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Posts Tagged ‘Optical’

Video: A ‘Retro Review’ of the 20-year-old Canon Pro90 IS, Canon’s first digital camera with optical image stabilization

12 Jun

Gordon Laing, Editor of Camera Labs, is back again with another episode of ‘Retro Review.’ In this video, he puts the Canon Pro90 to the test to see how well it holds up two decades after it was released.

At the time of its release, the Canon Pro90 IS was Canon’s flagship PowerShot camera. It retailed for $ 1,300, used a 3.3MP sensor and had a design similar to its Pro70 predecessor, but featured a 10x zoom lens compared to the 2.5x zoom lens on the Pro70. It was also Canon’s first camera with optical image stabilization.

As impressive as the optics were though, the camera had an interesting design quirk—the image circle of the lens didn’t fully cover the 1/1.8″ sensor, so the resulting images were digitally cropped down to just 2.6MP. Incredibly, the camera featured a Raw capture mode though, in addition to JPEG support (with various compression ratios) as well as QVGA (329 x 240 pixel) video recording.

To find out more, set some time aside to watch the entire 12 minute video. To see more Retro Review content and other interesting insights on vintage tech, head over and subscribe to Laing’s Dino Bytes YouTube Channel.

Articles: Digital Photography Review (dpreview.com)

 
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Oppo shows off its next-generation optical zoom camera module with 85-135mm equivalent focal length

20 Aug

Oppo has announced (translated) it’s latest camera technology, a next-generation periscope zoom camera that features improved optics, a new sensor and updated image processing algorithms.

The new camera module features an 85mm to 135mm full-frame-equivalent focal length with an aperture range of F3.3 through F4.4. To achieve this, the module uses seven elements in three groups with the two rear-most groups being the ones that move for zooming and focusing.

In addition to new optics, the camera module uses a new 32MP quad-bayer-like sensor. Both the movement of the lenses and image processing will be powered by the custom-designed 16-bit image processing chip inside the module.

Sample images from the new camera module captured with the wide angle (left), equivalent 85mm focal length (center) and equivalent 135mm focal length (right).

If we’re to assume this would be used in a smartphone with a 26mm main camera — such as the Oppo Reno 10x zoom — this new camera would offer a 3.3x to 5.2x optical zoom and presumably feature the same ‘hybrid zoom’ up to 10.4x. Even though the multiplication factor is roughly the same as that found on the Reno 10x zoom, Oppo says its new hybrid zoom technology improves image quality, as can be seen in these example images (older ‘hybrid zoom’ images on the left, new technology on the right):

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There’s no mention of when we could see this new camera tech, nor what phone it might be in, but as noted by GSM Arena, details of a forthcoming Oppo phone believed to be the Reno 10x zoom successor were revealed last month.

Articles: Digital Photography Review (dpreview.com)

 
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Xiaomi Mi 10 Ultra comes with 120mm optical tele, 120Hz display and more

12 Aug

Electronics manufacturer Xiaomi is celebrating its 10th anniversary with an event in China today and to mark the occasion the company has launched a new top-end-phone, the Xiaomi Mi 10 Ultra.

The Ultra shares quite a few specifications with its sister model Mi 10 Pro which was released in February, but, at least in terms of specifications ups the camera game considerably. Both devices come with a quad-camera setup, including short and long tele cameras as well as an ultra-wide. However, the Mi 10 Ultra comes with improvements in several key areas.

The long tele now offers a 120mm equivalent focal length (approximately 5x) versus 94mm on the Pro and comes with a larger 48MP sensor (1/2-inch versus 1/4.4-inch). The lens is stabilized and features a F4.1 aperture.

Wide-angle performance has been boosted, too. The Mi 10 Ultra ulta-wide camera features one of the widest fields-of-view in the market at 12mm (16mm on the Pro), making it an interesting option for mobile photographers with a focus on landscape and architecture. The ultra-wide uses a 20MP 1/2.8-inch sensor and comes with a F2.2 aperture and PDAF.

The short tele provides a 2x zoom factor (50mm) and is also used in portrait mode. Light is channeled through a F2 aperture and onto a 12MP 1/2.56-inch sensor. This module features a Dual-Pixel AF.

The primary camera offers a 25mm equivalent field-of-view and uses a 48MP Quad-Bayer sensor instead of the 108MP variant in the Mi 10 Pro. The large sensor (1/1.32-inch) combined with a fast F1.85 aperture and OIS should make for very decent low light image quality, though. In addition the camera array features a multispectral color temperature sensor to support the auto white balance system.

In video mode the Mi 10 Ultra is the latest device capable of recording 8K video at 30 frames per second. When shooting at 4K the frame rate can be increased to 60fps which should make for smooth panning and motion. At the front a 20MP selfie shooter hides under a ‘punch-hole’ cutout.

Non-camera specs and features are flagship-worthy, too. The phone is powered by Qualcomm’s top-end chipset Snapdragon 865, including 5G modem, and features the latest generation LPDDR5 RAM and UFS 3.1 storage for swift data transfers and overall performance.

Images and videos can be viewed on a 6.67-inch FHD+ OLED display with a high 120Hz refresh rate for smooth and responsive operation. In the battery department the Xiaomi offers 120W fast-charging, with the compatible charger provided in the box. The company claims the system can charge the 4,500mAh battery to 100 percent in only 23 minutes, or to 41 percent in five minutes. 50W wireless charging and 10W wireless reverse charging are available, too.

The Mi 10 Ultra also comes with in-display fingerprint sensor, IR blaster, NFC and stereo speakers. The display is protected by a layer of Gorilla Glass 5. The back is covered with Gorilla Glass 6.

Pricing has so far only been released for Xiaomi’s home market. In China the Mi 10 Ultra starts at 5,299 yuan (approximately $ 763) for the 8GB/128GB version but you’ll also be able to pick up 8GB/256GB, 12GB/256GB and 16GB/512GB options in either Obsidian Black, Mercury Silver or as a Transparent Edition.

Articles: Digital Photography Review (dpreview.com)

 
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O-Film demonstrates smartphone camera module with 85-170mm equivalent optical zoom

17 Jun

The zoom performance of smartphone cameras has improved dramatically in the last couple of years or but still lags behind conventional cameras, despite dedicated tele lenses pretty much being the norm on high-end smartphones these days. It’s fair to say that overall, zooming on a smartphone camera is at this point still a bit of a compromise, but that could soon change, though.

Chinese camera module supplier O-Film has demonstrated a periscope-style smartphone lens that provides an optical zoom range of 85-170mm (35mm equivalent). This, in theory, should provide a more consistent image quality across the zoom range than current models.

Most tele cameras inside flagship smartphones provide magnification factors between 3x and 10x compared to the primary camera, but speaking about ‘zoom’ factors in this context is slightly misleading. In most instances, the tele camera use lenses with a fixed focal length and computational methods are used to deliver the stated zoom ratios.

At intermediate zoom settings between primary and tele cameras most models use digital zoom/cropping and other computational imaging methods that combine image data from both cameras to create an output image. This Samsung system illustrated in the video below is a good example:

In practice, this means that if you want the best possible image quality you will have to shoot at the native focal lengths of either the primary or tele camera. At intermediate settings your images will, at least under close inspection, almost certainly show a loss of detail and/or a range of fusion artifacts. For example, on some models the level of detail at the center of the frame is high because this portion of the image is captured with the tele camera. Often a lack of detail is visible towards the edges, though, as these areas of the frame are ‘filled’ with digitally zoomed image data from the primary camera.

O-Film’s solution should avoid these kind of image quality inconsistencies by providing optical zoom across the entire range of focal length from 85-170mm (35mm equivalent). The module’s aperture ranges from f/3.1 at the wide end to f/5.1 at the maximum tele setting, which is pretty much in line with the apertures on most fixed-focal-length tele cameras. At only 5.9mm the module is also impressively thin which means it should fit into the sleek form factors of most current flagship devices.

The zoom range of the O-Film module is roughly equivalent to a 3-7x zoom factor but the company claims it can also provide 3-5x, 5-8x and 3.5-9.5x variants.

Like other periscope style lenses with a fixed focal length, such as the one found in Oppo’s 5x camera module, the O-Film module uses an optically-stabilized prism to divert incoming light onto the image sensor. What’s different in O-Line’s module is a piezoelectric motor that drives a module with three lens groups to adapt the focal length. The autofocus mechanism moves with the lens elements.

If the new system works as advertised in the near future image quality on smartphones could be much more consistent across the zoom range than it is now, offering greater flexibility to mobile photographers. Unfortunately, there is no word yet on when we might see the zoom in a production smartphone.

Articles: Digital Photography Review (dpreview.com)

 
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Huawei launches P40 series with Leica-badged cameras and up to 10x optical zoom

27 Mar

Chinese manufacturer Huawei has today launched the latest generation of its camera-centric high-end P-series. The P40, P40 Pro and P40 Pro+ share the Kirin 990 5G chipset and the large 1/1.28-inch image sensor in the main camera but otherwise differ slightly in a range of areas.

The Huawei P40 Pro+

Large main camera sensor

Like for previous Huawei high-end phones, the camera assembly of the P40 series has been developed in cooperation with German camera makers Leica. The P40 offers a triple-camera setup with ultra-wide and conventional 3x tele cameras.

The P40 Pro camera cluster

The P40 Pro features the same main camera with 50MP Quad-Bayer sensor, OIS and fast F1.9 aperture lens, but adds a more powerful ultra-wide with a 1/1.54″ 40MP sensor and a periscope style tele-camera that offers 5x optical magnification and, in combination with super-resolution algorithms, a maximum zoom factor of 50. A time-of-flight (ToF) sensor for depth-sensing in bokeh mode and improved autofocus performance is on board as well.

10x optical zoom on the P40 Pro+

The P40 Pro+ tops the Pro version by replacing the 5x tele with not one but two tele lenses: similar to the Xiaomi Mi 10 Pro a 3x conventional tele is used for closer distances. If you want to zoom in further a 10x optical periscope-style variant that supports up to 100x digital zoom takes over. The 10x lens reflects light five times to achieve its long focal length. AI algorithms use data from the ultra-wide camera and zoom lenses to optimize still image and video stabilization.

The main camera sensor in all three models is Huawei’s largest smartphone image sensor to date and uses pixel binning for increased dynamic range and low light performance. The new Octa PD AutoFocus offers focus capability on all pixels and the HUAWEI XD Fusion Engine is combining image data form all sensors to smoothen zoom operation and achieve optimized image quality at intermediate zoom settings.

Color temperature sensor

In addition the camera features a new multi-spectrum color temperature sensor and AI-powered white balance algorithms which, according to Huawei, improve color accuracy by 45 percent. AI methods are also deployed to optimize portrait skin tones and textures.

New camera software features include a function that chooses the frames from a Moving Picture and AI Remove Passersby and AI Remove Reflection which can eliminate unwanted subjects and glare in your images respectively.

Ultra-wide video with real-time bokeh

Bu default the P40 Pro and P40 Pro+ use their ultra-wide cameras for video shooting. The 18mm focal length should be ideal for cinematic shots and the large 1/1.54-inch sensor offers a 3:2 aspect ratio. Fusion Technology supports 16-in-1 pixel binning in video mode which enables shooting at up to ISO51200 with a wide dynamic range and 7680fps ultra slow-motion video capture.

Video mode also supports real-time bokeh effects and zooming using the tele camera. In addition, the camera is capable of producing 4K timelapses and directional audio zoom lets you focus the microphones on a specific subject in a scene.

Plenty of power and apps from Huawei’s AppGallery

All new models are powered by Huawei’s latest top-end chipset Kirin 990 5G which features 5G band support and 160MHz Wi-Fi 6 Plus technology with 2,400Mbps peak theoretical transmission speed. The Pro+ also comes with 40W wireless charging.

Like last year’s Mate 30 series, the P40 models do not come with Google apps, such as Gmail, Maps or the Play Store. Instead, apps can be downloaded from Huawei’s own AppGallery. The company says the gallery is working with global developers to expand the app selection on offer but for now, many users will see the lack of Google app as a major drawback.

Premium design and 90Hz OLED display

All the high-end tech is wrapped up in glass-covered bodies on the P40 and P40 Pro. The Pro+ comes with a nano-tech ceramic back panel for an even more premium look and feel. The Pro and Pro+ models also come with a curved edge 90Hz FullHD+ OLED display that features extremely thin bezels and an in-screen fingerprint reader.

P40 colors

Pricing and availability:

Owning a P40 series model won’t come at a bargain price. The basic P40 with 6GM RAM and 128GB of built-in memory will set you back 799 Euros (approximately $ 880). The P40 Pro with 8GB of RAM and 256GB built-in storage is 999 Euros (approximately $ 1100) and the top-end P40 Pro+ with 8GB/256GB is a hefty 1399 Euros (approximately $ 1540). Bigger-storage variants are available for each model but Huawei has not released pricing information for those yet. Currently, no further information on geographical availability has been provided either.

Press Release:

HUAWEI P40 Series Marks the Age of Visionary Photography

Housing Huawei’s largest CMOS sensor yet, the HUAWEI P40 Series delivers all-day Super Definition photography with powerful cameras, high performance 5G and cutting-edge design

26 March 2020 – Huawei Consumer Business Group (BG) today announced the HUAWEI P40 Pro+, HUAWEI P40 Pro and HUAWEI P40, the new HUAWEI P40 Series flagship smartphones featuring cutting-edge designs with ground-breaking camera innovations that radically expand mobile photography and video capture possibilities.

The HUAWEI P40 Series continues the series’ heritage of imaging excellence. The large 1/1.28-inch sensor has a binned pixel size measuring 2.44?m to massively boost light intake for enhanced low-light performance, while a new periscope design realises 10x true optical zoom. The HUAWEI P40 Series is powered by Kirin 990 5G and supports high-speed 5G and Wi-Fi 6 Plus. The advanced hardware is embedded in a beautiful and compact enclosure featuring the HUAWEI Quad-curve Overflow Display that delivers outstanding fluidity and responsiveness.

Richard Yu, CEO of Huawei Consumer BG, “The HUAWEI P Series has always been about innovative aesthetics and making premium imaging hardware accessible, representing the very best of industrial design and technology. With an outstanding sensor, camera systems that we co-engineered with Leica, powerful chipset and HUAWEI XD Fusion Engine, the HUAWEI P40 Series exemplifies our focus and offers an all-day Super Definition experience to help consumers realise their creative vision.”

Unprecedented design

The HUAWEI P40 Pro and HUAWEI P40 Pro+ are equipped with the HUAWEI Quad-curve Overflow Display. Inspired by the art of motion, the display takes on a curved edge on all four sides, creating a shape that is reminiscent of water on the cusp of overflowing from the rim of a filled cup. The super narrow bezels and streamlined round corners ensure an ergonomic hold and a near borderless look, while an enhanced in-screen fingerprint reader offers 30 percent faster biometric authentication.

Available in three glossy glass finishes – Ice White, Deep Sea Blue and Black – and two innovative refractive matte glass finishes – Blush Gold and Silver Frost, the HUAWEI P40 Pro and HUAWEI P40 exude classical elegance from every angle. HUAWEI P40 Pro+ features an exquisite nano-tech ceramic back panel that is kilned and polished to ensure it stands the test of time with incredible durability and timeless style. This unique design comes in two iconic colours: Ceramic White and Ceramic Black.

All-day Super Definition photography

Embedded in the HUAWEI P40 Series is the advanced Ultra Vision Leica camera system, available in triple-camera, quad-camera and penta-camera configurations. The HUAWEI P40 delivers outstanding photographic results with ultra wide-angle, wide-angle and telephoto lenses. The HUAWEI P40 Pro features an evolution of the Leica Quad Camera with a more powerful Ultra Wide Cine Camera and ToF Camera alongside 50x SuperSensing Zoom. The HUAWEI P40 Pro+ lets consumers see the unprecedented with the SuperZoom Array, which supports 10x true optical zoom and 100x maximum digital zoom.

The HUAWEI Ultra Vision Sensor included in the full HUAWEI P40 Series is Huawei’s largest CMOS sensor to date. Measuring 1/1.28 inches diagonally, it supports pixel binning to achieve a pixel size of 2.44?m and Full Pixel Octa PD AutoFocus for high-speed focus at any time of day, while the HUAWEI XD Fusion Engine integrates and processes data from multiple cameras to generate a comprehensive improvement in picture quality.

HUAWEI P40 Pro brings faraway subjects up close with 5x optical zoom, 10x hybrid zoom and 50x maximum digital zoom. For the first time ever, the 5x Optical Telephoto Camera in the HUAWEI P40 Pro includes a RYYB colour filter array to boost light intake and improve quality of zoomed shots. HUAWEI P40 Pro+ has a 100x SuperZoom Array with a new periscope design that reflects light five times, extending the light path by 178 percent to support 10x true optical zoom. The optically stabilised Ultra Vision Wide Camera and SuperZoom Array work in tandem with AI to realise Triple OIS+AIS for vastly improved photo and video stabilisation.

Skin tone and texture are faithfully reproduced by a new Multi-spectrum Colour Temperature Sensor and AI AWB algorithm that boost colour accuracy by 45 percent. Deep learning algorithms provide real-time portrait optimisations that enhance lighting and detail. HUAWEI P40 Pro and HUAWEI P40 Pro+ have a 32MP AF Camera and IR Depth Camera that support autofocus and Bokeh reproduction to deliver the same outstanding portrait effects that are signature to Huawei devices, as well as IR Face Unlock for device unlock even in low light conditions. HUAWEI P40 Series also introduces HUAWEI Golden Snap, which includes AI Best Moment, a new smart photography feature that chooses the best frames from a Moving Picture. AI Remove Passersby and AI Remove Reflection can do away with unwanted subjects and glare from the frame, allowing users to easily enhance their images after the fact.

A powerful pocket-sized video camera

The 40MP Ultra Wide Cine Camera in HUAWEI P40 Pro and HUAWEI P40 Pro+ has a focal length that is equivalent to 18mm and a 1/1.54-inch sensor supporting the 3:2 aspect ratio. SedecimPixel Fusion Technology is built into this camera to support 16-in-1 pixel binning, producing super pixels that measure 4.48?m to boost light sensitivity up to ISO51200 and enable 7680fps Ultra Slow-Motion video capture.

HUAWEI P40 Series supports real-time Bokeh effects for videos. Similar to the results of a wide aperture lens, this feature adds progressive Bokeh to help highlight the main subject of the footage. The telephoto camera can capture high quality zoom footage as well as 4K time-lapse videos. Directional Audio Zoom, available on HUAWEI P40 Pro and HUAWEI P40 Pro+, allows users to zoom in on an audio source and amplify its sound at the same time.

An all-connected 5G powerhouse

The HUAWEI P40 Series is powered by Kirin 990 5G to deliver integrated 5G connectivity with the most comprehensive 5G band support, robust AI performance and power efficiency. Display responsiveness and gaming experience are taken to the next level by the upgraded graphics rendering engine making the most of the 90Hz panel on the HUAWEI P40 Pro and HUAWEI P40 Pro+. The 160MHz Wi-Fi 6 Plus technology featured in the full line-up offers high-speed connectivity with support for 2,400Mbps peak theoretical transmission speed. The industry-leading 40W Wireless HUAWEI SuperCharge is available on the HUAWEI P40 Pro+ for fast and convenient charging. The chipset is given the thermal headroom to deliver exceptional performance by the advanced cooling systems, including the bespoke 4-in-1 SuperCool system in the HUAWEI P40 Pro+.

The EMUI 10.1 operating system introduces a host of new features that enable a richer, more seamless AI life. HUAWEI MeeTime[1] supports 1080p Full HD video call on Huawei smartphones, tablets and the HUAWEI Vision TV and delivers clear picture quality even in low light or weak signal conditions. Users can also share their phone screen with the other party during the video call and mark-up notes to quickly share thoughts.

Huawei Share facilitates high-speed file transfer between the smartphone and other devices such as tablets and PCs. With Huawei Share on the HUAWEI P40 Series, consumers can stream music to a smart speaker, initiate screen projection and connect to Wi-Fi by tapping the device[2] they want to connect to with their phone. New functionality added to the Multi-screen Collaboration allows users to easily answer video or voice calls hands-free directly through the PC, and open files and hyperlinks on the smartphone with native PC applications for enhanced productivity.

Working in close collaboration with global developers, Huawei offers a wide range of global and local apps on AppGallery, Huawei’s official app marketplace. Users can also enjoy a rich library of quality entertainment media on HUAWEI Video, HUAWEI Music and HUAWEI Reader, with new additions from top content providers being added on a continuous basis.

Articles: Digital Photography Review (dpreview.com)

 
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Yuneec launches E30Z 30x optical zoom camera for H520 Hexacopter drone

04 Feb

Drone company Yuneec has launched its new E30Z 30x optical zoom camera for the H520 Hexacopter drone. The camera features a 2.13MP 1/2.8in CMOS sensor capable of capturing 1920 x 1080 video at up to 60fps, as well as JPEG still images. The model features 1/30 – 1/6000s shutter speeds, 100 – 6400 ISO, 30x optical zoom, 6x digital zoom, pan/tilt support and both auto and manual white balance controls.

According to Yuneec, users can fully zoom the E30Z camera in 2.55 seconds. Drone operators get access to the camera’s various settings directly through the ST16S controller’s touch display. As the images show, the E30Z camera features a built-in 3-axis gimbal with 360° rotation support and accuracy of ± 0.02°.

The E30Z is one of the multiple camera models that can be used with the H520 Hexacopter drone, which Yuneec says it built for professionals and industrial purposes. The drone features six rotors that the company says are able to keep the drone stable even in high-wind environments.

The E30Z 30x optical zoom drone camera isn’t yet listed in the Yuneec online store; its price and availability remain unclear. The H20 Hexacopter, meanwhile, is available from Yuneec now in multiple bundle options starting at $ 3,999.99.

Via: Newsshooter

Articles: Digital Photography Review (dpreview.com)

 
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The world’s largest optical lens has been delivered for a $168M, 3.2-gigapixel telescope camera

01 Oct
Farrin Abbott/SLAC National Accelerator Laboratory

The SLAC National Accelerator Laboratory in California, the lab overseeing the design and fabrication of a 3.2-gigapixel digital camera for the Large Synoptic Survey Telescope (LSST), has successfully received the shipment of what may be the world’s largest high-performance optical lens. The announcement was made earlier this month by the Lawrence Livermore National Laboratory (LLNL), where researchers designed the optical assemblies for the LSST.

At this point in time, the 3.2-gigapixel digital camera intended for the LSST is 90% complete, according to LLNL. SLAC has been tapped to manage the subcomponent integration and final assembly of the $ 168 million camera, which is currently estimated for completion in early 2021.

Image credit: Farrin Abbott/SLAC National Accelerator Laboratory

Ball Aerospace in Colorado and Arizona Optical Systems built the lens assembly for the telescope, including the massive 1.57m (5.1ft) diameter L-1 optical lens and the smaller 1.2 (3.9ft) L-2 lens. According to LLNL, the L-1 is likely the largest high-performance optical lens ever created. It took around 17 hours to deliver the two lenses by truck to the SLAC in Menlo Park. Below are a few images of the delivery from the full Flickr album posted by SLAC:

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Livermore physicist Scot Olivier largely credited LLNL optical scientists Lynn Seppala and Brian Bauman, as well as LLNL engineers Vincent Riot, Scott Winters, and Justin Wolfe, for making the massive optical lens a reality. Once fully completed, the LSST will be used to capture digital images of the entire visible portion of the southern sky, according to Livermore, offering what experts anticipate will be ‘unprecedented details of the universe.’


Image credits: Farrin Abbott/SLAC National Accelerator Laboratory, used with permission

Articles: Digital Photography Review (dpreview.com)

 
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CP+ 2019: Sigma interview – ‘Optical design is always a battle with the design constraints’

07 Apr
Sigma CEO Kazuto Yamaki, pictured at the CP+ show in Yokohama, Japan.

Last month at the CP+ show in Yokohama we spoke to executives from several major manufacturers, including Sigma. In our conversation with CEO Kazuto Yamaki we discussed his plans for future L-mount lenses (and cameras) and some of the challenges of supporting multiple mounts.


It’s been six months since the L-mount alliance was announced. How’s it going?

At CP+ our main theme is to show our commitment to the L-mount system. We didn’t bring [out] any totally, brand-new products at CP+ but we showed our commitment to L-mount system by showing our new mount adapter and prime lenses for the system.

The response is better than I thought, initially. Not only from retailers and distributors, but also users who have showed very strong interest in L-mount system. Potential customers are very positive, which is more than I expected: it’s a nice surprise.

You expected it to be harder to convince people?

Yes, because it’s a relatively new system. It’s not a brand-new system, because Leica already had their own system, but as an alliance, this is only the beginning. Panasonic just announced a few products, so compared to the existing systems, particularly compared to Sony system, it’s not [comprehensive]. I was pretty surprised customers showed interest in our system.

The Sigma 35mm F1.4 Art for L-mount is a new lens, but the optical design was laid down at the launch of the Global Vision lens series, in 2012.

Do you have plans to design native L-mount lenses?

We will probably release a few lenses this year, designed for the short flange-back distance.

What are the most important lenses the L system will need in order to be a success?

First of all we need to have more and more lenses. Variety is key. Regardless of whether it’s standard zoom lens, telephoto lens or primes, we need to have more lenses because professional photographers and enthusiasts want to try many lenses. [They don’t] have to be standard or unique, the first priority is to have more. That’s why we announced eleven lenses at CP+, all of which will be available this year.

It might also be a good idea to have unique lenses that only L-mount users can enjoy: we’ll need to think about this.

L-mount lenses from Panasonic and Leica are all fairly expensive, compared to typical Sigma pricing – should we expect your L-mount lenses to be more affordable?

We believe our mission is to provide high quality products with affordable prices. Although I have said we can’t be the cheapest product supplier, we do our best to provide the highest quality product with an affordable price.

Actually the production cost is very high but we minimize the organization, we maintain a very lean organization: we have very few employees in marketing, sales, administration or HR so we can provide products at an affordable price. Our goal isn’t to increase the price more than necessary.

DFD information part of the L-mount standard: will you be writing this information into your L-mount lenses?

I just can’t comment. It’s great technology but I’m not sure we can implement it in our camera because it requires a lot of processing power. We respect the technology but we cannot comment [on] whether we’ll implement in our cameras.

Ahead of the development of brand new lenses designed from the ground up for mirrorless, Sigma has created two MC-21 adapters to convert its Sigma SA and Canon EF lenses to the L-mount.

What about your lenses?

Yes, that’s why Panasonic, Sigma and Leica engineers [are working] together to enhance the L-mount system. We keep upgrading the L-mount system for much more communication between the lens and body to support technologies like DFD.

Sigma arguably started the trend of big, heavy, very sharp primes but now everybody is doing it. Can Sigma create a new segment?

I must admit our position in the industry: people [regard us as] a third-party or accessory provider. Many customers may wish to choose their original manufacturers’ lenses. So, as a lens manufacturer, differentiation is important for us. We always try to bring a unique lens that the body manufacturer doesn’t have.

A long time ago we produced similar lenses with much, much cheaper prices. But today we produce everything in Japan, including parts, so we can’t be the cheapest product supplier. The only way to survive in the industry is to produce unique products. I think big, heavy but super performance was one of the strategies to differentiate ourselves. But today many companies have similar products so perhaps we need to find another [strategy].

The Art series is our heart and we have many users all over the world, so we’ll maintain this lineup

Of course the Art series is our heart and we have many users all over the world, so we’ll maintain this lineup. In order to differentiate ourselves we’ll need to create new ideas for lenses and we’re currently working on it.

I can’t tell you [more] now. Maybe after several glasses of sake!

Is there room in the range for smaller, maybe F2 primes?

The advantage of mirrorless cameras is the small factor. I’m aware some users want very lightweight, small camera bodies and small lenses. They might want to use the big, heavy lenses for some occasions, but for casual shooting, like street photography, they might wish for smaller lenses. I can’t comment but maybe in the future we may be able to deliver such products.

With so many new camera systems on the market now, how do you prioritize which mounts you develop lenses for?

I have a great interest in the Canon R and Nikon Z systems because eventually they will have more and more customers. So we are now investigating these systems. But still it’s too early to make a statement about how we will respond.

Right now we see many new Canon R and Nikon Z users using mount adapters with their existing lenses. So we’re concentrating on optimizing the compatibility of our lenses with their mount adapters and cameras.

We’ve already made sure that our lenses work almost perfectly, without any problem, but we’re looking in detail: maybe there are some minor issues with this specific setting, or with that specific procedure, and so on, so you may still see some minor issues. Our software engineers are now de-bugging those kind of things. But, at the same time, we are looking into how to support the new systems.

Nikon’s wide, shallow mount provides some advantages for optical engineers, but according to Mr Yamaki it’s easier for a third-party manufacturer to design solutions for narrower standards first, and adapt them outwards.

How difficult is it to create one lens design which has to work for several different mirrorless mounts, with their different dimensions?

We have the same challenge in the case of DSLR. The Canon EF mount has larger diameter than Nikon F mount [for example]. We sometimes thought if we only made lenses for Canon EF mount it could be easier but we always overcame such challenges. So we have the experience.

Flange-back distance should not make much difference but [mount] diameter may make some difference. This is a challenge we need to overcome.

It’s true if you need to make a very fast, very high optical performance lens, the Nikon Z mount is very nice. Personally [I believe the short flange-back distance places the rear optical group] a bit too close to the sensor, I’m a bit concerned about reflection problems: it may create some strange ghosting. But its shorter flange-back and bigger diameter gives more options to an optical designer, in theory.

Are the mounts similar enough that you can use one optical design?

If we are to make lenses that are usable for all mounts, we’ll probably optimize to the longest mount. Such a lens could still be used for Nikon Z mount [which has the shortest flange-back distance]. If we optimize to the Nikon system, we can’t use that [lens design] on a [a mount with a longer flange-back].

There is some difference between the mounts but it doesn’t make a huge difference in designing the lens. Of course there are some challenges, maybe if we make exactly the same spec (same aperture and optical performance), a Nikon [Z mount lens] may be 2-3mm shorter but I don’t think it makes a huge difference.

Technically the larger mount diameter give more options to the optical designer

But the mount diameter does make some [amount] of difference when you’re designing. Optical design is always a battle with the design constraints: if the mount diameter is very wide, our optical engineers can use very big diameter lenses in the rear lens group, which makes the design easier. Technically the large diameter give more options to the optical designer but it doesn’t mean we can always design high optical performance lenses. That’s our technique: our technology tries to overcome such limits to provide the best performing lens.

Sigma has been making lenses for radically different mounts for decades, including some weird and wonderful products like this XQ 24mm F2.8 Filtermatic, with built-in filters for black and white film.

Via Wikimedia Commons, credit: Maksim Sidorov

Even in the film era, Sigma supported very different mounts – has anything really changed?

When designing a lens, we try to minimize aberrations, make [the lens] as sharp as possible and try to create nice bokeh in the background: such basics are the same. Mirrorless systems have pros and cons. The pros are that we can make wide-angle lenses much more easily than for DSLRs, just because of the short flange-back distance. But the challenge is the focusing system: if we need to support contrast detection AF or autofocus during movie capture [for example], it’s challenging.

It’s harder to support CDAF?

Yes, if we are to achieve the best optical quality. From an optical point of view it would be ideal to move the whole lens forwards or back to focus. When we had manual focus there were some designs where we moved the whole lenses to focus. But when we started building autofocus lenses we needed to make the focusing lens lighter and smaller so that the motor can support the focusing lens. But the basic physics is the same: the bigger and heavier the focusing lens, the easier it is to maintain optical performance in a shorter focusing distance.

We publish MTF charts but this is the performance at infinity. We optimize at infinity, but naturally the performance degrades at closer distances. If we use a smaller diameter, lighter focusing lens, it tends to degrade more at closer focus distances. That’s the challenge.

There is no ideal world for optical design

In order to support contrast AF we need to implement ‘wobbling’: we need to move the focusing lens back and forth to detect the subject. In order to do that, we need to make the focus lens very light and small and this tends to degrade the performance in the short focal distance.

That’s not always the case, though. Canon doesn’t use that system: they use dual pixel and it works like phase detection, but other manufacturers use pure contrast AF or hybrid AF so the lens has to support that kind of AF operation. Nikon is hybrid, Sony is hybrid. We will probably [implement a hybrid AF system too]. There is no ideal world for optical design, the engineer always has to fight against such limitations.

Does a lens design optimized for CDAF give better performance on cameras that use PDAF?

In terms of speed, yes. If we talk only in terms of focus performance and accuracy then yes, it’s better but the downside is optical performance, in theory. We have many other technologies to maintain optical performance and other companies try to solve the problem with such technologies but in theory it’s challenging.

Sigma’s 50mm f1.4 Art is not a new product, but its lovely rendering of out of focus areas and relative lack of longitudinal CA make it a beautiful lens for portraiture, even now.

When designing lenses, how do you balance things like sharpness with less quantifiable qualities like bokeh?

I think the [main goal] is to make the best possible optical performance for almost all lenses. So we like to minimize the aberrations, the coma, to provide the best quality from the center to edge.

You mention the ‘beauty’ of the image and that’s quite subjective, so it’s not easy to understand the real demand from users. But we [at Sigma] are also photographers, so we do understand these needs. So we may try such a target with some specific lens, so that we [can gauge] response from the customers.

We don’t have a specific plan, but we could have such a product in the future.

Today [our] design software can simulate bokeh: we always check whether the bokeh is ok or not, it’s very important. It’s a subjective matter but still we know what is good bokeh and bad bokeh so we always pay attention to that.

Is the existence of so many new lens mounts a challenge or an opportunity for Sigma?

It’s both. The more mounts, [the] more opportunity: the most active companies will survive in this very chaotic market. But we need to work very hard.

I personally regard this as an opportunity. If we stay only on the very conventional, old systems, we cannot stimulate the market. But on the other hand, this is a very, very big challenge for manufacturing, for our factory. Especially because we make everything ourselves, we make most of the parts and components. So if we make a much wider lineup, it [could] easily confuse our production system.

If we relied on many suppliers we could respond to demand by just changing the size of our order

If we relied on many, many suppliers we could respond to demand by just changing the size of our order, and buy from a different supplier: it’s easy to control. But we make everything by ourselves: we need to change a setting on the machine for each part, so every, let’s say, hour we change, it deteriorates our productivity and efficiency, and we very easily lose the profit margin from manufacturing. This is very challenging.

Will you need to change the way Sigma is organized?

Yes: I’ve been explaining this challenge to my staff for more than a year. The toughest time for [manufacturing] will come in maybe 2019, 2020, 2021 because we will maintain our current lineup for DSLR while also expanding to include more mirrorless [lenses]. So our product line will increase by 50%, maybe as much as twice. This will be very, very challenging for manufacturers like us.

Mr Yamaki, pictured here in Sigma’s factory in Aizu, Japan. Read more about the facility in our detailed tour, here [2015].

Will you need more factory space?

We do have plans to expand the factory. We will start construction of a new building in the same location for an assembly line to build the very modern, high performance lenses. We are putting more and more technology into the assembly line: checking performance and adjusting the lenses.

The assembly line is getting longer and longer so we need more space. We will start construction on two new buildings near the same location. But we’re doing this just to keep the pace with the modern technology, not to expand the production [volume].

Are you planning to create lenses for Fujifilm’s X-mount?

I have [had] many questions about it. I know that some [Fujifilm] customers are wishing for us to make lenses for them. It’s always a matter of priority. We know there are many good customers of the Fuji system and they’re perfectly matched with our ideal customer but [Fujifilm doesn’t] really disclose the protocol between the lens and camera, so we need to do the reverse engineering by ourselves.

It’s a really time-consuming process so we need to prioritize support for Sony E mount, our L-mount system, existing DSLR mounts and Micro Four Thirds.

So you’re balancing the cost of reverse engineering against the potential market size?

Yes, that’s true.

In other words, because you know that Nikon and Canon mounts will be popular, the cost of reverse-engineering can be justified?

Yes.

Sigma is working its next generation of cameras, which unlike the SD-series of old, will be built around the mirrorless L-mount and will feature full-frame Foveon sensors.

What is Sigma’s future as a camera manufacturer?

I have explained that our mission is to create unique lenses, a unique product for the customer and eventually I hope the customers have more choices. They can choose ordinary products from camera manufacturers and unique product from lens manufacturers [like us].

Our future camera business will be even more extreme: I’d like to deliver even more unique cameras that the big players may not deliver to market. We like to be a unique camera manufacturer in the future.

Unique in what way?

Right now I can’t say: you will see at some point in the future.

Are you hoping to make the type of camera that some people might want but that companies the size of Canon and Sony wouldn’t target?

When we launched the first DP it was the first compact camera to feature a large sensor. We [were consequently in] a very unique position but it’s not unique anymore, so we will pursue another solution to make us unique.

What potential benefits should a customer expect to see from a full-frame Foveon sensor?

The basic technology is the same, there is no complete silicon change. People can expect better image quality simply because of the sensor size: APS-C and Full Frame are quite different, so people can expect better performance.

I gave a presentation [to a Japanese audience at CP+] and we announced the basic spec of the [full-frame] sensor [currently being developed]. It’s 20 megapixels times three, so about 60MP. They’re not tiny pixels: they’re relatively big pixels so each pixel can capture enough light. And we’ve gone back to the original pixel structure: 1:1:1, so people can expect very nice, rich data from the sensor.

I hope they like it, but the Japanese audience [at the presentation] has a poker face: they don’t show their feelings on their faces, so I didn’t see a clear response, but I hope they’ll like it [laughs].

What improvements are you mainly targeting?

We tried to improve all aspects [readout speed, color separation, noise performance]. With this sensor we tried to improve the high ISO performance but color separation is the same: we maintained the same characteristics as before. It’s challenging: if we keep the same characteristics it’s challenging for the high ISO performance but it means we can reproduce better color gradation between blue, green and red.

Color specta derived from Raw images, with Foveon (top) showing much smoother red-to-green transitions and greater ability to capture violet tones that exist beyond the blue filter that the three Bayer cameras can capture.

This image [demonstrated by Mr Yamaki in the interview and reproduced above – the upper strip is from a Foveon sensor, the lower three are from three different Bayer-pattern sensors] is taken by a Foveon sensor. Foveon can capture greater graduation between each color. This is from a Raw file but if the Raw data has the correct response to each wavelength then we can render all these colors in processing.

One of the projects we have at the moment is to recreate this nice color graduation in the final image. You can’t create this graduation from nothing so while we retain the same color separation, we’re trying to improve the processing.

What’s the response been like to adding DNG capability?

When we announced DNG output, [our customers] were very excited but after they tried it they were a bit disappointed by the quality because the pre-processing was a little bit different. So most of the customers that I know prefer SPP, despite the [penalty in] processing speed.

Are you working on enhancing the DNG performance?

We’re always trying to improve the processing in the camera. Our Sigma Photo Pro software can do some pre-processing that DNG cannot, so we need to do that pre-processing in the camera and write it into the DNG file. The power of the in-camera processing is limited: when it comes to PCs, the processing power available is much [greater]. But we always try to improve the pre-processing in the camera.

What are the other products in the market you’ve been impressed by?

So far I like Canon, the 28-70mm F2 and the 50 mm F1.2. Their [RF] mount system is quite impressive.

But it’s noticeable that they both use slower, ring-type focus motors -presumably Canon has had to make that same image quality / speed decision…

This is the same challenge for all manufacturers.


Editor’s note: Barnaby Britton

The last time we spoke to Mr Yamaki was late 2018, at Photokina, where he had just announced the L-mount alliance with Panasonic and Leica. In the intervening six months it sounds like his team of engineers has been pretty busy developing a ‘unique’ Foveon-equipped full-frame L-mount camera, as well as ensuring a wide range of native L-mount lenses by the time it is launched (which we expect to happen later this year).

Of course the 11 L-mount lenses that Sigma has launched so far this year are only ‘new’ in the sense that they’re newly machined for L-mount: optically these are the same designs that we’ve seen before, going back to the launch of the Global Vision range in 2012. This fits with Mr Yamaki’s initial L-mount strategy of ‘more and more lenses’, with perhaps some unique optics coming a little later.

Reassuringly, despite the eye-watering cost of most L-mount lenses currently on the market from Panasonic and Leica, Mr Yamaki seems set on his long-standing strategy of quality at ‘an affordable price’. One of the ways of keeping prices down, of course, is to standardize optical designs across lenses made for different mounts. This is not a new challenge for Sigma – Canon EF and Nikon F mounts are radically different, for example, and the company has been offering versions of the same lenses for both, for more than 30 years.

When faced with the challenge of standardizing optical designs, it makes more sense to design for the most limiting mount first, and work outwards

In this interview Mr Yamaki confirmed a couple of things that we’ve long suspected: firstly that, in theory, systems with a wide mount and short flange-back give the optical designer more options, especially when it comes to creating certain kinds of lenses. And secondly, when faced with the challenge of standardizing optical designs for radically different lens-mounts, it makes more sense to design for the most limiting mount first, and work outwards from there. As Mr Yamaki says, ‘if we optimize to the Nikon system, we can’t use that [lens design] on a [a mount with a longer flange-back]’. But if he starts by looking at – say – creating a lens for Sony E-mount, adapting it to a wider mount should be relatively straightforward from an engineering perspective.

Of course, for that to happen, Sigma must first reverse-engineer the Z-mount. Nikon – like Canon, and Fujifilm – does not disclose details of its mount standard to third-parties. According to Mr Yamaki, the cost of the R&D required is easy to justify for major mounts, where sales are guaranteed. The flip-side, of course, is that for systems with a relatively small market share, and / or a large range of attractive native options already in existence – like Fujifilm X – it’s a trickier proposition.

Another complicating factor is the mixture of different autofocus technologies currently used by camera manufacturers. Some use pure contrast-detection, some on-sensor phase-detection, and some a combination of both. Mr Yamaki’s description of the optical and functional limitations imposed by the need for CDAF support is fascinating, and rather than unpack it again here, I refer you to his concise explanation, above.

Articles: Digital Photography Review (dpreview.com)

 
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Huawei P30 Pro features super-wide-angle, 5x optical zoom and ISO 409,600

27 Mar

One year after launching the P20, Huawei has announced its new P-series high-end smartphone models: the P30 and P30 Pro. As usual, the Chinese manufacturer is at the forefront of smartphone camera development and the P30 Pro in particular has some real innovation to offer in the camera department.

The top-of-the-line device comes with a triple-camera setup (Huawei calls it a quad-camera, counting the time-of-flight (ToF) sensor), covering a focal length range that has previously been unheard of on a smartphone. The primary camera features a 1/1.7 40MP quad sensor that puts out 10MP images. The optically stabilized lens comes with an 27mm-equivalent focal length and F1.6 aperture. If you want to go wider there is also a 20MP 16mm-equivalent super-wide-angle option but the P30 Pro’s real highlight is the stabilized 5x (125mm-equivalent) periscope-style tele-camera with folded optics.

Huawei P30 Pro

The concept is very similar to OPPO’s prototype zoom system and allows for a much longer reach than would be possible with a conventional lens in a thin smartphone body. In addition Huawei also uses clever software algorithms to further enhance the P30 Pro’s zoom performance. In combination with a super resolution algorithm which merges several RAW frames into one high-resolution image that is then cropped to produce a zoomed image, a maximum zoom factor of 50x can be reached.

During the presentation Huawei CEO Richard Yu also put a lot of emphasis on the the camera´s low light capability, claiming a maximum ISO of 409,600 and the capability to capture well-exposed images in near darkness (1 Lux). This is made possible through the use of an RYYB sensor in the primary camera. According to Huawei the chip is 40 percent more light sensitive than a conventional RGB sensor. Combined with OIS and a fast F1.6 aperture the new Huawei should be one of the best performing smartphone cameras in low light we have seen.

There is also an improved portrait mode that creates a background-blurring bokeh effect. A first depth-map is created using data from the super-wide and primary cameras. It is then refined with the help of the ToF-laser that can precisely measure subject distance in all ligh conditions. Other imaging innovations include adaptive frame rates in video mode – the camera shoots at 60fps in bright light and with camera motion and reduces to 30fps in lower light or when the camera is held still – and HDR video recording on the front camera.

Other key specs include a Kirin 980 chipset, 8GB RAM, a 6.47-inch display with minimal bezels and FHD+ resolution as well as a 4,200mAh battery with fast charging. The Huawei P30 Pro is available from today but unfortunately isn’t quite a bargain. Pricing ranges from 999 ($ 1130) Euros for the 128GB version. You’ll have to invest 1249 Euros ($ 1410) for the 512GB top-of-the-range model.

Huawei P30 Pro key camera specifications:

  • Triple-camera setup
  • Primary: 40MP, 1/1.7-inch quad sensor; F1.6 aperture, OIS, 27mm-equivalent
  • Tele: 8MP sensor, folded optics with F3.4 aperture, OIS, 125mm-equivalent
  • Super-wide: 20MP, F2.2 aperture, 16mm-equivalent
  • PDAF/Time-of-flight (ToF) autofocus
  • LED flash
  • 32MP front camera, 26mm equivalent, F2 aperture, HDR video
Huawei P30

The P30 is the Pro version’s mode affordable cousin. In the camera department it lacks the 5x optical zoom and comes with a similar camera setup to last year’s Mate 20 Pro. The primary camera uses the same sensor as the Pro but has to make do without an OIS system. The super-wide comes with a lower 16MP resolution and the conventional tele ‘only’ offers an 80mm equivalent focal length.

Other differences include a smaller 6.1-inch OLED display and a lower capacity 3650 mAh battery. The Huawei P30 comes with 6>GB of RAM and 128GB of storage and will set you back 799 Euros ($ 900).

Huawei P30 key camera specifications:

  • Triple-camera setup
  • Primary: 40MP, 1/1.7-inch quad sensor; F1.8 aperture, 27mm-equivalent
  • Tele: 8MP sensor, F2.4 aperture, OIS, 80mm-equivalent
  • Super-wide: 16MP sensor, F2.2-aperture, 16mm-equivalent
  • PDAF/Time-of-flight (ToF) autofocus
  • LED flash

Articles: Digital Photography Review (dpreview.com)

 
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Optical Versus Electronic Viewfinders: Which is Best for You?

14 May

In this article, we’ll take a look at optical versus electronic viewfinders so you can get a better understanding of the differences and strengths and weaknesses of each.

Coke versus Pepsi, Star Wars versus Star Trek, football versus futbol. The world is full of great rivalries, and photography is no exception. Aside from simple brand loyalty and lens preference, there are dozens, perhaps hundreds, of other tools, features, and options that photographers to argue about. One of the most recent but most pronounced has to do with how you see the world in front of your lens.

Some cameras have optical viewfinders while others sport more technologically advanced versions called electronic viewfinders. Other cameras even have hybrid options that attempt to combine the best of both worlds. So which is better? Just like most rivalries, that question is impossible to answer, but it is worth exploring some of their individual strengths and weaknesses to help you know which one might be right for you.

Optical Versus Electronic Viewfinders - low angle sunset shot

Seeing the scene

A viewfinder is one of the most basic elements of any camera; it’s what you use to look at what you will be photographing. When you hold your camera up to your eye, whether you’re shooting DSLR or mirrorless, the tiny little hole you look through is what’s known as the viewfinder. This is what you use to compose your shots.

Some cameras forego the viewfinder altogether and just have a giant LCD screen on the back, which is how all mobile phones work. But it’s not uncommon for many cameras to include a viewfinder along with the rear screen.

It’s not just a holdover from days gone by, and even in today’s fast-paced tech-centric world, there is a myriad of reasons why many photographers prefer to compose their shots with the viewfinder instead of the rear LCD screen.

  • The scene appears much larger when held up to your eye which gives you a better sense of how your picture will look.
  • Holding your camera up to your face also has the rather practical benefit of making things more stabilized.
  • Viewfinders in DSLR (and more mirrorless) cameras often contain a row of numbers and indicators at the bottom showing you things like your aperture, shutter speed, metering mode, shots remaining, and more.
Optical Versus Electronic Viewfinders - inside the camera view

Optical viewfinders have a row of exposure and photo information at the bottom to help you as you shoot pictures.

Optical Viewfinders

Despite being decades-old technology, optical viewfinders still have many staunch supporters in photography today, with good reason. Their most important benefit, and the reason many photographers prefer them, is that they present an unfiltered and unaltered view of the scene in front of you as you are composing your shot.

Looking through an optical viewfinder, or OVF, is no different than looking through a window: nothing is changed in any way, shape, or form. This lets you see exactly what your shot will look like, and the view is not dependent on any type of fancy technology in order to function.

Optical viewfinders work even if your camera is turned off, in much the same way that looking through binoculars, a telescope, or even a paper towel roll does not require a battery. OVFs have no issue with accurate color rendition or screen refresh rates, and they work the same in bright light as they do in low light.

Optical Versus Electronic Viewfinders - crowd watching a speech outdoors

Most optical viewfinders also have indicators to show things like focus points and framing guides. When you half-press the shutter button to focus your camera, a small dot or square will show up in your camera’s OVF to let you know where the point of focus will be, and you can use a dial or knob on your camera to change this if you prefer.

Limitations of OVFs

However, not everything is sunshine and roses in the land of optical viewfinders. They do have some significant limitations that could be a factor depending on the type of photographs you take.

One of the most important is that you can’t see your image when you take a picture – a phenomenon known as viewfinder blackout. When you press the shutter button the mirror in a DSLR camera flips up and out of the way to let light pass through to the image sensor, which means the OVF goes completely dark.

dog with a frisbee - Optical Versus Electronic Viewfinders

This is not very noticeable when using fast shutter speeds but if you are shooting at about 1/30th of second or slower you will see a big blank box of nothing for a brief moment whenever you take a picture. In most situations, this blackout period is not going to make or break the photograph but it can cause issues if you are shooting fast-moving subjects. In those cases, the short amount of time that the OVF is blank is enough for the object you are photographing to move around quite a bit and it can take some practice to get used to this type of shooting.

Disadvantage

Another disadvantage of optical viewfinders is that they show you the world around you as it really is, not as it will appear in your digital photograph. The OVF sees what your eyes see, which is not necessarily the same as what your camera’s image sensor sees.

Unless you have a solid grasp on metering modes and how they affect your exposure, you might end up with pictures that are too bright or too dark, especially if there is a great deal of light and shadow in the scene itself. Looking through the OVF you might think your pictures are going to be just fine only to realize later that they are under or overexposed. Unless you shoot in RAW there might not be much you can do about it.

flowers with shallow DoF - Optical Versus Electronic Viewfinders

Electronic Viewfinders

A few years ago, this discussion about optical versus electronic viewfinders would have been more of an academic exercise without a whole lot of practical value because EVFs simply couldn’t compete with their analog counterparts in practical terms. Their list of downsides was as long as a 70-200mm lens, and aside from a few key benefits, there wasn’t much reason to use an EVF compared to an OVF.

However as time marches on and technology gets better and better, electronic viewfinders have now just about reached parity with optical viewfinders. They are not just a viable option, but in some cases are a superior one for some photographers.

Main difference

The most obvious difference with electronic viewfinders is that just like looking at the LCD screen on the back of your camera, you see a digital representation of the world in front of your camera instead of the actual world that your eye sees. An EVF is a tiny high-resolution screen that you hold less than an inch from your eye. Because it is entirely digital, it can show you a wealth of information and data that you simply can’t get with an optical viewfinder.

bike panning shot - Optical Versus Electronic Viewfinders

Benefits and bonuses of EVFs

While optical viewfinders have static overlays with framing guides and focus points splayed across your field of view, electronic viewfinders can show all kinds of information that is highly useful when taking photographs. You can see things like a live histogram and digital level along with the usual collection of exposure and metering information. But the ace up the sleeve of any OVF is its ability to show you exactly what your photograph will look like, not what the world in front of the lens looks like.

Electronic viewfinders will let you see instantly, in real-time, whether your shot is exposed correctly. This allows you to quickly made adjustments not based on a light meter (though you certainly can) but on the final image and how you want it to appear.

Things OVF can’t provide

If you’re shooting in a black and white mode, then that’s precisely what you will see as you look through the EVF to compose your image. You will also see the depth of field reflected exactly as the final image will appear, and you can watch it change in real-time as you adjust your focus point or aperture.

To put it simply, EVFs remove much of the guesswork inherent in OVFs. In many cases, this makes the act of taking pictures much easier, especially for new photographers.

pink flowers - Optical Versus Electronic Viewfinders

Getting the exposure right on this shot was easier thanks to the electronic viewfinder in my Fuji X100F.

Due to their electronic nature, EVFs gives you options that an OVF is simply incapable of doing. Many cameras with EVFs allow you to check focus by enlarging a portion of your image so it fills the screen, and you can often get visual aids like focus peaking in the EVF as well. You can use an EVF to go through menus, review pictures, and even record and review movie footage you have captured with your camera–all things that are impossible with an OVF.

Drawbacks of EVFs

There are, as you might expect, some important downsides to EVFs not the least of which is power consumption. Optical viewfinders work without any batteries at all, whereas electronic viewfinders require constant power to operate. It’s not uncommon for cameras that rely on electronic viewfinders to have much shorter battery lives than their optical counterparts, and many photographers who use these cameras are in the habit of carrying spare batteries for a day of shooting.

Electronic viewfinders also suffer from screen refresh rate issues, which means that they can be difficult to use in situations with a lot of fast-moving action. Some EVFs have a great deal of lag which means the image you see is just slightly behind what is actually happening. While they have certainly gotten much better in recent years, they are still not quite on par with optical viewfinders in this regard (in my opinion).

Finally, even though electronic viewfinders show you a good representation of what your final image will look like they don’t quite have the same color range and resolution as what you will see in your photographs. Even the best EVFs top out at 3 megapixels with most hovering around 1-2, which means you’re looking at a much lower-resolution version of what you will see in your pictures.

low camera angle of a long passage way - Optical Versus Electronic Viewfinders

So which is better?

Like many aspects of photography, this issue isn’t about whether an optical versus electronic viewfinder is better, but which one will suit you and your needs as a photographer. Some people prefer the analog precision of an optical viewfinder, while others like the high-tech features offered by electronic viewfinders. At the end of the day, what really matters is that you have the right tool for the job. So if you tend to prefer one of these over the other then, by all means, go ahead and use it.

I would like to add one caveat to all this, which is if you have not used an EVF in a few years you might want to give it a try. The shortcomings of EVFs are rapidly being addressed by many camera manufacturers today, and EVFs from days gone by have been eclipsed many times over by their modern counterparts. It might be worth your time to go to your local camera store and check out one of the newer models with a built-in EVF and see what you think, just so you can make an informed decision when choosing your next camera.

Optical Versus Electronic Viewfinders - pink flower

What about you? Do you prefer optical or electronic viewfinders? Leave your thoughts below. I’d love to hear from the dPS community about all of this, and I’m sure other readers would like having your thoughts as a way of learning more about this whole issue.

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