Figuring out which pixel pitch of the thermal imaging sensor (also known as microbolometer) suits you best – 12 or 17 microns – is a common dilemma. Does size matter? A simple answer is – yes, it does. But you should know beforehand that pixel pitch directly influences base magnification, image quality and thermal imager sensitivity. So, when it comes to choosing the right one, there are a lot of beliefs and misconceptions floating around. In this article, we will try to explain them all.
Also, to explain what it means – both in theory and in the field – we’ve made this short video where our colleague Laurynas shares everything you need to know about pixel pitch.
A common user determines the class of a thermal imaging device by the sensor resolution or, in other words, by the number of pixels horizontally and vertically. Although there are many more factors to determine the quality of a thermal image, there is a reason for this – the more pixels a sensor contains, the more details of the observed image it can show to the user.
The resolution of a thermal imaging device is determined by the parameters of optical elements, sensor, display, design concept quality, as well as signal processing algorithms. In this article, we will consider only the influence of sensor parameters on the quality of a thermal image. As for the remaining parameters, we will proceed from the fact that they are solved in an optimal way.
The resolution of a thermal imaging device is a complex parameter that consists of thermal and spatial resolution.
Spatial resolution characterizes the ability of a thermal imaging device to show two closely spaced dots or lines separately. The higher the resolution, the clearer the image is shown to the user. From the user’s point of view, spatial resolution is the most understandable and objective parameter for determining the image quality of a thermal imaging device.
Thermal resolution (minimum detectable temperature difference) is the boundary ratio of the observed object signal to the background signal, considering the noise of a thermal imaging sensor. High thermal resolution means that a thermal imaging device can detect an object with a certain temperature against a background with a similar temperature. The smaller the difference between an object and background temperatures, which are recorded by a thermal imaging device, the higher the thermal resolution.
The most important characteristic that affects the thermal resolution of a thermal imaging device is the sensor’s NETD (Noise Equivalent Temperature Difference). It is measured in millikelvins. The NETD of a sensor is a parameter that represents the smallest temperature difference that the sensor can perceive. This parameter corresponds to a signal-to-noise ratio equal to one. In other words, the change in the sensor output signal at a temperature difference equal to NETD corresponds to the noise level of the sensor. The lower the NETD value, the higher the sensor sensitivity.
When choosing a thermal imaging device, customers are guided by different arguments: base magnification, detection range, field of view, weight, size, price. However, not even the most detailed technical data sheet provided by manufacturers of thermal imaging devices contains the item “image quality”. At the same time, even devices with the same field performance on paper show noticeably different results in reality.
Let’s compare two thermal imagers by Pulsar: the Axion 2 XG35 and the Helion 2 XP50 Pro.
It is a good example of thermal imaging devices with similar field performance but different prices. The Axion 2 XG35 and the Helion 2 XP50 Pro have the same sensor spatial resolution of 640×480 pixels, 2.5 – 20x magnification, as well as similar fields of view (12.5×9.4 and 12.4×9.3 degrees) and detection ranges (1750 and 1800 meters).
So, what is the reason for the 30% difference in price? The answer is image quality.
Suppose you go out with the Axion 2 XG35 and the Helion 2 XP50 Pro into the field on a summer evening and look through the eyepiece. In that case, only a well-trained eye will notice the difference in image quality – both devices will show approximately equally contrasting and detailed images.
However, hunting rarely takes place in ideal conditions and at the ideal time of day for a thermal imaging device. The season of active hunting in Europe falls in autumn and winter, the time of wet weather with rain, fog and night frost. The difference in price becomes clear under such real conditions.
In conditions of low thermal contrast, the image in the Helion 2 XP50 Pro is more informative compared to the Axion 2 XG35. This is not a set of spots with a limited number of shades between black and white; this is a “photographic” contrast image with a large range of mid-tones and high-quality rendering of the target and background. The best thermal resolution of the Helion 2 XP50 Pro comes primarily from the sensor’s NETD sensitivity – a good NETD is especially important for scenes with low thermal contrast when objects have approximately the same temperature. For example, landscapes.
The observation of low-contrast thermal scenes clearly demonstrates the coherence between the thermal resolution and the spatial resolution of a thermal imaging device. It would seem that in devices with the same sensor resolution (in our case, both sensors have a resolution of 640×480 pixels), the image visible on display should be equally detailed.
No. If the thermal contrast of the scene is low, then a thermal imaging device with a lower thermal resolution (higher sensor NETD value) will show poorer detail distinction. Areas with similar temperatures will be shown on display as equal, and they will have the same brightness and contrast in the pixel group image. In fact, this means less spatial resolution.
Thus, the spatial resolution of the visible image is not constant and may decline with the decrease in the thermal contrast of the observed scene. It seems like a paradox, but thermal imaging devices with lower sensor resolution and better sensitivity (for example, 384×288 pixel @ 17 µm / NETD < 25 mK) can show low-contrast scenes in more detail than thermal imaging devices with higher resolution but lower sensitivity (for example, 640×480 pixel @ 12 µm / NETD < 40 mK).
The sensor sensitivity doesn’t affect the detection range (it depends on the lens focus and the pixel pitch of the sensor). In our example, the Helion 2 XP50 Pro and the Axion 2 XG35 have the same detection range of a standard 1.8m tall object. However, if we talk about the qualitative characteristics of the observation range, namely the distance of recognition and identification, then with a decrease in the scene contrast (fog, rain, mist, increased humidity), the Axion 2 XG35 thermal imaging device will “lose” noticeably faster.
Let’s get back to the examples. In each of the cases considered, the best image quality was shown by devices with a sensor with a NETD <25 mK. And both of these sensors have a pixel pitch of 17 microns.
The larger the pixel and the larger its area, the more LWIR (Long Wavelength Infrared) radiation it is able to receive and the higher the sensitivity of the entire thermal imaging sensor. The effect of sensor size on NETD underlies the very principle of sensors with one or another pixel size.
This is clearly seen in our example. The sensors have the same resolution, 640×480 pixels, but the sensor of the Helion 2 XP50 Pro thermal imaging device has a larger pixel size (17 microns vs. 12 microns) and, finally, a better sensitivity (NETD <25 mK vs. NETD <40 mK).
As a result, the Helion 2 XP50 Pro is a professional-level device. By purchasing this thermal imaging device, the customer pays not only for top image quality but also for the confidence that the device will cope with any surprises that the weather can bring during the hunting.
A few words about the advantages of sensors with small pixel sizes. Firstly, for thermal imaging devices with a sensor with a smaller pixel, the same detection range, magnification, and field of view can be achieved with lenses with a smaller focus. This is what the Axion 2 XG35 showed.
In a pair of the Axion 2 XG35 and the Helion 2 XP50 Pro, both devices have the same detection range. The Axion uses a lens with a smaller focus (F35/1.0) and the Helion – with a larger focus (F50/1.0), but the detection range of the devices is the same due to the smaller pixel in the Axion sensor. Under ideal conditions with the deterioration of thermal contrast at the observation site, the Helion 2 XP50 Pro will show better results as a device with the best NETD sensor.
Secondly, for the same resolution, a sensor with a smaller pixel size will have a smaller physical size. So, the device based on it can be made more compact.
If we compare a modern 12-micron sensor and a sensor of the early 21st century with a pixel of 25 microns, then the NETD of the latter one will quite possibly be higher since, over 20 years, there has been serious progress in the development of micro bolometric sensor manufacturing technologies and the quality of materials used.
In modern sensors, the larger the pixel size, the higher the sensitivity (the NETD index is lower). This is a general truth – using the same materials, it is impossible to create a thermal imaging sensor with a smaller pixel size, lower price and, at the same time, better sensitivity.
The NETD of the sensor is measured in compliance with the regulations, which are the same or similar for all manufacturers. But recently, there has been a transformation of NETD from a special technical characteristic into a popular tool for promoting devices, which is not always conscientious.
Now, the best production batches of sensors with a pixel pitch of 17 µm achieve NETD less than 25 mK, with a pixel pitch of 12 µm – less than 40 mK. At the same time, there are always a certain number of sensors with a lower NETD value in the batch. This means that manufacturers can assemble a small number of high-sensitivity thermal imaging devices that are used as demonstration samples at market launch. Meanwhile, such sensitivity cannot be maintained in the manufacture of any significant production batches of devices. However, in advertising and informational materials about the product, the overestimated sensitivity is declared throughout the entire life cycle.
When writing technical specifications in the device certificate, some manufacturers are guided by the parameters of market leaders and indicate the numbers that a potential consumer wants to see. As a result, today on the market, you can find devices with a NETD value less than 25 mK declared for sensors with a 12-micron pixel (for example, for a sensor 640×512 @12µm), which is not true.
Some manufacturers use and take into account signal post-processing, such as image filtering, to increase NETD value. The result obtained in this way cannot be considered as the NETD value of the sensor. More correctly, it is the NETD value of a thermal imaging device and looks nice on paper. In reality, improving the NETD (i.e., reducing the value of the parameter) due to image filtering leads to a decrease in the spatial resolution of the image visible on display, as well as to the loss of image detail and lowers its informational value.
In the development of sensors and thermal imaging devices, there are objective laws and limitations that cannot be bypassed. A top thermal imaging device cannot be cheap. If thermal imaging devices similar in terms of declared field and functional capabilities have a significant difference in price, then it is highly probable that a low price in a more affordable device is achieved by making compromises in terms of image quality. This should be kept in mind when choosing a thermal imaging device.
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