RSS
 

Posts Tagged ‘sensors’

Smartphone image sensors are low in supply

21 Aug

In May we reported that CMOS sensor sales were at an all time high and record numbers were expected for 2018.

It appears the strong sales have not slowed down at all over the summer, and we’re now in a situation where CMOS sensors are in short supply. Industry news publication IFNews quotes a number of Chinese sources that refer to an article in the Taiwan Economic Times, reporting that image sensors are now in short supply.

Big suppliers like Sony and Omnivision are increasing their prices for image sensors

This is largely due to dual and triple cameras becoming more commonplace on smartphones, with even mid-range models often featuring dual-setups now, sometimes at front and back.

As a result big suppliers like Sony and Omnivision are increasing their prices for image sensors. Smaller smartphone manufacturers who don’t get the same priority access to the big suppliers as major manufacturers are diverting orders to smaller sensor makers, such as Pixart and Silicon Optronics (SOI) to keep component cost under control.

The trend for multiple cameras and sensors on smartphones is unlikely to stop any time soon, so be prepared for increased sensor prices having a minor knock-on effect on final device retail pricing. On the plus side, as this development mainly affects the smaller sensor implemented in smartphone cameras, the impact on the market for the larger units used in DLSRs and most mirrorless system cameras should be minimal.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Smartphone image sensors are low in supply

Posted in Uncategorized

 

Canon is now selling CMOS image sensors, including a 120MP APS-H beast

23 May

It looks like Canon is getting into sensor sales. The three specialized CMOS sensors the company has been recently showing off—including a 120MP APS-H model and an ultra-low light sensor—have been listed for sale by special order through Canon, and through Phase 1 Technology Corp in the US. As far as we know, this is the first time Canon has publicly gotten into the semiconductor business.

That in and of itself is big news, despite the fact that these sensors are likely meant for security, machine vision and, say, astrophotography camera makers. There’s the 120MP APS-H sensor, which outputs images measuring 13280×9184 pixels; there’s a 2/3″ 5MP global shutter sensor that boasts “remarkably wide dynamic range”; and, finally, a 2.2MP full-frame unit with 19µm high-sensitivity pixels designed for extreme low-light shooting. All three are available in RGB and monochrome variations.

B2B sensor sales like this usually require you purchase more than one sensor, so at-home camera makers may not be able to get into the action, but we’ve contacted the company for a quote so we can share the price with you all the same. We’ll update this article if and when we hear back. In the meantime, you can find more information about all three sensors on the Phase 1 Technology Corp website.

Specifications

Canon 120 Megapixel CMOS Sensor

Available Variations:

  • 120MXSC: RGB
  • 120MXSM: Monochrome

Ultra-High Resolution CMOS Sensor

The 120MXS is an ultra-high resolution CMOS sensor with 13280 x 9184 effective pixels (approx. 60x the resolution of Full HD). It has a size equivalent to APS-H (29.22mm x 20.20mm), and a square pixel arrangement of 2.2µm x 2.2µm with 122 million effective pixels. Ultra-high-resolution is made possible by parallel signal processing, which reads signals at high speed from multiple pixels. All pixel progressive reading of 9.4 fps is made possible by 28 digital signal output channels. It is available in RGB or with twice the sensitivity, in monochrome.

Technical Information:

  • Sensor size: APS-H (29.22mm x 20.20mm)
  • Filter types:
    • 120MXSC: RGB
    • 120MXSM: Monochrome
  • Number of effective pixels: 13280h x 9184v, approx. 122MP
  • Pixel size: 2.2µm x 2.2µm
  • Progressive Scan
  • Rolling Shutter
  • 188pin ceramic PGA
  • Sensitivity:
    • 120MXSC (Green): 10,000e/lux/sec
    • 120MXSM: 20,000e/lux/sec
  • Saturation: 10,000e @ gain0.5x
  • Output Channels: Data 28 lanes, Clock 14 lanes
  • Dark Random Noise: 2.3e rms @ gain x8, Room Temp.
  • Dark Current: 8.1e/sec @ gain x8, 60°C
  • Number of output channels: Data 28 lanes, Clock 14 lanes
  • Main clock frequency: 45MHz (Recommended)
  • Output format: 720Mbps in LVDS output 9.4fps @ 10 bit
  • Built in column amplifier (Pre-amplifier gain mode: x0.5, x1, x2, x4, x8)
  • Serial communication
  • All pixel progressive scan reading function, Region of Interest (ROI) reading function (Vertically)
  • Vertically intermittent reading function (1/1, 1/2, 1/3, 1/5, 1/7, 1/15)
  • Power consumption: 2.5W (under recommended operating conditions)
  • Power supply voltage: 1.7 V, 3.5 V
  • Package size: 55.0mm x 47.8mm x 4.49mm

Canon 5 Megapixel Global Shutter CMOS Sensor

Available Variations:

  • 3U5MGXSC: RGB on-chip color filter
  • 3U5MGXSM: Monochrome

Global Shutter CMOS Image Sensor

The 3U5MGXS global shutter image sensor employs a new pixel design introducing new drive readout and light guiding technologies significantly expanding the full well capacity, reducing noise, and contributing to remarkably wide dynamic range with a power consumption of 500mW. Equipped with a global shutter and all pixel progressive reading at 120fps, the 2/3″ sensor size, and pixel size of 3.4µm with 5.33 million effective pixels (2592 x 2056) easily allow for applications in machine vision and other industrial environments where smaller size and high performance are required. It is available in RGB and Monochrome.

Technical Information:

  • Sensor size: Approx. 2/3 inch (8.8mm x 7.0mm)
  • Number of effective pixels: 2592h x 2056v, approx. 5.3M
  • Filter types:
    • 3U5MGXSC: RGB on-chip color filter
    • 3U5MGXSM: Monochrome
  • Pixel size: 3.4µm x 3.4µm
  • Maximum Frame Rate: 120fps
  • Global electronic shutter function
  • Progressive scan
  • Main clock frequency: 36MHz (Recommended)
  • Sensitivity:
    • 3U5MGXSC (Green): 30,000 e/lx/sec @Analog gain x1(TBD)
    • 3U5MGXSM: TBD
  • Saturation: 14,000e gain x1 (10 bit 60 fps) (TBD)
  • Output Channels Data: 12 lanes, Clock 2 Lanes
  • Output from LVDS: Maximum output of 864Mbps
  • Analog gain: 0 to 36dB
  • Digital Gain: 0 to 24dB
  • Dark Random Noise: 2.6e rms @ Analog gain x4(TBD)
  • Dark Current: 1.3 e/sec @Analog gain x4, Room Temp
  • Maximum Dynamic Range: 74dB (TBD)
  • Function: ROI function (8 region) Inverted output function (horizontal and vertical)
  • 180pin ceramic LGA
  • Power consumption (Typ): 500mW (full pixel scan at 60 fps)
  • Power supply voltage: 3.3V, 1.2V
  • Package size: 19.0mm x 18.1mm x 2.5mm
  • Exposure control by external trigger

Canon 19µm Full HD CMOS Sensor

Available Variations:

  • 35MMFHDXSC: RGB
  • 35MMFHDXSM: Monochrome

Full HD, High-Sensitivity, Low-Noise Imaging

The 35MMFHDXS CMOS sensor delivers highsensitivity, low-noise imaging performance, even in exceptionally low-light environments. The sensor’s pixels and readout circuitry employ new technologies that reduce noise, which tends to increase as pixel size increases. High sensitivity and increased well depth have been achieved through a larger pixel size of 19µm x 19µm (square) with proprietary device design technologies. The 35MMFHDXS CMOS sensor is available in RGB or Monochrome.

Technical Information:

  • Sensor size: 35mm film size (36.48mm x 20.52mm)
  • Number of effective pixels: 2000h x 1128v, Approx. 2.2MP
  • Filter types:
    • 35MMFHDXSC: RGB
    • 35MMFHDXSM: Monochrome
  • Pixel size: 19µm x 19µm
  • Progressive scan
  • Rolling shutter
  • Serial communication
  • 180pin ceramic PGA
  • Sensitivity:
    • 35MMFHDXSC (Green): 1,100,000e/lx/sec @gain x1
    • 35MMFHDXSM: 2,100,000e/lx/sec @gain x1
  • Saturation: 61,000e @gain x1
  • Dark RN: 2.2e rms @gain x16, around 35°C
  • Dark Current: 250e/sec @gain x16, 60°C
  • Simultaneous reading of vertical 4 lines
  • Drive frequency: 16ch x 18MHz (Recommended)
  • Output format: Source follower output (Analog)
  • Built in column amplifiers: (Basic pre-amplifier gain: x1, x4, x16)
  • Power consumption: 2.2W (At 60 fps under recommended operating conditions)
  • Power supply voltage: 5V, 3.3V, others
  • Package size: 60.9mm x 44.6mm x 3.57mm

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Canon is now selling CMOS image sensors, including a 120MP APS-H beast

Posted in Uncategorized

 

Video: Understanding the science of camera sensors

22 Apr

When we see a technical video posted online, purporting to explain some scientific concept that has to do with photography, we typically brace ourselves. More often than not, they fall into two categories: (1) oversimplified, or (2) blatantly incorrect.

That’s why this Filmmaker IQ episode on the science of camera sensors is such a breath of fresh air: not only is it factually solid, it goes into more detail and makes that detail easier to understand than just about any other technical breakdown of image sensor science we’ve seen… and they throw in a great explanation about how film works just to sweeten the pot.

The 13 minute video explains:

  • How photographic film uses a thin coating of silver halide crystals to capture light.
  • The science behind the photodiode that converts light into electrical current for all digital image sensors
  • How a Charged Couple Device (or CCD) sensor works, and its pros and cons.
  • How a Complementary Metal Oxide Semiconductor (or CMOS) sensor works, and its pros and cons.

If you’ve never bothered to dive into the science of image sensors or, every time you tried, the explanation was just too dense, give this video a look and let us know what you think in the comments below.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Video: Understanding the science of camera sensors

Posted in Uncategorized

 

Tech Insights teardown confirms Galaxy S9 uses Samsung and Sony image sensors

12 Apr

The analysts at Tech Insights have torn down the Samsung Galaxy S9 in order to analyze the device’s camera sensors and, as usual, the summary of their findings makes interesting reading for anyone who has an interest in image sensor technology. The main takeaway from Tech Insight’s report is that Samsung is once again using different image sensors by region.

Depending on where you buy the Galaxy S9, your device will either come with a Samsung S5K2L3 or Sony IMX345 chip.

Both imagers use a 3-layer stacked structure, comprising a CMOS image sensor, image signal processor (ISP) and DRAM. The Sony IMX345 is very similar in structure to the IMX400, the world’s first 3-layer stacked imager that was introduced on the Sony Xperia XZ flagship a year ago.

The Samsung S5K2L3 ISOCELL Fast sensor is the Korean manufacturer’s first 3-layer stacked model. In contrast to Sony’s custom solution with the DRAM in the middle, Samsung has opted for connecting the DRAM chip face-to-back on the ISP. The assembly also includes a dummy silicon structure filling the unoccupied space next to the DRAM chip.

This definitely won’t translate into noticeable performance or image quality differences between Galaxy S9 smartphones, but it does seem to show that Samsung is far from its goal of dethroning Sony to become #1 in the global image sensor market—it’s hard to dethrone the competition when you’re still using their sensors.

For a lot more detail on the sensor structure and assembly head over to Tech Insights, where you can also purchase even more in-depth reports if you really want to dive deep.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Tech Insights teardown confirms Galaxy S9 uses Samsung and Sony image sensors

Posted in Uncategorized

 

‘Perfect’ sensors may be possible, but might not come to cameras

24 Feb
Fossum’s team has created a prototype chip with a variety of pixel designs and readout methods. This included combinations with sufficiently low read noise to allow individual photons to be counted.

The future could include sensors that perfectly describe the light in the scene, that offer new computational possibilities and give film-like latitude in the highlights. And yet we may not ever see them in cameras, says father of the CMOS sensor, Professor Eric Fossum.

We spoke to Fossum shortly after he received, alongside three other pioneers of digital photography, the Queen Elizabeth Prize for Engineering for his work on CMOS sensors. But the topic of our conversation is the future, rather than his past achievements. He now leads a group at the Thayer School of Engineering at Dartmouth, New Hampshire, working on what he calls Quanta Image Sensors (QIS). The team has recently published a paper announcing a breakthrough using the same fabrication process used to make CMOS image sensors.

The perfect sensor?

The principle is to use nanoscale, specialized pixels, called ‘Jots’ to capture light at the level of individual photons. They work in a binary fashion: they’ve either received a photon or they haven’t (as opposed to conventional sensors which accumulate the charge generated by lots of photons during exposure). These jots are read repeatedly to see whether another photon has arrived since they were last checked.

While Fossum is keen to stress that other teams are having some success in the same field (using a slightly different approach), his own team’s work is looking very promising. The paper in the journal Optica shows the team’s technology has been refined such that a 1MJot chip can be read 1000 times per second while still exhibiting sufficiently low read noise that it can distinguish between individual photons.

We can count every photon: you can’t do any better than that

“The Holy Grail is no read noise,” says Fossum: “so that the read signal is proportional to the signal as it arrived.” And the team’s latest paper says they’ve got very close to this, with noise levels so low that the sensor can distinguish between individual photons without getting confused by read noise. This opens up the possibility of cameras that could perfectly describe the light in the scene, even in near total darkness.

A mathematical model showing how noise levels (measured in the root mean square of the number of electrons), affect the ability to interpret small signals. The lower the read noise, the more accurately you can distinguish between individual values in the signal.
Diagram from the team’s paper in Optica

Eliminating read noise from the sensor wouldn’t mean totally noiseless photos, since the randomness of the light being captured is a key source of noise, but it’s the best any sensor can possibly achieve. “We can count every photon: you can’t do any better than that,” he says.

The paper, perhaps conservatively, says the technology could be suited to scientific, space, security and low-light imaging applications, but Fossum has clearly also been thinking about conventional photography.

A classic response

“Because it’s binary in nature, its response is comparable to old photographic film,” he says. “In film, when the silver halide was hit by a photon, it’s reduced to a silver atom that isn’t washed away [during processing]. If it’s hit by two photons, it doesn’t make any additional difference.”

This ends up meaning that in bright regions of the image there are ever fewer unexposed silver ions as the exposure goes on. This, in turn makes it less likely that the last few ions will be hit by a photon, so it becomes increasingly difficult to fully saturate the system. The same is true for the tiny, binary Jots: as more of them become saturated, it becomes increasingly difficult to saturate the last few.

“The response is linear at moderate exposure but it trails off to give significant overexposure latitude. It’s a pattern first observed by Hurter and Driffield in 1890,” says Fossum: “they showed the same curve that we measure, experimentally, in our QIS devices.”

Diagram showing the Jots’ exposure response, in comparison to mathematical models of different read noise levels. Note the roll-off at high exposures, comparable to the Hurter Driffield response curves of photographic film.
Diagram from the team’s paper in Optica

“That has obvious interest both for still photographers who’re used to shooting film and for cinematographers who’re looking for that kind of response.”

The use of such tiny pixels has other benefits, too: “Jots are below diffraction limits in size. This means the resolution of the system is always higher than the resolution of the lens, which means we never have to worry about aliasing.” While the group’s prototype sensors feature one million Jots, Fossum says their target is one billion.

Beyond conventional photography

Fossum isn’t just thinking about photographic history, though. The tiny size and the approach of repeatedly reading out the sensor challenges the existing concept of single exposures. “At the moment we make motion pictures by shooting a series of snapshots. With QIS it’s more like the reverse process,” he says: constructing still images from precisely captured movement.

Professor Fossum has already been responsible for one revolution in photography: the invention of the CMOS sensor. In December 2017 he was awarded the Queen Elizabeth Prize for Engineering for his work.

Essentially, taking lots of short, sub-frames during an exposure gives you an extra dimension to your images: time. “If you take a single frame, you get a bunch of ones and zeros. If you take another, you quickly build up a cube of ones and zeros,” Fossum says: “For example, if you shoot 100 frames at 1000 frames per second, you get a cube that’s x pixels wide by y pixels tall, but also 100 frames deep.”

This presents some interesting questions, he says: “What do you do with that data? How do you create an image from that very faithful map of where photons arrived?”

“You could choose a number of pixels in x and y but also in the time axis. If you wanted a very sensitive pixel in low light you could combine 10 x 10 Jots in x and y and then maybe combine the data from 100 frames: it’s essentially like increasing the grain size in a more sensitive film.”

Of course you can achieve something comparable to this in conventional digital photography by downscaling an image, but Jots allow greater flexibility, Fossum says: “your pixel size could vary between different parts of the image, so in some places you’d have bigger but more sensitive grains.”

What is the object of photography? Is it artistic or an attempt to perfectly recreate the scene as it was?

The time component also opens up additional possibilities, he says: “if an object moves during these hundred frames, instead of adding all the values from the same location, you could add them at an angle that corresponds to the movement,” so that all the pixels relating to the same object are combined. “We could take out motion blur or remove the scanning effect of a computer screen in video.”

The idea of combining multiple frames in interesting ways is, of course, already becoming a core part of mobile photography, and Fossum says finding all the things that are possible is a challenge he is leaving for others: “From my point of view, we’re building a platform for computational imaging, it’s for others to develop all the ways to use it. A camera would have to take account of the new sensor capabilities.”

But it’ll ask interesting questions, he believes: “What is the object of photography? Is it artistic or an attempt to perfectly recreate the scene as it was? Some of the things we associate with photography are artifacts of the way we capture them.”

Not the only future

With all this going for it, it might seem odd that Fossum isn’t promising to deliver a second revolution in digital imaging. But, having devoted a career to developing technologies and teaching about the challenges, he’s realistic both about the work left to do and the competition any product would face.

“What we’ve already achieved is wonderful. The next challenge is adding color [awareness], but I don’t think that’s going to be particularly problematic. Then there’s power: we’ve shown we can produce a large chip that doesn’t consume or disperse a prohibitively large amount of power. We’re currently at around 27mW but scale it up by 1000 [to get to one billion Jots] and that’s 27W, so we need to cut that by about a factor of ten.”

His concern is more about the current state of the rival technologies: “In order to bring a new technology to replace the existing one, it has to be compellingly better in a number of ways,” he says. “For a few niches, [our technology] is already compelling.” But for photography, the bar is already set very high.

I don’t want our startup to be another esoteric imaging product that fails to find a market

“CMOS technology is pretty awesome right now,” he says, before almost embarrassedly stressing that he’s not claiming the credit for this: “where it is today is the result of the input from thousands of engineers from different companies who’ve contributed towards where we are now.”

Professor Eric Fossum pictured with Dr Jiaju Ma, one of the co-authors of the Optica paper and a co-founder of the spin-off company, Gigajot Technology.

But, for all his cautious words, Fossum is convinced enough by the technology’s potential to have created a company, Gigajot Technology, with his co-researchers. “Finding a sweet spot in the market is a really important part of challenge. It comes back to the things I teach: ‘who is your customer?’ ‘what is your market?’ ‘how are we going to get there?'”

“I don’t want our startup to be another esoteric imaging product that fails to find a market,” he says.

While it’s by no means certain that QIS sensors will make their way into mainstream cameras, it already looks like the technology has tremendous potential for niches such as scientific measurement. This alone shows just how far the technology has come from Fossum’s original idea. As he readily admits: “When we first started this project I wasn’t even sure it could be made to work.”

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on ‘Perfect’ sensors may be possible, but might not come to cameras

Posted in Uncategorized

 

Samyang unveils ‘premium’ XP 50mm F1.2 lens for 50MP sensors and 8K capture

20 Feb

It’s official! 24 hours after product photos leaked online, the rumored Samyang/Rokinon XP 50mm F1.2 lens for Canon EF Mount has officially arrived. This is the third so-called “XP” lens—the first two, which were announced in 2016, were the XP 85mm F1.2 and XP 14mm F2.4—which are named for their ‘Excellence in Performance.’ That is: they’re designed to resolve over 50 megapixels for photography purposes, and easily capture crisp 8K video.

Like those lenses, the XP 50mm F1.2 is manual focus and currently only made for the Canon EF mount. It boasts a 9-blade aperture, and is made from 8 groups of 11 lens elements, including one aspherical and one high-refractive lens element that promise to “deliver sharp and vivid images to camera sensors by effectively tuning the light path.”

Finally, Samyang has also included its “ultra multi coating” to help ameliorate flare and ghosting. Here’s a closer look at this lens:

$ (document).ready(function() { SampleGalleryV2({“containerId”:”embeddedSampleGallery_7420838441″,”galleryId”:”7420838441″,”isEmbeddedWidget”:true,”selectedImageIndex”:0,”isMobile”:false}) });

And here are some sample photos, posted by Samyang on the new XP 50mm F1.2 product page alongside an MTF chart and detailed specs:

$ (document).ready(function() { SampleGalleryV2({“containerId”:”embeddedSampleGallery_6295771671″,”galleryId”:”6295771671″,”isEmbeddedWidget”:true,”selectedImageIndex”:0,”isMobile”:false}) });

Samyang/Rokinon XP 50mm F1.2 spec sheet

The Samyang XP 50mm F1.2 will be available for purchase in March, at an expected retail price of 950 Euro (and very likely the same price in USD). To learn more, head over to the Samyang Global website.

Press Release

Samyang Optics Launches the Premium Photo Lens- XP 50mm F1.2

February 20th, 2018, Seoul, South Korea – Global optics brand, Samyang Optics (http://www.samyanglensglobal.com) is pleased to unveil the Premium Photo Lens – XP 50mm F1.2 for Canon full frame DSLR cameras. The XP 50mm F1.2 is the third lens of the premium line up, XP series, created under the motto of ‘Excellence in Performance’. The XP 50mm F1.2 lens is expected to expand the brand power of Samyang in the premium lens market thanks to its great image quality, following in the footsteps of the XP 14mm F2.4, XP 85mm F1.2.

The moment of the drama with absolute resolution

This lens, built for DSLR cameras, has a resolution of more than 50 megapixels for photography and 8K for video. The XP 50mm F1.2 manual focus lens enables you to capture those dramatic moments in perfect image quality with a bright F1.2 aperture. In particular, it optimizes for portraits, capturing the delicate change of the eye at the time of a portrait, right down to a strand of hair, and bright and beautiful skin colour. You can express unconstrained depth with the bright aperture, while the 9 blades also deliver beautiful bokeh, starburst, and out-focusing effects. Also, you can even achieve high image quality in low light conditions and indoors thanks to the fast shutter speed

Excellence in Performance

Produced from a total of 11 lenses in 8 groups, you can minimize distortion and various aberrations while producing crystal clear resolution. The special optic lenses, aspherical lens, and high-refractive lens deliver sharp and vivid images to camera sensors by effectively tuning the light path. Also, flare and ghost effects can be well controlled thanks to the ultra multi coating.

Available from March 2018

The absolute resolution XP 50mm F1.2 lens will be available in March at a suggested retail price of EUR 949. To celebrate the launch, Samyang Optics will hold various consumer events on Facebook and Instagram. For more information on the product, visit Samyang Optics’ official website.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Samyang unveils ‘premium’ XP 50mm F1.2 lens for 50MP sensors and 8K capture

Posted in Uncategorized

 

Samsung’s new smartphone sensors can shoot 480fps in Full HD

22 Jan

Samsung has just announced a new mobile image sensor that may just reveal what’s in store for the rumored Galaxy S9 smartphone—specifically in the slow-motion capture department.

Announced earlier today, Samsung’s new ISOCELL Fast imager chips feature a 3-stack Fast Readout design that Samsung claims will shoot Full HD 1080p video at a whopping 480fps. That’s not quite as fast as the eye-watering 960fps in Sony’s high-end Xperia models, but the Sony mode can only capture for a fracture of a second—Samsung’s super-slow-motion could potentially offer longer capture times.

According to Samsung’s product page, the ISOCELL fast sensors also come with advanced autofocus technologies—such as Dual-Pixel or Super-PD—built into the chip, allowing for very fast focusing in all light conditions. ISOCELL Fast sensors with the aforementioned technologies are currently available with 12 and 16MP resolutions and sizes ranging from 1/2.8″ to 1/2.56″.

As usual, there is no way of knowing for certain if either of these sensor variants will make it into the Galaxy S9, but it’s safe to assume we’ll see the new 480fps Full HD mode in a Samsung mobile device in the near future.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Samsung’s new smartphone sensors can shoot 480fps in Full HD

Posted in Uncategorized

 

DxOMark: The full-frame Leica M10 is ‘on par’ with the best APS-C sensors

16 Dec

DxOMark has just finished a new sensor test, and for once it’s not a “highest rated camera in the world” announcement. Instead, the testing and consulting company put the new Leica M10 to the test to see how it compares to the rest of the luxury brand’s lineup. The results: they’re calling it “a classic reinvented.”

Unlike the top-scoring Nikon D850 and Sony a7R III—both of which scored 100 and sit at the top of DxO’s full-frame sensor rankings—the M10 pulls in a meeker score of 86. However, that still makes it the second highest scoring Leica ever, just behind the Leica SL with an overall score of 88.

What’s intriguing is that, in terms of sensor performance, the Leica M10 actually scores “more on par” with the best APS-C chips DxO has tested, outperforming them significantly only in the low-light ISO category thanks to its physically larger sensor:

Image: DxOMark

DxO summed up these results well for us in an email:

Overall, better image quality can be found elsewhere for less money, but the Leica offers first-class engineering, and a digital camera with similar proportions to analog M cameras will be hugely appealing to Leica enthusiasts. Add to that compatibility with almost all Leica lenses ever made, as well as its simplicity of operation, and the M10 will be an attractive proposition to those who appreciate the quality of the Leica system.

No doubt a good chunk of our readers will bold-face and underline what DxO said above: “better image quality can be found elsewhere for less money.” But does the massive lens library, top-notch engineering, ‘simplicity of operation,’ and that pretty red dot help balance out the cost at all?

Head over to DxOMark to read the full review, and let us know what you think about these results in the comments.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on DxOMark: The full-frame Leica M10 is ‘on par’ with the best APS-C sensors

Posted in Uncategorized

 

Sony to shift focus as demand for automotive image sensors increases

26 Oct

Sony is the largest supplier or CMOS image sensors worldwide, with about half of its production capacity reserved for mobile device image sensors. However, according to a DigiTimes report, the company is now looking to expand its position in the market for automotive image sensors, where rivals On Semiconductor and OmniVision are currently the largest players.

As a consequence Sony is planning to allocate a larger portion of its sensor production capacity for advanced driver assistance systems (ADAS) and other automotive electronics applications.

Self-driving vehicles have been identified by sensor suppliers as a major growth area that will generate elevated demand for image sensors in the near future. According to DigiTimes sources, automotive is expected to overtake mobile devices as the leading application for CMOS sensors and will be first among all auto electronics segments, with major growth kicking in during 2018.

According to Digitimes, increasing demand for CMOS sensors through high-end smartphone and automotive applications could be bad news for consumers as the average unit price of CMOS sensors is expected to rise. The global market volume for CMOS sensors is forecast to increase to nearly US$ 13.8 billion in 2020, up from US$ 11.2 billion in 2017.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on Sony to shift focus as demand for automotive image sensors increases

Posted in Uncategorized

 

New Samsung image sensors use dual pixel for fast AF and fake bokeh

13 Oct

Samsung Electronics has launched a couple of new image sensor—both intended for use in mobile devices—under its ISOCELL sensor brand—the ISOCELL Fast 2L9 and the ISOCELL Slim 2×7.

As the model name suggests, the ISOCELL Fast 2L9 is part of the Fast line-up, providing fast autofocus speeds, even in low light conditions. To achieve this, the chip is using dual-pixel technology with two photo diodes at each pixel location. This not only speeds up autofocus but, according to Samsung, also allows for creation of a software-based bokeh-effect without the need for a dual-camera, which is more or less what Google’s new Pixel 2 devices do.

The 12MP sensor comes with a 1.28µm pixel size, which is slightly smaller than the 1.4µm currently used in Samsung flagship phones.

At 0.9µm, the pixel size is even smaller on the second new sensor, the Slim 2X7. Like the Fast 2L9, it is designed to fit into even very thin devices without the need for a camera bump, but this one comes with a higher 24MP pixel count. In low light, the sensor combines the image information captured by four neighboring pixels to increase sensitivity and reduce image noise, a process which Samsung calls Tetracell.

Like in other ISOCELL sensors, Deep Trench Isolation technology is applied to improve dynamic range and reduce color crosstalk on both sensors.

Looking at the technologies used in these new sensors it is evident that as a maker of both hard and software, Samsung is an excellent position to design its sensors with computational imaging applications already in mind. Unfortunately, there is no information yet on when we’ll see the new sensors integrated in actual devices.

Articles: Digital Photography Review (dpreview.com)

 
Comments Off on New Samsung image sensors use dual pixel for fast AF and fake bokeh

Posted in Uncategorized

 
« Older Entries
Newer Entries »