and enthusiasts at home.

The history of thermal imaging cameras

It’s only in the past few years that the mass production of thermal imaging technologies has reached a point where handheld thermographic cameras (also known as heat cameras, thermal detection or infrared cameras) are now an accessible option for most civil applications and/or hobbyist use.

However, viewing heat energy as an infrared spectrum display isn’t actually a new concept by any means; in fact, the roots of the basic thermography principle were established more than 200 years ago by the German-British astronomer William Herschel:

• • In simplified terms, Herschel was the first to discover the presence of infrared, all the way back in February 1800, while using a prism to study the visible light spectrum
  • Herschel found he could place a thermometer just beyond the red light end of the spectrum to detect the existence of a hitherto unknown invisible band, warmer than any of those in visible light
  • Today, we refer to this invisible band as ‘infrared’ radiation, which lies between visible light and microwave frequencies on the electromagnetic spectrum

Although thermal imaging camcorders were still a long way off, Herschel’s findings were quickly used to produce a number of early thermocouple-type modules, which could detect the unseen heat emanating from warm bodies at a considerable distance. His initial discovery was further developed by many other physicists, engineers and inventors in subsequent years:

• • Especially important to the development of the thermal imaging technologies we use today was the work of Hungarian polymath Kálmán Tihanyi (also responsible for pioneering cathode ray TV technology)
  • In 1929, Tihanyi effectively created the first ‘night vision’ infrared video cameras for use in British anti-aircraft defences
  • During the 1970s, the technology rapidly moved towards solid-state thermal imaging arrays, and eventually on to modern hybridised single-crystal-slice imaging devices
  • Handled units developed through the 1980s and 1990s were far more versatile, user-friendly, and didn’t require active cooling to work, unlike early mechanical versions
  • Still, thermal imaging cameras didn’t really become a financially viable option for most civil uses until the early 2000s, which saw dramatic reductions in the production costs of uncooled arrays
  • This led to a boom in the popularity of heat camera use for applications such as emergency response, architecture analysis, medical diagnostics, environmental control and autopiloting systems.

Today, the plummeting cost of cutting-edge technologies like smart sensors, microcircuitry and WiFi connectivity make thermal video cameras a popular addition to many professional and household engineering, repair, design, creative and hobbyist toolkits.

How thermal imaging cameras work?

An infrared, IR or thermal imaging camera works by detecting and measuring the infrared radiation emanating from objects - in other words, their heat signature.

In order to do so, the camera must first be fitted with a lens that allows IR frequencies to pass through, focusing them on to a special sensor array which can, in turn, detect and read them.

The sensor array is constructed as a grid of pixels, each of which reacts to the infrared wavelengths hitting it by converting them into an electronic signal. Those signals are then sent to a processor within the main body of the camera, which converts them using algorithms into a colour map of different temperature values. It’s this map which is sent on to be rendered by the display screen.

Many types of thermal imaging camera will also include a standard shooting mode that works with the visible light spectrum, much like any other point-and-click digital camera. This allows for easy comparison of two identical shots - one in IR and one in normal mode - to help quickly identify specific problem areas once the user steps out from behind the lens.

Thermal imaging camera usage questions

Alongside frequently asked questions about how thermal imaging cameras work in general, there are also a number of common queries regarding specific use scenarios and the effectiveness of the technology in particular environments or applications.

In this section, we’ll examine a few of the better answers and the reasoning behind them.

Why do thermal imaging cameras work better at night?

Thermal imaging cameras tend to work better at night, but it has nothing to do with the state of the surrounding environment being light or dark.

Rather, because the ambient temperature - and, more importantly, the core temperature of otherwise-unheated objects and environments - is nearly always significantly lower at night than during sunlight hours, thermal imaging sensors are able to display warm areas at higher contrast.

Even on relatively cool days, heat energy from the sun will be gradually absorbed by buildings, roads, vegetation, construction materials and more while ever it’s daylight outside. And, for every degree these sorts of objects gain in ambient temperature over the course of the day, they become less clearly distinguishable from other warm objects the camera’s sensor is being used to detect and highlight.

For the same reason, most thermal imaging cameras will display warm objects in sharper contrast after several hours of darkness, rather than just after the sun sets - and, even during full daylight hours, they’ll usually be more effective in the early morning than in the middle of the afternoon.

Do thermal cameras work through glass?

You may be surprised to learn that thermal imaging cameras don’t generally work through glass.

A full explanation of the technical reasons for this would be somewhat complex from a physics standpoint, but the principle is pretty straightforward. In essence, a sheet of glass allows visible light through but acts a bit like a mirror for infrared wavelengths (this is why the lenses on IR cameras are commonly made from germanium or zinc selenide, not glass).

If you were to point a thermal detection camera at a window, what you’d see onscreen wouldn’t be a clear thermal rendering of what’s on the other side, but most likely a blurry mess - and possibly a vague reflection of yourself holding the camera!

It’s not an absolutely hard and fast rule; certain infrared frequencies can pass through glass, and certain types and configurations of glass may allow varying degrees of infrared to pass through. Car windscreens tend to yield better results than standard household glazing, for example.

In most cases though, the image will be largely obscured by infrared reflection from the ‘wrong’ side of the glass, overlaid in varying degrees of opacity. At the very least, the object being viewed will lack significant detail and contrast.

In short, you won’t want to be using a thermal imaging camera to get accurate readings through glass (or various other types of highly reflective surfaces).

Do thermal cameras work underwater?

Thermal cameras don’t tend to work well underwater. The reasons are, in part, related to the issues with glass outlined above.

Water blocks a lot of infrared wavelengths, much as an opaque barrier blocks visible light wavelengths. In the same way that we can’t see through paint, infrared sensors can’t ‘see’ through any significant depth of water, because the waves it detects don’t pass through water easily.

Water also provides another challenging issue for IR cameras, related to thermal conductivity and specific heat. Water has a much higher heat capacity than air, requiring four times as much energy to raise or lower the temperature of an equivalent volume by one degree.

In practical terms, this means that objects lose (or gain) their own heat energy relative to water much faster, and over shorter distances. For thermal imaging purposes, objects are therefore naturally harder to differentiate when submerged than they would be in the air.

Can thermal imaging cameras see through walls?

Well, no - but to be fair, they don’t ‘see through’ anything at all. A thermal imaging camera detects the surface temperature of the first object in its line of sight; point one at a wall or other solid surface, and it will register the heat being radiated outward by that surface.

Uses of thermal imaging cameras

Beyond basic engineering applications, the emergency services are among the more familiar users of thermal detection cameras today. The technology is deployed regularly in scenarios including firefighting, night-time police pursuits, and disaster response search and rescue.

However, there are a number of other widespread uses of thermal imaging cameras today that may be less obvious. In this section, we’ll look briefly at some of the more common scenarios.

Summary

With so many varieties, designs and sensitivities of thermal imaging cameras available, it’s important to know exactly what it is you’re shopping for before deciding on a specific product or accessories. Key considerations that will influence your ideal purchase include:

• • • Price
    • Brand
    • Certification
    • Size and weight
    • Ergonomics and design
    • Image resolution
    • Thermal range
    • Lens interchangeability
    • Calibration

For more information on any particular heat detection products, or for further advice and assistance with thermal imaging cameras in general, feel free to contact a member of our expert support team by phone, email or live web chat.

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