A lot has been said in past few weeks about Sony's new 48 MP sensor (called IMX586), which is used in the recently released Honor View20. As a photography enthusiast, I was intrigued and I must admit that the more I dug into the issue, the more some of the information did not add up.

Before we start

I want to note that I'm not trying to push for or against certain smartphone manufacturers in this article. I'm not even attacking Sony for its work. I'm sure the company's engineers have valid reasons every every choice made in the design of the sensor. I invite them, in case they are reading this article, to correct me or explain these choices.

Obviously comments and objections from you readers are also welcome, as long as you keep the conversation civil and respectful.

Is the Sony IMX586 really a 48 MP sensor?

In theory, yes, in practice, not so much. Reading the specsheet published by Sony, you can find the phrase "48 effective megapixels" everywhere. The table shows a resolution of 8000x6000 pixels which actually equals that number. But let's take a closer look at the sensor...

Redmi Note 7 uses a 48MP sensor manufactured by Samsung. / © Redmi

In a sensor that uses a Bayer array pixel arrangement, each individual photoreceptor is physically filtered so that only green, red or blue light wavelengths can pass through (a common practice that mimics the way the human eye operates). The sensor electronics are then responsible for transforming groups of adjacent pixels into the actual color that has been "perceived" by the individual pixel by borrowing information from neighbors and using some good old math. This is done by taking the values of two green pixels (G) averaged, one red pixel (R) and one blue pixel (B).

On the IMX586 Sony uses a pixel arrangement called Quad Bayer array, which is nothing more than a classic Bayer Array arrangement (used on virtually every existing smartphone sensor) but where instead of every single pixel four pixels have been placed to form a 2x2 square. This article by our colleagues at GSM Arena explains perfectly how the Quad Bayer matrix works on the Huawei P20 and P20 Pro smartphones.

Filter with Bayer matrix. / © Wikipedia

Now, you can undestand how grouping 4 pixels of the same color next to each other in a Quad Bayer matrix is almost equivalent to having a sensor with a Bayer matrix with double-sized pixels (measured on the side, quadruple as an area). Knowing this, the Sony IMX586 is closer to the definition of 12 MP than 48 MP as claimed.

However, we can't say that the information is wrong, because each individual photoreceptor is separate from the one adjacent to it, so technically there are 48 million ...

The difference between Bayer and Quad-bayer. / © GadgetByte

So much marketing

Sony claims that this configuration allows both high sensitivity and high definition for its sensor. I can't say anything about the sensitivity: by grouping 4 pixels of the same color together you get the equivalent of a single 1.6-micron photoreceptor, instead of the (poor) 0.8-micron single light receptor.

What you have to remember, however, is that this is only slightly larger when compared to the more common Sony IMX363 which has pixels the size of 1.4 microns, not to mention that in that case the pixels really have that size and are not interpolated. On the IMX586, taking into account the Quad Bayer array (to simplify, the grouped version resulting in 12MP) the simulated photoreceptors are only 30% larger than the IMX363. On the contrary, if we take into account the individual pixels, we have a 67% smaller area.

I don't know about you but for now I see few advantages and many disadvantages. / © NextPit

However, Sony says that it only uses the native resolution for high brightness because such small pixels really need a lot of light to perform properly. The smaller the photoreceptor, the more likely it is that noise will appear (resulting in degradation of image quality) as the brightness drops. When the brightness is not the best, the pixel grouping system is used to reduce the noise and increase the overall sensitivity of the sensor (best SNR value) at the expense of the resolution.

As we have seen before, however, the photoreceptors are arranged using a Quad Bayer matrix and this is where my biggest doubt arises. Since these pixels are physically filtered by certain light frequencies, it is not possible to move and transform a Quad Bayer matrix into a Bayer matrix to take full advantage of the 48 MP. The individual photoreceptors would need to be physically moved.

A sensor made as shown on the left cannot be transformed into the one shown on the right. / © Sony (edited)

The result is therefore only an approximation of what a true 48 MP sensor with a Bayer matrix would be able to capture. How come? Because it is more difficult to determine the color captured by individual pixels when relying on information from neighbours who likely share the same color.

Size matters

The Sony IMX586 has a surface of 30mm² and this where it must stuff all of its 48 million pixels. The sensor is therefore smaller than the 40 MP one used on the Huawei P20 Pro or Mate 20 Pro, which measures at 45mm² (7.76x5.82mm) and shares the same Quad Bayer matrix. Not only that, but the now extinct Nokia Lumia 1020 (41 MP, 58mm²) and Nokia 808 (41 MP, 85mm²) are doing much better, with the Symbian OS device still reigning supreme with the largest sensor ever inserted into the body of a smartphone (excluding the Panasonic Lumix DMC-CM1 experiment).

Size matters in photography. / © Sony

In addition, many other factors must be taken into account, such as the lenses used and the processing that is done to the data collected by the sensor. For example, the image processing done by Honor and its Kirin 980 on the View20 newcomer could be very different from that performed by competitors with different chips.

For now, I have to admit, I wasn't impressed. I used an Honor View20 in Berlin and during the winter most days are dominated by the color gray. I was able to get pleasant images in broad daylight only by taking advantage of the 12 MP capture modes (however not at the level of other smartphones I have tested). In comparison, the photos I took with the 48 MP mode were mostly unusable. The sensor seems to lose a lot of quality at the edges of photos and I also noticed a lot of noise when zooming. Would you really buy a smartphone to take pictures only during the day and only on sunny days?

Below you can see two examples of photos taken at 48MP during the day and at night in less than ideal conditions:

I'm not saying that you should avoid buying smartphones that use the Sony IMX586 sensor, but it seems fair that you are aware that:

More megapixels do not necessarily result in better photos. The sensor is not larger (and therefore does not capture more light) than the competition. The software and hardware that accompany it can make a huge difference in the era of computational photography. You don't have to be fooled by the marketing that revolves around these huge numbers of pixels. If the flagships (which are constantly under the magnifying glass of the fans) do not use this sensor, maybe there is a reason for this. This is only my opinion 🤓

Now, after reading my personal outburst supported by the data I was able to collect during my research, feel free to challenge me or share your opinion in the comments!