I've always found Nikon to be lacking in competitive models with Canon in the places that count. Canon frequently make lenses of the same focal length but for different budgets, e.g. they have 4 70-200mm models. Nikon's range has always been weirdly spotty, with some excellent lenses at the high end but weird gaps elsewhere.

Tangentially, I recently bought a superb Sigma lens and was happy to see that it was actually still made in Japan as well; I thought all the third-party lens makers had moved abroad, but surprisingly a number of them are still there.

I was also very happy to discover that Canon promotes wildlife reserves around its factories and headquarters. It's nice to see a company that reflects some of its customers' interests: https://global.canon/en/environment/bird-branch/index.html

Modern lens are made with techniques perfected in semiconductor manufacturing, and use advances in material science (meta materials in particular). I don't know how close this is to mass market, but I've seen superthin flat lens, with a marginal cost of production around ~$2 in a university facility, that work better than some $500 lens -- and the latter are expensive because they are hard to make the traditional way.

Canon putting Fresnel elements in their lenses to reduce size/weight: https://kenrockwell.com/canon/lenses/400mm-f4-do-is-ii.htm

Canon making an f/11 800mm super telephoto lens that can still autofocus thanks to the new mirrorless camera bodies: https://www.kenrockwell.com/canon/eos-r/lenses/800mm.htm

I think we'll see a big pivot in the market (we're already seeing it, really) with the switch to mirrorless. What I'm hoping we'll see is a total rethink of what's possible in a lens; adapting this new technology to make new designs that exceed what was possible before, rather than just matching it. If they can bring costs down by making use of this new tech then I think it will re-open the market for "I want something that does more than a phone camera". At the moment lens prices are pretty bonkers but I think that Canon f/11 lens is a great indicator; it's basically less than 1/10th of the cost of a traditional 800mm lens and does more than enough for most people.

And yes, they are mostly better than previous generations across the board. Which is pretty cool, that something based on such a simple idea that’s been around hundreds of years still has room for major improvements.

Mirrorless in practice really just means the camera works more like your phone camera. You view the image on a screen instead of through an optical viewfinder. That brings some nice benefits, none of them are necessarily a game changer on their own but together it makes for a major step forward in the experience. Now the viewfinder shows you the picture more like it will actually look, the processor can see the image as you’re composing it before you take the shot and provide hints and show you that information overlayed on the image, the processor is involved in auto focusing and can do things like use ai models to focus on eyes, plus the physical benefits like there’s a big complex moving piece the camera no longer needs.

Camera makers then used this change to make a bigger platform shift at the same time. Just like a major version bump in software, if you have breaking changes you’ve been waiting to make you might want to make them all at once. They widened the mount diameter of lenses, which combined with the shorter distance to sensor because of the lack of a mirror gives more flexibility in letting in more light to the sensor. And they built a new set of lenses around it, whereas a lot of the lenses in their old lineups were sometimes decades old and not designed for the crazy high megapixel sensors we have now and in the near future. Most of these new lenses released in the past few years have been very high quality, so to answer your question that’s really where the improved image quality comes from, this new generation of lenses.

Sort of. The diameter of the front element is predetermined, a function of the sensor size, focal length, and aperture. Mirrorless cannot escape this.

But, the shorter distance from sensor to lens does simplify the design of a good wide angle. Sadly, wide angles were never the big heavy lenses in the first place.

The whole smaller & lighter thing is not a lie but pretty oversold. Some of the RF glass is actually bigger and heavier than the equivalent EF glass.

It's a trade-off, though. Seeing the actual image through the lens, and not a digital representation, which is what you get with a mirrorless system, has its benefits.

I never found those benefits. What would you say they are?

Early on, the problem was mirrorless were slow in autofocus, and they had relatively terrible EV quality. Now they have better autofocus than mirrorless, and more importantly, with the very high resolution EV displays they have now [1], what you see is exactly what you end up getting. You don't have to guess about anything anymore, like what's going to blow out, which is fantastic. What you see in an optical viewfinder with your eye is not what your sensor sees is going to portray. I don't see any benefit to optical viewfinders at this point.

[1] 5.7MP OLED EV!: https://www.bhphotovideo.com/c/product/1494679-REG/sony_ilce...

Which is fine for what it is! If you aren't shooting in a studio, the reduced mass of equivalent lenses with mirrorless systems is a big quality of life upgrade all on its own, for example. But the color representation just isn't there, and it isn't going to be until we get better color in our display systems. It's being worked on, of course, but there's a long way to go.

I don't understand this. The EV displays are calibrated. It's what you're going to get on your high end monitor when you get home. Eyes do not work like camera sensors, so I don't see how this is a plus. White balance being a great example.

> the true dynamic range,

How can your eye tell you this though? Unless your'e doing HDR/exposure stacking, dynamic range from the perspective of the sensor is all you're going to get. With the EV, you get clipping/black indicators, and even a histogram. I'm never wondering if I'm going to blow out the sky or crush some details in shadows anymore. I can see if I am, without having to snap then preview.

> the ability to see to edges of the focal plane with greater clarity.

I don't understand this at all. The new EVs give you 100% crop (with some slightly reduced zoom so it fits), with complete clarity edge to edge.

I would suggest giving a new high end EV another try.

1. The color space of the EV's display (and even the wide-gamut monitors available for desktop use) do no fully encompass the colors we can see. https://i2.wp.com/digital-photography-school.com/wp-content/... for a diagrammatic example of common colorspaces vs. what our eyes are capable of perceiving. In particular, the greens and purples are abbreviated, and I prefer composing with the true colors in my eyepiece.

2. Knowing the condition of the light before it hits the sensor lets me compose more accurately. If I'm looking at the true light, I can tell at a glance if there is detail worth working to preserve in the highlights or shadows (by using a split neutral density filter, for example, to bring the sky brightness down some) or not.

3. I'm not talking about edge-to-edge clarity. I'm referring to the depth of the focal plane, and the rate of falloff. If you're shooting with a very wide aperture before infinity-focus distance, the plane is going to be very narrow, and seeing the rate of the falloff is easier when it isn't pixelated.

Hope that helps.

In either case, when the photo is taken, the mirror whips out of the road (which generates mirror slap, another problem), and the light travels to the film or sensor. Since this path is a different distance to the one used for focusing, it requires only a small calibration error between the body and lens to end up with out-of-focus images. It is very normal to have to tweak the focus (higher end bodies will let you do this), or to have to have a body or lens physically corrected. No matter how exquisite your optics - in fact paradoxically, this effect is worst with high-end optics - the way the light path works here can be a real pain for getting good focus.

Because mirrorless systems focus and capture from the same medium, this literally can't happen with your mirrorless camera.

Modern zoom lenses have anywhere from 11 to 30 elements, in 3-11 groups, that move at different speeds relative to each other. Doing that with a tiny electric motor, precisely, for a decade is a tough task, especially when the mass of the glass starts to exceed 1kg.

With a mirrorless camera, you can reduce the mass of the lens by ~10% for a full frame camera. With an APS-C sensor, mirrorless, you can reduce the mass by 33%. With a "micro four-thirds" sensor, the mass of the lens is less than 50% of a full frame. Rough numbers. As with everything, there are pros and cons to going with smaller sensors than full frame.

For example, for many years fast normal lenses on SLRs were 58mm “Biotar” not 50mm because a a new kind of focusing (retro focus) had to be adapted to work with a mirror in the way.

The switch is quite obvious from the Canon release schedule - I don't think they have a single non-RF (mirrorless mount) lens being released this year.

Aside, I enjoy that Ken also loves this lens, despite it being mostly plastic, which he usually shits all over. It actually seems like a feature here, for weight purposes.

Where the 400DO perhaps really shines is paired with a 1.4x TC - it's much more handleable than a 600/4 and paired with a decent body gets results as good as bodies 10 years ago would have got with the 600/4.

I have three different TCs which I got from a friend who switched to Sony. I haven't really used them much because they seem to drastically change the optic behavior in ways I don't like. Maybe I should give them another chance as they never come out of their cases.

But that tradeoff seems hardly new to me. Consumer 70-300 for ~300 $ vs. Pro 70-200 for 2000+ $. The "only" difference is build quality and the pro lens being 2-3 stops brighter. Price difference: ~10x.

Another example is if I focus on something and then zoom in and out some lenses have to refocus and others maintain focus. This is an important feature for video and any kind of fast shooting. Many lenses have much more "focus breathing" than others. That is, the change of the effective focal lens as the lens focuses closer and closer. I had a lens that was 200mm but it was really only at infinity. At close focus is was closer to 135mm since the focus breathing was so pronounced.

Bokeh, chromatic/comatic abberations, geometric distortion are other things I can go on and on about.

It's been a long time since I paid any attention to pro photographic equipment so I don't know if fast lenses are important with modern sensors performing so well in low light. But back in the analog/early digital days 2-3 stops was a huge advantage.

Also something to consider, the pro lenses also focus faster and more accurately. I was never sure if this was down to the software in the lens, which is proprietary and why 3rd party lenses are never as good as manufacturer. I could easily see Canon or Nikon tweaking the firmware on prosumer lenses to focus a fraction slower.

IIRC, the pro lenses (white Canons) focused faster as a result of them letting more light in, as well as having faster motors (USM), though mid-range lenses had these as well.

Around that time, the body also made a big difference since the 1D-series had ~45 AF points, and the lower and mid-range bodes had 9-20 AF points. Not sure if this is still relevant but I think even low end bodies have a ton of AF points these days.

Especially when it doesn't have a nice manual focus ring à la the Olympus m43 lenses.

More importantly, those things combine to make a certain je nais sai quoi that makes photos taken with it seem to have much higher quality. I took a quick test shot of my dog when I got it and my sister remarked that she could practically feel the dog with her eyes, just looking at the photo. Nobody has ever said that about pictures of the dog that I took with the old lens, even if I spent considerable time trying to get lighting right and the dog to hold still.

My old lens ruined a bunch of shots I took in a forest that required running at the extreme edge of its settings. This new lens doesn't look like it will do that.

Actual light transfer (e.g. t-stops in cine, but less quantitatively in SLRs, say - some lenses are brighter than others), sharpness, chromatic aberration, spatial aberration, focal speed and accuracy (assuming autofocus), consistency across the telephoto range (not for primes, obviously) - some lenses will have not just differet f-stops at different lengths, but really different characteristics. This doesn't even get into the subjective aspects (e.g. "bokeh") that some people care a lot about.

Is it brighter for the same camera body, aperture and depth of field?

If so, what would one look for in a lens's specifications to describe this difference?

Which makes it bigger and heavier, harder to manufacture, and smaller market - all of this pushes prices up (an order of magnitude is common)

As for relative aperture adjusted for actual, measured light transmission, that's a T-stop, but these are typically only marked and specified for cine lenses, e.g.,

https://www.zeiss.com/consumer-products/int/cinematography/m...

(IIRC, the Master Primes are geometrically f/1.2 at T1.3)

the maximum f-stop of the lens describes the ratio of sensor length (1D, diagonally is best comparison probably), to the diameter of lens aperture. because the opening and sensor are two dimensional, every sqrt(2) increase in f-stop describes halving the light. for example, a f 1.4 lens can allow ~twice as much light as an f 2.0 lens. Every doubling of light is considered a "stop", like {1.4, 2.0, 2.8, 4.0, 5.6, 8.0}. An important consideration is that this number describes a ratio, not the absolute opening in the lens without respect to sensor size.

One possible conversion method is to consider the sensor size of the system against some popular standard. For example, "aps-c" sized sensors are about 1 stop "slower" than full frame sensors, due to being 1/(2.25) the size of full frame sensors in area, or 1/(1.5) linearly. This means that many lenses can be converted not only on focal length, but also for f-stop, to estimate the total light gathering power of the system, and the output "look" of the image. Full frame sensors (~36mm x 24mm) are most frequently used in the photography world as a standard comparison point. For example, a 50mm 1.4 lens gives 50mm 1.4 on full frame, but that same lens on an aps-c sensor (like a fuji X, sony 6xxx, canon 7d, etc.) would not only give a cropped 75mm [full frame] focal length equivalence, it would also give the depth of field of a 75mm _2.0_ lens [on full frame], not 75mm 1.4. At the same time, the exposure would still benefit from the light gathered at f1.4. This is why many say that smaller sensors give a larger depth of field (more in focus, less out of focus background). In reality, this is due to the lens aperture being measured only as a ratio to the sensor size. Finally, the smaller aps-c sensor will give a larger depth of field at the same f stop, but may also give higher noise at the same ISO (to a similarly advanced full frame sensor). This means that an aps-c camera takes the exact same image when it has ~1 more f stop, ~33% less focal length, ~1 stop lower ISO to the full frame system. A big confusion around any of this "equivalence" discussion is that sometimes people mean equivalence for lens "look", and other times, they mean equivalence for exposure, while others may be talking about absolute image quality and noise. They're actually all related, though much of this discussion isn't important to real world photography.

They also have a 500mm 5.6 that's similarly tiny (compared to a non-PF version) and hard to get.

I'm planning on picking up one of the Nikon mirrorless FFs soon.

Sensor size comparison: https://commons.wikimedia.org/wiki/File:Sensor_sizes_overlai...

I find this very fascinating because while I enjoy my ever-increasing smartphone camera and use it as a daily driver, I have a about 13 year old Canon DSLR (one of the first one they made now) with a few lenses and that 2007 model Canon D-SLR with the 1" large digital sensor can RUN INSANE LAPS AROUND TOP OF THE LINE SMARTPHONES with respect to the ability to take low light photos, get a lot of good light, and of course zoom on the telephoto, macro on the macro, etc. The autofocus is probably five times faster and the ~10 zones are lightyears ahead of the phone.

There's no comparison. Sure, the 7MP megapixels are bad. Sure, the ISO noise is pretty bad compared to modern smartphone postprocessing. But the telephoto isn't some pitiful "optical zoom", it's instead incredible powerful optics. The low aperture prime lenses produce beautiful shots whose distortion is matched to human preference.

The idea that phones can "catch up" to even 10 years ago on DSLR's would be very cool.

Unfortunately, I'm not holding my breath. Phone sensors are what 10X smaller? Doing great things with 10X less light is impressive, but at some point, you need a big sensor and good quality glass.

Would love to see us get DSLR quality pics from a phone tho.

To me, the old DSLR is simply not worth the weight of lugging it around any more. It's funny how we have such different perceptions of our old DSLRs.

I don't expect to do low-light without long exposure (ie, no impromptu shots) and I do have an external flash for bounce lighting indoors.

It's still better than my iPhone (which admittedly is a couple of years old), but weight is a huge factor I only use this when intending to get really good shots. Another is the extra time it takes to transfer files, sort through bursts and put into iCloud or smugmug.

https://www.flickr.com/cameras/canon/eos_digital_rebel_xsi/

Contributing factors may be that the pixels on the sensor are physically larger, and that the sensor-shift image stabilization helps with longer exposures.

2/3 of a second with an f/2 or f/2.8 lens means you can take pictures lit by not much more than starlight.

Actually, even without this, with an F/1.4 lens I can take a handheld picture using only light pollution.

It is now possible to build a telephoto lens for your DSLR, that costs $2 to make, is short and flat, yet has better optics than your current kit. When these become common, it will likely cause another seismic shift in the pure-camera market. Perhaps some of them will actually be bonded with the sensors, unlike what we have today.

Regardless, new lens technology -- while likely to make a greater impact on mobile phones -- is largely orthogonal to them.

Do you have any references you can share? I'm super interested.

edit: For anyone else interested, the key phrase that worked for me was "metasurface lenses".

But, I mean, it better not be considering both were about the same price!

This problem is basically solved already by taking multiple exposures and blending them in software. Once we're at the point where stacking 10 exposures works reliably even in challenging conditions (and we're pretty nearly there with the latest phones) then many of the advantages of a larger sensor are moot.

As far as glass "quality" is concerned, smart phone manufacturers benefit hugely from economy of scale. I wouldn't necessarily assume that smart phone lenses are manufactured to lower quality standards just because you're paying less for them.

Lenses on phones are limited by diffraction. They can never provide the quality of a larger lens because their aperture is so small that their airy disk is often over the size of a pixel.

Phones are simply not better at taking non-blury pictures in very lowlight. Cameras evolved since the 90s, we have 5 stops of IS, sharp f/1.4 lenses and exposure stacking.

The resolution advantage is not moderate at all. A 12MP phone is around as sharp as a theoretically perfect 8MP sensor with a perfect lens, while current cameras are as sharp as 40+MP perfect sensor with a theoretically perfect lens.

Diffraction absolutely doesn't come out as a wash. What matters is the actual diameter of the aperture, not the ratio. Phones are a tenth of ILCs in this metric, or even less for non-optimal focal lengths.

It's actually the f stop that matters for diffraction, not the absolute diameter. Roughly, this is because the light spreads more with a longer focal length because it has a longer distance over which to diverge. If you crunch the numbers this exactly compensates for the larger absolute diameter of the aperture. Here is a post with a reference: https://www.dpreview.com/forums/thread/21428

It's amazing how much enthusiast discussion about cameras is based on basic misconceptions about optics.

Here, the airy disk diameter is the image size. At the same magnification, the image height is proportional to the object size.

Since when the f number is smaller, at the same magnification, substituting in the thin lens formula with the magnification, you find that the object size is inversely proportional to the focal length.

From this you come to the conclusion that, at the same focus distance, the smallest object you can image is a function of the absolute diameter of the aperture.

Intuitively, this is because even though the airy disk has the same size, the focal length is much smaller, therefore the field of view is much wider for the same sensor size, therefore the angular confusion is much bigger, therefore for the same FoV at the same f number detail goes down.

Or put another way, yes the light spreads more, but the sensor on a camera is bigger, so in the end you have much more detail anyways.

This is why, for example, spy satellites despite operating at f/11 or so can resolve much more detail than a cellphone :)

This is a standard exam question if you ever take a Wave Optics class, by the way. But as you say, enthusiast discussion, such as on DPReview, is often based on basic misconceptions about optics :)

If the phone was using a slice of a DSLR sensor, then yes, the absolute aperture would be what was relevant, as you obviously cannot improve the resolution of an image merely by cropping it (if you imagine a ultra ultra wide DSLR lens which becomes a normal phone lens after the crop).

But two points:

First, you're then comparing resolution at a focal length that's irrelevant to DSLRs, so in practical terms it's not a like for like comparison.

Second, phones are using sensors with higher pixel density. The question is just whether the phone can use a wide enough fixed aperture to avoid being limited by diffraction at the desired resolution. A fixed aperture of e.g. f1.6 is practical at phone focal lengths but not (as a fixed aperture) at full frame focal lengths. If you calculate the theoretical linear resolution limit imposed by phone camera f-numbers, it's approaching 1000 lp/mm for the better models (e.g. an iPhone with an f1.6 aperture and a ~10mm sensor). I'm sure the real limits are lens aberrations and noise at the moment.

Secondly, I'm actually comparing resolution at fixed FoV, not a fixed focal length.

Again, the sensor size doesn't matter, what matters is the focal length. The focal length of an iPhone main lens isn't 10mm, the sensor size is 8.5mm but the focal length is actually around 5mm. You find the theoretical maximum linear resolution is more around 300-400 lp/mm. If you run the numbers, at f/1.6 the airy disk diameter is already bigger than the pixel pitch (2.11 microns airy disk and 1.7 micron pixel pitch). The resolution is already being seriously degraded by diffraction, although it's not completely diffraction yet. Lens aberrations make it even worse, of course. All in all, realistically the resolution is pretty much at its limit.

If you work at this regime where the linear resolution is close to equal to the airy disk, you start having a type of abberation where changing the wavelength of the system causes a change in the resolution, which can't be fixed. So pretty much in practice you can't really exceed the resolution we see now even in perfect light with a perfect lens, because you start having unavoidable abberrations that are very significant to the image.

Well, yes, but the two are obviously tightly linked if we're comparing a DSLR to a phone camera.

I'm going by the calculation in the 'Cameras' section of https://en.wikipedia.org/wiki/Airy_disk It explains why only the f-number is relevant. If you plug values for an iPhone into the 'x =' equation, you'll see that an iPhone camera is not really close to being limited by diffraction. The minimum separation distance at 500nm wavelength at f1.6 comes out to 976nm. Along an 8mm sensor dimension that's 8188 line pairs. Now sure, that's by the Rayleigh criterion, so you're not resolving 8188 perfectly sharp line pairs. But that's a still a good margin over the sensor resolution, and it's an open question how good sharpening algorithms can get.

And this is of course the very best you can do at 26mm equivalent focal lengths, if you want a tighter or wider shot your image quality degrades because once again the optics don't fit and you'll have to reduce your f number.

2000 line pairs in perfect conditions is quite low. Better is expected from cheap DSLR zoom lenses.

Yes: the quantity calculated is the smallest separation two objects can have before they blur together (by the Raleigh criterion).

According to the standard notion of lp/mm, there is no need to halve the reciprocal of this quantity to get lp/mm. See e.g. the table on p.14 here: https://zenodo.org/record/3518178/files/Verhoeven%202019%20-... An airy disc of ~2um radius translates to ~500 lp/mm. The following page also agrees with this usage, as does every other source I can find at the moment. http://www.normankoren.com/Tutorials/MTF1A.html

I think you are basically out by a factor of 4 by using the diameter instead of the radius and requiring line quads rather than line pairs. I believe the lp/mm value obtained is for ~9% MTF, so it's a fairly generous estimate of the available resolution, but not excessively so.

Regardless of the correct definition of lp/mm, the iPhone has plenty of room to increase the sensor resolution at f1.6. And phone cameras could certainly move to somewhat wider apertures and somewhat larger sensors.

As for the rest, lp/mm only makes sense at a given MTF rating. MTF50 is the standard. MTF9 is very, very, very generous. Incredibly so.

But anyways, sure, let's take 900lp/mm on the short edge for 4590lp/mm MTF9 - maybe I misremembered. A 5DSr with a real world zoom lens, the 24-70mm F2.8L, gets 7700lp/mm in the real world, and that's the MTF lens-sensor system, not just the lens. And that's not even close to the maximum possible resolution, nor to the maximum you can actually get in real life as you can. If you take the sharpest full-frame lens I know of whose MTF9 is limited to 400lp/mm because no testing apparatus was available that could go higher, the actual maximum is around 9600lp/mm. In any case, even the highest theoretical resolution of a phone is far lower than the practical resolutions of ILCs in use today, and is actually less than the sharpness of a 90$ lens on the very cheapest full-frame body you can find.

Indeed, take the Canon 50mm EF II, with an MTF50 yielding ~2000-2400lp/mm on the short edge of FF sensor. According to this source (https://www2.uned.es/personal/rosuna/resources/photography/D...), at around f/1.6 we should get around 420lp/mm, on the short edge that's 2142lp on the short edge, which is less than the cheapest EF lens in production right now. I don't know about you, but the best possible performance in theoretically perfect conditions being under the performance of the cheapest EF lens in the real world says something.

In real life, of course, the lens-sensor system will barely get close to the theoretically perfect result, and you will peak at the best possible result being around half the linear resolution of the cheapest production Canon lens.

Keep in mind, if you were to go for a larger sensor, you'd have to increase the focal length to compensate too. So 20% increase in sensor size length would need a 20% increase in focal length and at the same f number you'd need a 20% wider aperture too. And again, you'd be fixed at around 25mm FF eq. focal lengths, if you try more practical focal lengths like 50mm FF eq. you would see a drop in quality. They're already pretty much at their optical limits and have been for a while, actually f/1.6 isn't even the fastest phone lens - but those had smaller sensors still.

Here's the problem.

Doing "things in software" is akin to saying ultraprocessed food is gourmet "food".

Basically, it's a pretty common technique for increasing SNR, it's a very different kind of "doing things in software" than, say, an iPhone's fake bokeh. It's no surprise that phones are starting to use it.

I feel that phones usually make better decisions for contrast, white balance, exposure than DSLRs do. With a DSLR, reaching the same finished product usually requires a ton of manual work editing photos.

Of course, the DSLR has far better detail on the pixel level, and if you need to zoom in at all, it wins in a landslide. I wish I could combine the strengths of both platforms.

That said, the traditional camera manufacturers are pretty much laggards with respect to software so their better hardware isn't really used to full advantage a lot of the time.

They're trying to solve two different problems. Nikon want to reproduce colors that are balanced and accurate. Apple want to produced colors that 'pop' and catch peoples eye when scrolling through Instagram.

My dream is a camera with a nice sensor/lens and an iphone brain. It likely already exists, up there orbiting the earth...

There's a ton of engineering that goes into designing eg; a zoom lens that can cover a focal range while retaining sharpness, minimal color fringing, etc. And that's assuming you can use software to correct for distortion... in the past that was a dealbreaker. The result is a lens that requires 10-20 (or sometimes even more) individual elements. No matter how you cut it that will be expensive.

There's no cheating physics sadly.

It was something reproducing a sort of "solar furnace" (https://en.wikipedia.org/wiki/Solar_furnace) at a micro scale, coordinated with electronics. Think creating a dynamic lens by redirecting light from many micro lenses (mirrors?).

The upside being dynamic focal lengths using extremely short lens (the whole thing being microscopic).

Am I day dreaming? I can swear I read something or saw a documentary somewhere.

Or is what I'm describing just another name for metamaterial lenses? Based on what I've read about metamaterials, right now, I don't think it is, but I can very easily be wrong.

Edit:

Ah, maybe microlenses? https://en.wikipedia.org/wiki/Microlens

Does anyone know if they're applicable to camera lenses?

(1) Older digital sensors weren't good at all with high-iso (high read-noise, low photon-electron conversion efficiency, etc)

(2) An off-sensor DSLR AutoFocus array has a very small effective-aperture, making the lens aperture very important in low-light situations for autofocus (which a lot of nature photography is)

(3) Bokeh - Ofcource nothing beats large aperture bokeh, but this can be tackled perhaps through computation?

For (1) and (2) Modern imaging sensors perform beautifully in high-iso scenarios. Also, with mirrorless, there are cameras that can AF down to F/22 - something unimaginable (and impossible) with DSLRs.

While the demand for 600mm F/4 is there from a professional standpoint, there is an even larger demand for cheaper options - and.. this point is important, you can produce award-worthy images using those cheaper potions. In fact if you look at any nature competition a lot of the awards go to images made with cheap/budget gear.

Pick up a Canon CN-E 30-300 cinema lens and it is this exquisite, jewel-like thing that seems as though it is made by NASA. And it's $45K.

I always found Nikon cameras more my taste than canon. But that is just taste, in terms of quality, in the sense of the pictures, I never saw a difference. Not back the day when we still developed our black and white pictures ourselves and not now with digital cameras.

Lenses on the other hand a different thing altogether. There I saw defferences between the "cheaper" Sigma and the premium Nikkor ones. Not always but sometimes. I would assume that the new mirrirless cameras are less complex to build, so maybe the Thailand based manufacturing facilities are best suited. After all, it's the lense and the person behind the camera that counts.

But with the capabilities of modern cameras the production requirements for them are high and the challenge to make something that works for a variety of consumers even higher. I can't even look at a camera that isn't "weather-proofed" as I live in a place with a 90% chance of rain at any moment, for example. And a lot of these advancements are designed to work in combination with the lenses, such as in-body and in-lens stabilisation working together, weather seals that line up, etc. I think it's pretty important to maintain the same manufacturing quality between the two areas. I'm sure that's possible when moving production to Thailand, but I expect it will take time for them to iron out their processes.

My personal experience of Canon vs Nikon is that I prefer the software of Canon, and historically I preferred the physical ergonomics of Nikon, but the newest Canon models have improved a lot there. On the lens side it was always Canon for me, although I do have a lot of love for Sigma: my 150-600mm Sigma lens has a USB dock where I can actually manually configure the autofocus, among other things, which appeals to my gadget side (and honestly their quality has jumped up massively in the past decade).

It's totally hand-holdable, but reviews online make me wonder if everyone else has pipe cleaners for arms; it took a couple of weeks to get used to it but I don't have any trouble now. The image quality is fantastic and extremely competitive. The image-stabilisation works superbly, and the autofocus is very good - much better than their older lenses.

I mostly photograph birds and I'm extremely happy with the quality. All the recent bird photos I've uploaded are taken with it: https://www.flickr.com/photos/robotmay/50528664881/in/datepo...

I'd like to get myself a long lense for those kinds of shots but I really can't afford Nikon prices!

Can't agree more on the weather-proof part. I was ather funny to be out taking pictures all day, only to find the camera was sitting in 5 cm of water in its protective bag. Nikon did work better druing that, than. Just an anecdote so, some Nikon's didn't like it that good neither.

Some Sigma lenses were really good back than, some on par with Nikkor. Canon lenses were, if I remember well, mostly on par with Nikkor. Been used to Nikon so, I always to break the lighter Canon camera bodies.

Nikon have already been making weather-sealed cameras in Thailand for ages (e.g. the D7500). I think your concerns here are overblown. Any quality problems with their Thai manufacturing operation would already be apparent, given that most of their cameras are made there.

They always have. Yet strangely you can buy an L lens and it may outlast a whole series of bodies. (if we continue to have DSLRs that is).

I've always wondered what the difference is between Sigma and a brand like Canon or Nikon.

I used to have both Canon and Sigma lenses. The Sigmas felt different, and the pictures they produced had a different "look" for what was supposed to be an equivalent lens. My eye isn't trained for these sorts of things, so I was never able to quantify it.

What is it that Sigma does that makes its lenses cheaper than the others?

So they also do a 150-600mm Contemporary model, which has 90% of the performance. It doesn't have full weather-sealing, and it has a different element arrangement which slightly changes the picture quality, but it also drops a huge chunk off the weight and about £400 off the price. It's not quite as solidly built but for a lot of people it's more than enough and provides a good alternative.

In my personal experience Sigma lenses tend to be heavier than Canon for equivalent build quality. ~10 years ago I'd say the picture quality was slightly poorer, but now they compete very well in a variety of ranges.

My use case also involves a fair amount of tripod work, and I even picked up a gimbal just recently.

So I'm glad that Sigma is making lenses which are cheaper / better for the price by leaving out OSS, because there are ways to not need it. If you figure OSS would cost another $200 per lens, which seems a little low but is in the ballpark, then with the Sigma 'trio' of 1.4 primes, the difference between the a6100 and a6600 is just about a wash.

Agreed on customer service.

Nikon still make many of their top tier lenses in Japan as well. I don’t see that changing any time soon.

Apple’s cross functional business org makes them really effective at transferring expertise across product lines. Just subsidizing the high end camera line might be worth it to transfer technology and expertise to iPhone cameras.

(Plus slapping an Apple logo on Nikon cameras would probably boost sales overnight)

Seems if I add any lenses to my collection I'll be buying used or new from Sigma/Zeiss. I saw the shift happening already and had mostly already been doing that. I will say the new PF series pro lenses with fresnel lens elements are really great though. While I still have my older 300mm, I also got the new pro series 300mm prime from Nikon as it's significantly smaller and lighter weight, doesn't even require a lens foot and can be shot hand-held if you have a steady grip. I suppose I should start budgeting to acquire the 500mm version of the PF lens before they move production out of Japan as I find it unlikely I'd buy anything else that's Nikon branded for lenses. For shorter focal length stuff Zeiss is far far superior.

All the Leica m43 glass are so called Pana-Leica glass: Panasonic designed and manufactured but Leica rubber stamped. They still are really nice glass, though :)

Disclaimer: used Olympus 4/3 and m43 for reaally long time but the mirrorless full frame gear feels so much better in the closely same sized package.

Last year I cracked the lens mount on my d810, and I took it to the shop where I bought it, and they sent it off and had it repaired no questions asked for a reasonable price (it's out of warranty). It took longer than I would have liked, but other than that a good experience.

Over at Fred Miranda and DPR, canon shooters always lament about the lack of competitiveness Canon was regarding Nikon glass.

I really would like to have the 13mm Rectilinear lens if only it isn't worth several tens of thousands of dollars.

https://en.wikipedia.org/wiki/Nikkor_13mm_f/5.6#:~:text=The%....

Sigma is probably the best of the third-party lens manufacturers. I have a first-generation Sigma 50mm f/1.4 with Nikon mount (purchased around ~2011) — the build quality is great, and the bokeh is fabulous.

I can't say the same for Tamron.

They had never been particularly big, until the 1990s, with the advent of point-and-shoot digital cameras.

That gravy train ended when the iPhone came out. They are probably contracting to their more traditional role, of Big Black Cameras, as well as some very good scientific optics.

They have some of the finest scientists and engineers in the world, as well as a gigantic portfolio of patents. They aren't going away.

From what I hear, the Thai do a great job, but it's still a big psychological shock to leave Japan. Their Japanese plants were considered the "top shelf" production facilities.

Kodak would like to have a word.

Nikon sees this happening and choose which side of the divide to service. It's probably the safer bet, too, as some of the top-tier manufacturers are going to have to either coalesce or dissolve in the next decade or two regardless of strategy. At least in the consumer market strategy, such as partnering with a cellphone manufacturer, could open new opportunities.

Kodak pioneered digital photography (they literally invented the first digital still camera). All through the 80s and 90s they had the best digital camera sensors on the market and where first to release a commercially available DSLR. In the mid 90s they owned the pro DSLR space.

But they didn't want to cannibalize their film market, and after much infighting between senior managers they ended up not investing in the digital lead they had. And the rest, as they say, is history.

That's a philosophy that I have followed, myself, and I find it is quite effective.

They will have to join the queue behind a lot of Swiss watchmakers.

There has been massive consolidation in that market and most of those brands you see are all owned by one of maybe three conglomerates.

The people who make movements are a much smaller bunch.

Incidentally, recent sales have apparently been massively affected by COVID, as many of them are sold in bricks-and-mortar boutiques that customers are no longer visiting.

[Edit] - this is the queue of companies who failed to consider a rival disruptive technology.

I'd argue not having to go into an office and "dress up" has impacted the watch market as well. If I'm at home all day, I don't really need a clock on my wrist.

Lots of AirPods, too.

But that is anecdotal, from a limited geographic perspective.

For a time, a fair number of people didn't wear watches at all, and used their phones.

Those are the people that I'm seeing with Apple Watches (and other devices, like FitBits).

Apple watches are updated every few years. Swiss watches last a lot longer. Price might not be that different over 10 to 20 years.

They are good enough looking, and I need to close my rings, damnit! They just do so much more...

That's a bug, not a feature! My Gshock is indestructible and tells the time, and that's about it. Perfect for me.

No amount of valuable patents and top-notch engineers can help a failed strategic bet like this.

I also have a couple of Japan-only Casio/Oceanus watches.

I haven't worn any of them in quite some time.

Those are exactly quickly going away. Engineers and scientists need to get paid and want job stability, while patents have a 20-year lifespan.

Nikon was on top of the world in 2008 with the D300 and the D90, but the technologies that made those possible were patented years prior. Right now, the curve is with mirrorless where Sony, Panasonic, and (now defunct) Olympus have a 10-year lead on patents. It's also with smartphones, and those technologies bubbling up. In the deep learning/ML battle, Nikon is bringing a knife to a gunfight.

On the other side, they're having massive layoffs right now. When companies have layoffs, usually they let go the bottom end of the workforce, while the top end leave voluntarily.

Nikon is continuing to patent new lens designs, but so is its competition. Nikon has excellent optics, but so does Olympus, Canon, Fuji, or Sony; they aren't exactly ahead of the pack here.

Sigma has really been pushing the edge on optics.

I'd love to know things like what they trade off in terms of $, weight, complexity, aberrations, performance. And do they have to retire an old lens line to make room for a new one?

And this is way too much to ask here (I'm sure I need to read an optics intro), but how in the world do they solve that they need 12 elements, etc. to make some aberration go away, by combining 3 different index of refraction glasses in a certain order, etc! Amazingly complicated.

I imagine now there are ray tracing solvers for it, but I wonder how they did it in the early days of lens design!

Now phones have eaten both compact cameras and hobbyist DSLR markets. Prosumer and professional DSLRs/ILCs are a niche market and Nikon is becoming a niche company.

If your hobby is shooting sports, wildlife or stars (big balls of gas), buy an ILC. If all you need is a travel camera, an iPhone is a damn good one and it's smart enough to beat 9 out of 10 humans fiddling arround in Lightroom.

Nikon, if it were to survive, would need to move into new markets. dSLRs are dying, but imaging is exploding. Nikon and Canon ran into the innovator's dilemma: they didn't want to eat into their core market, so they released crippled products like the Nikon 1 or Canon M-mount. By the time they got into the game, their market was collapsing, they lost a lot of credibility, and Sony had a huge lead. It's probably too late, but we'll see.

Drones, industrial, teleconferencing, and hundreds of other markets are popping up, but Canon and Nikon are conspicuously absent.

And, when I do buy an expensive item "made in Japan", I can generally trust that it is of high quality. Compare this to shopping for appliances in the USA, where brands like KitchenAid and CuisinArt are perpetually cheapening the quality of their products while keeping the price the same and coasting on the reputation they built in the 1970s and 1980s.

For instance Sony products are not seen as ‘made in China’, just ‘made by Sony’

There’s a scale, and ‘made in Japan’ seems to so far be better than not.

That said, if they can halve their prices by building in Thailand, maybe customers will forgive them.

Since the only thing left is the high end market though, I’m not sure cutting prices is most relevant now though.

But quality? Sorry but haha. No.

...as it somehow tries to imply that it is not designed in China (but it is).

To me that kind of messaging just exudes arrogance.

Sony has…a lot, from semiconductors to financial instruments. Canon has high-end video, scanners, and enterprise printing and copying. Nikon has photography-oriented cameras, some medical optics, and semiconductor equipment, and that’s about it. They’re just not the sprawling conglomerate that can absorb losses as easily as Sony.

Sigh. I’m a camera nerd, and I hate to see the market shrink further. I know it’s going to—cell phone cameras accomplish the actual job to be done that most people have, which is snapshots of kids and cats. And, interchangeable lens cameras are getting to the point they’re over-serving the high-end market with ever-fancier lenses and marginal sensor improvements, with no real workflow improvements.

Though that still gets to my point that they make optics, and pretty much just optics. Makes it hard to pivot (ugh, sorry) to anything else, from a corporate mentality standpoint.

[0] https://www.digitalcameraworld.com/news/gun-control-nikon-wi...

At the risk of angering Leica fans: they’re shipping not exactly state of the art technology at very high prices, with a lot of the R&D actually being done by Panasonic. (Or, in the case of their Lux compact cameras, they’re literally shipping Panasonic cameras with a different sticker on them.)

Look at the Leica Q2: it costs $5000. The Fuji X100V costs $1300. I know there’s a bigger sensor in the Q2, but, c’mon, there’s not $2000 worth of magic hiding in there.

By contrast, Leica's digital M bodies have always been at least a generation behind... at their time of release. The way you deal with this is correct exposure discipline, such that there's less to deal with in post. Newer M bodies have gotten much better, however.

The Q is a really interesting line, since I assume it's a collaborative project between Panasonic, Tower Jazz, and Leica. Frankly, the images for both the Q and Q2 are outstanding, and I'd throw down another $5k for a 50mm Q2. If you seriously think an X100V can compete with a Q2 for full pipeline imaging (capture to print), you're nuts. I've personally seen large prints come out of my Epson P800 from an XE-3 + 23/1.4 and my Q2 and the noise reduction artifacts inherent to the X-trans filter are noticeable on paper. If all you're doing is posting to IG or Flickr, Fuji is amazing for the money.

The M9 was revolutionary in 2009, an 18MP full-frame sensor in a peer-comparatively tiny body. The M Monochrom in 2012 is the only major first-party camera to release w/o a Bayer filter with massive increases in resolution and sensitivity. They've been riding the "classic rangefinder experience" for some time since with incremental improvements, but the early digital M bodies were anything but behind. The recent M10-R and M10-M are also competitive sensor-wise.

I think that misses the point: when you buy Leica, you're not buying technology. It's not a technology company, it's a luxury brand. You buy Leica over Canon, Fuji or Panasonic for the same reason you buy Rolex over Casio, Swatch or Seiko.

Having used an M camera briefly, they aren't worth the price new, but used they are really great values that are built like nothing else. When you tire of them, you can sell them back for what you paid, sometimes more!

If you look at the photos on a big monitor, you can spot the difference between a DSLR and smartphone. But on a smartphone screen, where 95% of the photos are viewed these days, the difference is negligible. Heck my wife recently printed out 4x6 prints of her smartphone photos and they looked pretty good too.

I've recently got a iPhone 12 Pro, and it's good enough that I'm thinking of selling my Fuji X100V. DSLRs used to be accessible for amateurs. But unless you need specific capabilities (strobe usage, fast sport shooting, ultra-telephoto, etc), most people don't need to buy a DSLR if you have a decent smart phones these days.

Personally, I'm very pleased that my camera (a Nikon D850) boots instantly (approx 0.2 seconds) and has a shutter lag of 0.05 seconds (when pre-focused). It essentially never unexpectedly hangs when I need to take a shot. For my preferred subjects (wildlife) a consistently instant response is far more important than arbitrary functionality. If I want to share pictures or do other things, I can use the built-in wi-fi or Bluetooth to shunt pictures to my SmartPhone.

Why would I ever want any of that in a DSLR?

A DSLR can go from sitting on the shelf to having taken a focused photo in less than a second. The battery life is measured in weeks (unless using built-in flash). No comparison how much better experience it is.

My Sony runs Android and never hangs nor has an shutter lag. Instant response in everything. It can be done.

Granted, it's not "no shutter lag", but 2.3ms might as well not exist.

I looked at the camera specs online.

Also, what you're asking for is already available in most flagship smartphone these days. Instead of moving apps to cameras, they moved a good enough camera to a phone where all your apps are available.

The idea I really liked was Sony that made "smart lenses" that was basically a decent sensor and a decent lens that you clipped onto your phone and connected via Bluetooth/WiFi and used the phone as a display and storage

Photographers rarely post un-processed images. Even before all of that, settings are chosen which alter the exposure, depth of field, focus point, color temperature of the image which alter the "real thing". It's common to think "editing" a photo is some cheating magic, but it should be considered the norm, and how people share their vision of what they want it to look like.

The AI can just automate a lot of the workflow or need to buy extra equipment, still up the human to decide how they want the image to come out.

I'm not sure what's going on, but this craze about computational photography is ruining cellphone photography for me.

Try to take a selfie with the iPhone 12 Pro. It's awful. If you use the regular camera, it generates an HDR selfie exaggerating every imperfection on your face. And if you use portrait, it applies a fake looking blur and softness to your skin and is incredibly strict on framing.

Camera photography is moving further from realism and I don't want a part of it.

Turn the camera around and you get similar problems. From detail-less low-light images, to sun-saturated indoor shots. It's like everyone took the Samsung model and ran with it.

My DSLR is the only lens I have that can produce a realistic photo nowadays and give me access to the raw sensor data.

Every iPhone currently for sale and I presume most high-end Androids support shooting in RAW, you just have to use a third-party app.

as predicted, enthusiasts wanted to argue the point instead of acknowledge what the market can bear

photography enthusiasts have to realize that “the market” is more concerned about their shoes being in the photo than how the bokeh looks, and in that respect AI depth of field that comes with a nondestructive parallel full focus image, with smart HDR on by default, also available in a derivative of RAW format is more than good enough!

All in a much more portable form factor.

The potential for a 5-10% optimizations in a larger traditional form factor just isn't good enough of a distinction.

Didn't those just come out?

Oddly enough, I just picked up an X100T from eBay and I haven't been using my phone nearly as much. I don't know if the novelty will wear off or not, but I've been really enjoying it

I will concede that I'm not the average consumer and already had "manual mode" camera experience

> Without that, there is really no reason to use anything but a smartphone.

I would disagree with that sentiment, but I'm on the other side of the fence of knowledge, so it's hard for me to say

To counter that a bit I'd like to add that there is a rise of video/youtuber folks wanting smooth 4k video with tracking auto-focus, and real bokeh which is making cameras, or hybrid cameras relevant again. I don't think phones do fake bokeh in video mode or do low-light video w/o looking like ass.

The Lidar and infrared and AI will help with the low light. They fill in colors instead of take the result of the lens and sensor physical limitations.

There are apps that do what the default cameras don’t do yet, and we’ll continue to see rapid optimizations on this front.

what you mentioned is not outside of the realm of what can be done. If there is a need, making an app that does it will give you a brief advantage.

Outside of macro and wildlife photography (basically, extreme closeup and extreme telephoto), I tend to use my phone more than my dSLRs. It's smaller, more convenient, and the pictures it takes are 70-80% as good as I'd get on my heavier gear. Well, there's also an annual parade I shoot where I want to be able to control depth of field and trigger some strobes, and I use the dSLRs for that too.

I've been eying a body upgrade, but I can't really justify it. Having one crop sensor body and one full frame, I'd rather spend the money on new, fancy lenses. And the computer-designed lenses really are incredible. I have an 28-300 lens with vibration reduction that is frighteningly good for the range it covers. It has some distortion, but nothing that's not easily corrected in production. And it's very nearly as sharp as some of my pre-autofocus primes.

It seems one of the problems that Nikon (and the other manufacturers are facing) is that the quality of camera gear is just incredibly high across the board. I could spend a few grand to get a body with an extra stop or two, and a bunch more pixels. But I can hand-hold a modern vibration-compensating lens at 400mm down to somewhere around 1/100th of a second and get good results. I don't print large, so I don't need more pixels. Why spend the money?

https://www.imaging-resource.com/news/2018/04/17/glass-for-g...