This is going off of today's iPhone 5S announcement, when Phil Schiller said that "bigger pixels" is the key to a better picture.
- What does this mean?
- Is it true or just a marketing ploy?
by Paul Cezanne
What does this mean?
This is referring to the size of the photodetectors, which represent the pixels, on the camera's sensor.
In short, the more light reaching these photodetectors, the more accurately they can measure light levels, thus reducing noise. To simplify things, noise is usually a factor in low-light photography.
There are two ways to get bigger photodetectors on a sensor:
The former is a trade-off against resolution, whereas the latter is a overall gain. In the iPhone 5S, they've gone with the latter.
Small sensors such as those in cellphones and compact cameras suffer the most from having small pixels, because their pixels are tiny compared to those in DSLRs and other professional/prosumer cameras.
The megapixel race
The desire to cram more and more pixels into camera sensors has harmed the sensitivity of the sensors, particular small sensors in cellphones and compact cameras, resulting in more noise at the same light levels.
Unfortunately, it was driven by the mentality that "more pixels = better", as megapixel count is very easy to market your camera by. In reality, diminishing returns ensure that the more pixels you add, the less important it is to add more, and we're getting to the point where a lot of sensors, particularly the tiny ones inside cellphones, can't even resolve enough resolution to justify the megapixel counts anyway, making those extra megapixels more a burden than a benefit.
Advancements in technology such as microlenses and back illumination, along with more advanced noise reduction algorithms, have gone some way toward making up for the lost sensitivity due to increased pixel counts in such a small sensor, but not far enough: today's cellphone cameras are still horribly noisy due to their small light-gathering area.
It is very difficult to market your camera based on sensitivity or other aspects of image quality, when megapixel count remains the primary marketing statistic associated with digital cameras, however misleading.
So why is Apple marketing it this way?
The uninformed public still expects that if a camera improves, its megapixel count rises.
Apple, however, is releasing a "better" camera in their cellphone, but with no rise in megapixel count.
Technically, this is a good idea for image quality. However, it's difficult to explain to people why, when they've been conditioned to believe that megapixel count is the primary metric for image quality.
Marketing the iPhone 5S camera in this way is an attempt to:
Unfortunately they are not the first to attempt this same revolution and won't be the last. The megapixel myth is very firmly entrenched.
Note: in response to some comments below, I define the "megapixel myth" as the myth that pixel count is the primary factor determining image quality and that more pixels is always better quality - not that pixel count doesn't have any benefit. Also inherent to the problem of the megapixel myth is that it distracts from important statistics such as sensor size, which is virtually never even talked about for cellphones and compact cameras.
Is it true or is it a marketing ploy?
It is one of those rare marketing ploys that is also true.
It is true that bigger pixels = better sensitivity, and in this case they've kept the same number of pixels and made them bigger (not very much bigger, though! - it's a very tiny increase). This should result in lower noise (or, if the camera can use faster speeds as a result, possibly less motion blur in low light). Their actual claim that "bigger pixels = better picture" is a simplification of this and could potentially confuse people into thinking their outdoor daylight pictures might also be improved.
In reality, when there is plenty of light you are not going to notice a difference. In low light, it will make a positive difference. Due to the size increase being so slight, the difference may not be noticeable, and won't be revolutionary, but it will give low-light photography a small boost. Phone users don't want to have to worry about how much light they have, they just want to take a decent picture. A larger sensor, with the camera in auto mode, will result in slightly better pictures when the light is low, which is a good thing. Don't be mislead into believing that the sensor will have the sensitivity or quality in low light anywhere near that of a DSLR, however. We're only talking about a 6.6% increase in sensor size.
It's also a marketing ploy because previously their marketing did focus on megapixel count, and yet they've now switched the way they market because they have chosen to forego pixel count and focus on other improvements, and they now have to distract from any talk about megapixel counts. It just so happens that this ploy is a positive one.
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In theory having more smaller pixels is better than having fewer large pixels.
A small pixel will capture fewer photons and thus it's output is noisier, but by taking more samples the noise averages out, by simple resampling you can simulate the result of a sensor with fewer larger pixels.
But you can do better than simply matching the result of larger pixels. More small pixels together capture more information. Big pixels let you know how many photons fell in say a 5µm x 5µm area. Small pixels also tell how many photons fell in that same area, but can also reveal how many fell the upper left 25µm x 25µm region, the lower right 25µm x 25µm region etc. this extra information can be used for smarter resampling to yield less noisy more detailed images at the same resolution as a camera with larger more sensitive pixels.
In practice things are never quite equal. When read noise is taken into account reading the values from 4 smaller pixels means taking the read noise penalty four times, leading to greater noise in the shadows and reduced DR. This shouldn't be a problem with the latest Sony Exmor sensors with ultra low read noise but may be the reason Canon have as of 2013 not produced a body with more than 22MP).
Pixels aren't flat entities. Usually the photosensitive part is at the bottom with the surrounding electronics on layers above. This makes the pixels a bit like a well. When you make pixels very very small, the proportion of photosensitive area goes down and the depth of the well as a proportion of it's width gets much larger, reducing the number of angles it can receive light from and thus the sensitivity.
This is where they're at with phone camera sensors, they can't increase the number of pixels without seriously sacrificing fill fraction and angular efficiency, hence to try and appeal to consumers they're reducing the number of pixels. The best solution is to make the sensor bigger, but that would require a bigger lens and wouldn't allow for a super slim body that sells lots of phones.
There are also disadvantages to having fewer larger pixels. The reduced sampling frequency leads to increased moire, requiring stronger anti-alias filters exacerbating the problem of reduced resolution. A lower sampling rate also leads to more demosaicing errors.
Sadly the "small pixels bad" mantra is applied across format sizes and is causing camera manufacturers to become reluctant in pushing quality forward by increasing pixel counts as the "conventional wisdom" is that it's a bad idea and makes images noisier, more prone to camera shake, and requires better lenses (every one of these points untrue).
It's all about catching the light that comes in as accurately as possible.
It's fairly simple, with a bigger surface (per pixel) you will catch more light and be able to make a more accurate representation of that light in the end-result.
It is true that the photo's will be better, but just 15% per pixel isn't spectacular. So it's marketing as well. Nokia has done a similar thing with their PureView. Downsampling 41 Megapixels to 5-10 megapixels will also dramatically decrease noise-levels. Nokia's PureView will be superioir to this if you ask me.
The main idea here is that bigger sensor yields better picture (if the sensors use the same technology). What Apple have done is to increase the sensor size, and by keep the same number of pixels each pixel will have a higher signal-to-noise-ratio, resulting in a better picture.
There are two main advantages from making bigger pixels:
However even if we are debunking the well know myth of mega pixel we are generalizing "the bigger the better" truth about sensors. Of course how stated above is true but the performance of a camera depends from many other factors. To project an image in a bigger sensor maintaining a short distance between the frontal lens and the sensor (as an iPhone have to do) you need more lenses, and if the quality of one of these lens are not good, all the performance of the system will be worst. So "Bigger Pixels = Better Picture" is more a slogan than a law.