Monitor Calibration with ColorMunki

Monitor Calibration with ColorMunki Photo

Following on from my previous posts on the subject of monitor calibration I thought I’d post a fully detailed set of instructions, just to make sure we’re all “singing from the same hymn sheet” so to speak.

Basic Setup

_D4R7794

Put the ColorMunki spectrophotometer into the cover/holder and attach the USB cable.

_D4R7798

Always keep the sliding dust cover closed when storing the ColorMunki in its holder – this prevents dust ingress which will effect the device performance.

BUT REMEMBER – slide the cover out of the way before you begin the calibration process!

colormunkiSpecCover

Install the ColorMunki software on your machine, register it via the internet, then check for any available updates.

Once the software is fully installed and working you are ready to begin.

Plug the USB cable into an empty USB port on your computer – NOT an external hub port as this can sometimes cause device/system communication problems.

Launch the ColorMunki software.

The VERY FIRST THING YOU NEED TO DO is open the ColorMunki software preferences and ensure that it looks like the following screen:

PC: File > Preferences

Mac: ColorMunki Photo > Preferences

Screen Shot 2013-10-17 at 11.28.32

The value for the Tone Response Curve MUST be set to 2.2 which is the default value.

The ICC Profile Version number MUST be set to v2 for best results – this is NOT the default.

Ensure the two check boxes are “ticked”.**

** These settings can be something of a contentious issue. DDC & LUT check boxes should only be “ticked” if your Monitor/Graphics card combination offers support for these modes.

If you find these settings make your monitor become excessively dark once profiling has been completed, start again ensuring BOTH check boxes are “unticked”.

Untick both boxes if you are working on an iMac or laptop as for the most part these devices support neither function.

For more information on this, a good starting point is a page on the X-Rite website available on the link below:

http://xritephoto.com/ph_product_overview.aspx?ID=1115&Action=Support&SupportID=5561

If you are going to use the ColorMunki to make printer profiles then ensure the ICC Profile Version is set to v2.

By default the ColorMunki writes profiles in ICC v4 – not all computer operating systems can function correctly from a graphics colour aspect; but they can all function perfectly using ICC v2.

You should only need to do this operation once, but any updates from X-Rite, or a re-installation of the software will require you to revisit the preferences panel just to check all is well.

Once this panel is set as above Click OK and you are ready to begin.

 

Monitor Calibration

This is the main ColorMunki GUI, or graphic user interface:

Screen Shot 2013-10-17 at 12.32.58

Click Profile My Display

Screen Shot 2013-10-17 at 11.17.49

Select the display you want to profile.

I use what is called a “double desktop” and have two monitors running side by side; if you have just a single monitor connected then that will be the only display you see listed.

Click Next>.

Screen Shot 2013-10-17 at 11.18.18

Select the type of display – we are talking here about monitor calibration of a screen attached to a PC or Mac so select LCD.

Laptops – it never hurts a laptop to be calibrated for luminance and colour, but in most cases the graphics output LUT (colour Look Up Table) is barely 8 bit to begin with; the calibration process will usually reduce that to less than 8 bit. This will normally result in the laptop screen colour range being reduced in size and you may well see “virtual” colour banding in your images.

Remedy: DON’T PROCESS ON A LAPTOP – otherwise “me and the boys” will be paying you a visit!

Select Advanced.

Deselect the ambient light measurement optionit can be expensive to set yourself up with proper lighting in order to have an ICC standard viewing/processing environment; daylight (D65) bulbs are fairly cheap and do go a long way towards helping, but the correct amount of light and the colour of the walls and ceiling, and the exclusion of extraneous light sources of incorrect colour temperature (eg windows) can prove somewhat more problematic and costly.

Processing in darkened room without light is by far the easiest, cheapest and most cost-effective way of obtaining correct working conditions.

Set the Luminance target Value to 120 (that’s 120 candelas per square meter if you’re interested!).

Set the Target White Point to D65 (that’s 6500 degrees Kelvin – mean average daylight).

Click Next>.

Screen Shot 2013-10-17 at 11.19.44

With the ColorMunki connected to your system this is the screen you will be greeted with.

You need to calibrate the device itself, so follow the illustration and rotate the ColorMunki dial to the indicated position.

Once the device has calibrated itself to its internal calibration tile you will see the displayed GUI change to:

Screen Shot 2013-10-17 at 11.20.26

Follow the illustration and return the ColorMunki dial to its measuring position.

Screen Shot 2013-10-17 at 11.20.49

Click Next>.

Screen Shot 2013-10-17 at 11.21.11

With the ColorMunki in its holder and with the spectrophotometer cover OPEN for measurement, place the ColorMunki on the monitor as indicated on screen and in the image below:

XR-CLRMNK-01

We are now ready to begin the monitor calibration.

Click Next>.

The first thing the ColorMunki does is measure the luminosity of the screen. If you get a manual adjustment prompt such as this (indicates non-support/disabling of DDC preferences option):

ColorMunki-Photo-display-screen-111

Simply turn adjust the monitor brightness slowly until the indicator line is level with the central datum line; you should see a “tick” suddenly appear when the luminance value of 120 is reached by your adjustments.

LCDs are notoriously slow to respond to changes in “backlight brightness” so make an adjustment and give the monitor a few seconds to settle down.

You may have to access your monitor controls via the screen OSD menu, or on Mac via the System Preferences > Display menu.

Once the Brightness/Luminance of the monitor is set correctly then ColorMunki will proceed will proceed with its monitor output colour measurements.

In order for you to understand monitor calibration and what is going on here is a sequence of slides from one of my workshops on colour management:

moncal1

moncal2

moncal3

moncal4

Once the measurements are complete the GUI will return to the screen in this form.

Screen Shot 2013-10-17 at 11.26.29

Either use the default profile name, or one of your own choice and click Save.

NOTE: Under NO CIRCUMSTANCES can you rename the profile after it has been saved, or any other .icc profile for that matter, otherwise the profile will not work.

Click Next>.

Screen Shot 2013-10-17 at 11.27.00

Click Save again to commit the new monitor profile to you operating system as the default monitor profile.

You can set the profile reminder interval from the drop down menu.

Click Next>.

Screen Shot 2013-10-17 at 12.32.58

Monitor calibration is now complete and you are now back to the ColorMunki startup GUI.

Quit or Exit the ColorMunki application – you are done!

Please consider supporting this blog.

Become a patron from as little as $1 per month, and help me produce more free content.

Patrons gain access to a variety of FREE rewards, discounts and bonuses.

Screen Capture logos denoting ColorMunki & X-Rite are the copyright of X-Rite.

Monitor Calibration Devices

Colour management is the simple process of maintaining colour accuracy and consistency between the ACTUAL COLOURS in your image, in terms of Hue, Saturation and Luminosity; and those reproduced on your RGB devices; in this case, displayed on your monitor. Each and every pixel in your image has its very own individual RGB colour values and it is vital to us as photographers that we “SEE” these values accurately displayed on our monitors.

If we were to visit The National Gallery and gaze upon Turners “Fighting Temeraire” we would see all those sumptuous colours on the canvass just as J.M.W. intended; but could we see the same colours if we had a pair of Ray Bans on?

No, we couldn’t; because the sunglasses behave as colour filters and so they would add a “tint” to every colour of light that passes through them.

What you need to understand about your monitor is that it behaves like a filter between your eyes and the recorded colours in your image; and unless that “filter” is 100% neutral in colour, then it will indeed “tint” your displayed image.

So, the first effect of monitor calibration is that the process NEUTRALIZES any colour tint in the monitor display and so shows us the “real colours” in our images; the correct values of Hue and Saturation.

Now imagine we have an old fashioned Kodak Ektachrome colour slide sitting in a projector. If we have the correct wattage bulb in the projector we will see the correct LUMINOSITY of the slide when it is projected.

But if the bulb wattage is too high then the slide will project too brightly, and if the bulb wattage is too low then the projected image will not be bright enough.

All our monitors behave just like a projector, and as such they all have a brightness adjustment which we can directly correlate to our old fashioned slide projector bulb, and this brightness, or backlight control is another aspect of monitor calibration.

Have you done a print that comes out DARKER than the image displayed on the screen?

If you have then your monitor backlight is too bright!

And so, the second effect of monitor calibration is the setting of the correct level of brightness or back lighting of our monitor in order for us to see the true Luminosity of the pixels in our images.

Without accurate Monitor Calibration your ability to control the accuracy of colour and overall brightness of your images is severely limited.

I get asked all the time “what’s the best monitor calibration device to use” so, above is a short video (no sound) I’ve made showing the 3D and 2D plots of profiles I’ve just made for the same monitor using teo different monitor calibration devices/spectrophotometers from opposite ends of the pricing scale.

The first plot you see in black is the AdobeRGB1998 working colour space – this is only shown as a standard by which you can judge the other two profiles; if you like, monitor working colour spaces.

The yellow plot that shows up as an overlay is a profile done with an Xrite ColourMunki Photo, which usually retails for around £300 – and it clearly shows this particular monitor rendering a greater number of colours in certain areas than are contained in the Adobe1998 reference space.

The cyan plot is the same monitor, but profiled with the i1Photo Pro 2 spectro – not much change out of £1300 thank you very much – and the resulting profile virtually an identical twin of the one obtained with the ColorMunki which retails for a quarter of the price!

Don’t get me wrong, the i1 is a far more efficient monitor calibration device if you want to produce custom PRINTER profiles as well, but if you are happy using OEM profiles and just want perfect monitor calibration then I’d say the ColorMunki Photo is the more sensible purchase; or better still the ColorMunki Display at only around £110.

Become a patron from as little as $1 per month, and help me produce more free content.

Patrons gain access to a variety of FREE rewards, discounts and bonuses.

Monitor, Is Yours Up To The Job?

Is Your Monitor Actually Up To The Job?

As photographers we have to take something of a “leap of faith” that the monitor we use to view and process our images on is actually up to the job – or do we?

No – is the short answer!  As a Photoshop & Lightroom educator I try and teach this mystical thing called “Colour Management” – note the correct spelling of the word COLOUR!

The majority of amateur photographers (and a few so-called pros come to that!) seem to think that colour management is some great complicated edifice; or even some sort of “re-invention of the wheel” – and so they either bury their head in the sand or generally “pooh-pooh” the idea as unnecessary.

Well, it’s certainly NOT complicated, but it certainly IS necessary.

The first stage in a colour managed workflow is to ensure that your monitor is calibrated – in other words it is working at the correct brightness level, and the correct colour balance or white point – this will ensure that when your computer sends pure red to your monitor, pure red is seen on the screen; not red with a blue tint to it!

But correct calibration of your monitor is fairly useless if your monitor cannot reproduce a large variation of colour – in other words, if its’ colour gamut is too small.

And it’s Monitor Colour Gamut that I want to look at in this post.

The first thing I’d like you to do is open up Photoshop and go to the Colour Settings – that’s Edit>Colour Settings, or shift+cmd+K on Mac, or shift+Ctrl+K on PC.

Once this dialogue box is open, set it up as follows:

Screen Shot 2013-11-18 at 13.47.30

This is the optimum setup of Photoshop for digital photography as ProPhoto is the best colour space for preserving the largest number of colours captured by your dslr sensor; far better than AdobeRGB1998 – but that’s another story.

If you like you can click the SAVE button and then give this settings profile a name – I call mine ProPhoto_Balanced_CC

Now that you are working with the largest colour palette possible inside Photoshop I want you to go to File>New and created a new 500×500 pixel square with a resolution of 300 pixels per inch with the settings as follows:

Screen Shot 2013-11-18 at 13.58.34

Click OK and you should now have a white square.

Now go to your foreground colour, click it to bring the colour palette dialogue box into view and manually add the following values indicated by the small red arrows:

Screen Shot 2013-11-18 at 14.06.52

The colour will look a little different than it does in the jpeg above.

So now we have a rather lurid sickly-looking green square in the ProPhoto colour space.

Now duplicate the image TWICE and then go to Window>Arrange>3up Vertical and you should end up with a display looking like this:

unconverted

Now comes the point of the exercise – click on the tab for the centre image and go Edit>Convert to Profile and choose AdobeRGB(1998) as the destination space (colour space).

Then click on the tab for the left hand image and go Edit>Convert to Profile and choose sRGB as the destination space.

Here’s the thing – if your display DOES NOT look like this:

MonitorColourDisplay

and all three squares look the same as the square on the left then your monitor only has a small sRGB colour gamut and is going to severely inhibit your ability to process your images properly or with any degree of colour accuracy.

Monitors rely on their Colour Look-up Table or LUT in order to display colour. Calibration of the monitor can reduce the size of the available range of colours in the LUT if it’s not big enough in the first place, and so calibration can indeed make things worse from a colour point of view; BUT, it will still ensure the monitor is set to the correct levels of brightness and colour neutrality; so calibration is still a good idea.

Laptops are usually the best illustration of this small LUT problem; normally their display gamuts are barely 8bit sRGB to begin with, and if calibration drops the LUT to below 8bit then the commonest problem you see is colour banding in your images.

If however, your display looks like the image above then you’re laughing!

Why is a large monitor colour gamut essential for digital photography?  Well it’s all to do with those colour spaces:

Screen Shot 2013-11-18 at 14.56.11

If you look at the image above you’ll see the three standard primary working colour spaces of ProPhoto, AdobeRGB(1998) and sRGB overlaid for comparison with each other.  There’s also a 4th plot – this is the input space of the Canon 1Dx dslr – in other words, it encompasses all the colours the sensor of that camera can record.

In actual fact, some colours can be recorded by the camera that lie OUTSIDE even the ProPhoto colour space!

But you can clearly see that the Adobe space looses more camera-captured colour than ProPhoto – hence RAW file handlers like Lightroom work in Prophoto (or to be more strictly true MelissaRGB – but that’s yet another story!) in order to at least preserve as many of the colours captured by the camera as possible.

Even more camera colour is lost to the sRGB colour space.

So this is why we should always have Photoshop set to a default ProPhoto working space – the archival images we produce will therefore retain as much of the original colours captured by the camera as possible.

If we now turn our attention back to monitors – the windows on to our images – we can now deduce that:

a. If a monitor can only display sRGB at best, then we will only be able to see a small portion of the cameras captured colour.

b. However, if the monitor has a larger colour gamut and a bigger LUT both in terms of colour spectrum and bit depth, then we will see a lot more of the original capture colours – and the more we can see then more effectively we can colour manage.

Monitors are available that can display the Adobe colour gamut, indeed quite a few can display more colours – but if you are on a tight budget these can seem more than expensive to say the least.

A good monitor that I recommend quite a lot – indeed I use one myself – is the HP LP2475W, well worth the price if you can find one; and with a bit of tweaking it will display 98%+ of the AdobeRGB colour space in all three primary colours and even some of the warmer colours that are only ProPhoto:

Screen Shot 2013-11-18 at 15.40.07

The green plot is the Adobe space, the red plot is the HP LP2475W display colour space.

So it’s a good buy if you can find one.

However, there’s a catch – there always is! This monitor relies on the LUT of the graphics card driving it – plugged into the modest 512Mb nVidea GT120 on my Mac Pro it is brilliant and competes at every level with the likes of Eizo ColourEdge and NEC Spectraviews for all practical purposes.  But plugged into the back of a laptop then it can only reproduce what the lower specification graphics chips can supply it with.

So there we have it, a simple way to test if your monitor is giving you the best advantage when it comes to processing your images – food for thought?

Become a patron from as little as $1 per month, and help me produce more free content.

Patrons gain access to a variety of FREE rewards, discounts and bonuses.