It's very simple. A camera sensor has a certain dynamic range, i.e. can "see" things from shadows to highlights. The way the sensor sees the world differs from the human eye. To make the sensor data match human vision, a curve/picture profile is applied to the data it has recorded. Standard video curves/profiles, such as Rec709 for HD video, tend to crush the shadows and the highlights. Flat/log profiles reproduce the sensor data so that nothing gets crushed or clipped, typically resulting in a greyish/washed out-image to the human eye. This gives you more information for post-production color/exposure correction which wouldn't have been there with the crushed shadows and highlights of a standard color profile.

If you want a purely technical description: http://pro-av.panasonic.net/en/varicam/common/pdf/VARICAM_V-Log_V-Gamut.pdf

But if you want some context, basically V-Log and V-Log L are the same idea as Canon Log or Sony S-Log, though with specific differences. These documents explain it better:

• http://learn.usa.canon.com/app/pdfs/white_papers/White_Paper_Clog_optoelectronic.pdf

• https://pro.sony.com/bbsccms/assets/files/mkt/cinema/solutions/slog_manual.pdf

• https://pro.sony.com/bbsccms/assets/files/micro/dmpc/training/S-Log2_Technical_PaperV1_0.pdf

Standard cameras record into a display-referred color space: the signals are meant to be sent to a monitor for display, without any manipulation. The images are rendered for a certain type of display, and the look is baked in.

Camera log spaces such as S-Log and V-Log are scene referred. They represent the image in terms of the way the camera's sensor captured it. The look is not baked in. Contrast, saturation, and highlight handling are up to you and your workflow, instead of being determined by the camera and how it was set during shooting. Scene-referred images aren't meant to be displayed directly. A specific transformation is required to convert them to the color space of a display. For most camera log spaces that transformation involves a matrix or a 3D LUT. Standard color correction tools are insufficient to convert those camera log spaces to a display-referred color space, though many people still try to use them, making the job very difficult and producing inaccurate colors.

Here's a link to Barry Green's explanation of how the GH4's V-Log-L differs from the Varicam's V-Log tone curve:

The chart shows 16 stops from -8 to +8, with zero calibrated to 18% gray reflectance. Note how the flat log segment of the curve extends down to about -4, with a rolloff knee down to 0% reflectance in the bottom 4 stops of the shadow range. This is the part of the dynamic range that must be accurately exposed in order to match the non-log segment of the V-log LUT you select.

The important issue, however, is that green rectangle Barry drew on the chart at stop 4. That's where the GH4's 12-stop dynamic range ends with highlight clipping, 4 stops short of the 16-stop range of the Varicam's V-Log tone curve. In order to match the V-Log curve, he claims you should set exposure for highlight clipping at 79 IRE. That would appear to sacrifice the camera's 80-109 IRE range, for the sake of allowing you to use Varicam V-Log LUT's interchangeably with GH4 V-Log-L footage.

The vertical calibration on the chart is a 10-bit scale from 0-1024. On a camera with an 8-bit codec like the GH4, you would have a scale from 0-256. That means highlight clipping would be recorded at around 180, with no image details recorded in the range 181-255. At the other end of the scale, the bottom 4 stops of shadow detail would be recorded in the range 32-48, just 4 bits of data to cover 4 stops of dynamic range.

In short, 8-bit V-Log-L appears to squeeze out more dynamic range by sacrificing tonal range in both highlight and shadow regions.

@Vitaliy_Kiselev The V-Log chart was missing in the other topic. That's the key piece of evidence.

My little prediction about Barry Green's analysis of Matthew Allard's test of V-Log L on the DVX200: the analysis was not correct and their expectations about clipping are wrong. The ISO was set too low to use the entire V-Log L range. Just increase the ISO setting, and the clipping level goes up closer to where you'd expect it to be.

I don't believe Panasonic would be so ridiculous as to make V-Log L always clips at 79%.

1. It's a pseudo-logarithmic RGB scale. The luma scale takes properties of the RGB scale, since luma is derived from the RGB values.

2. V-Log L extends the highlight range compared to a standard photo style at the same ISO setting. You can capture brighter highlights without clipping. But just how much it extends and where it clips depends on your ISO setting.

3. I'm not sure what you mean. But capturing an extended range of highlights doesn't mean the midtones and shadows are the same. To capture more highlights, the sensor gain needs to be turned down. It's sort of like shooting at a lower ISO and then brightening the image in post: the shadows will be noisier. The best exposure for a standard photo style won't be the best exposure in V-Log L. For the same ISO setting, you need to boost the exposure in V-Log L to achieve comparable noise in the shadows and midtones. (or, for the same exposure, you need to boost the ISO setting)

How does V-Log L magically extend the highlight range without turning down the gain? Full well capacity doesn't change because of V-Log L. Panasonic was not throwing away tons of highlight range captured by the sensor in the days before V-Log L. Why do you think V-Log L is not available at the same base ISO as standard photo styles? Because for the same ISO setting, it uses a lower sensor gain, and of course there is a minimum gain. I don't like to debate with you. Just think about it.

Perform this test, and you will understand the connection between V-Log L and sensor gain:

Wait and get your hands on V-Log L for the GH4. Shoot an object in V-Log L at ISO 3200, with the exposure adjusted so that the object is just below clipping in the V-Log L output. Switch the photo style to Standard and shoot the same object as a raw photo at ISO 3200, with the same exposure. Use RawDigger or some such tool to analyze the raw image. Will the object be just below clipping in the raw photo? What's the highest ISO setting that will make the object be below clipping in the raw photo?

Wait and get your hands on V-Log L for the GH4. Shoot an object in V-Log L at ISO 3200, with the exposure adjusted so that the object is just below clipping in the V-Log L output. Shoot the same object as a raw photo at ISO 3200, with the same exposure. Use RawDigger or some such tool to analyze the raw image. Will the object be just below clipping in the raw photo? What's the highest ISO setting that will make the object be below clipping in the raw photo?

Well, it was not me who stated all this, hence - do the tests.

And throw out ISO from all this. Just fix ISO (low is preferable due to obvious reasons) and do not touch exposure. Target of this tests is to get math function. You do not need to adjust anything.

@VK we need to fix this problem. Shooting log rules topic needed.

Bullet point style. Do this -> then this. Expose to this. Etc. End the IRE rubbish. Just simple rules.

IRE is not rubbish. It measures luminance values in the decoded video signal which allows us to measure display brightness without referring to bit depth.

On a camera with an 8-bit codec like the GH4, you would have a scale from 0-256. That means highlight clipping would be recorded at around 180, with no image details recorded in the range 181-255.

It make really no sense, at all.

As only marketing idea (to make it look dull and super flat) can lead to this. Or some utter failure that Panasonic proponents want to hide under smart looking terms.