ColorAnt | Evaluate

Evaluate - Proof Evaluation

Evaluation of Proof Measurement Data

Evaluate – Proof Evaluation

The Evaluate tool can be used to check whether the proof measurement data from a media wedge fulfills the requirements for a contract proof according to ISO 12647-7 or a validation print according to ISO 12647-8.

In addition, a PSD evaluation can be performed using two different evaluation methods: “Side-by-Side” or “Media Relative”.

Moreover, the Evaluation Method G7 gray balance allows the measurement data to be checked for G7® conformity.

Finally, a fully detailed report can be created with a pass/fail indicator.

Notes

  • The Proof Evaluate tool supports all color spaces including Multicolor and spot colors. It is a powerful addition to ZePrA’s proofing feature, as it allows you to use the reference files of the dynamic media wedges created by ZePrA for proof evaluation.
  • For redundant measurement values, the median is determined and all duplicates (i.e., all patches with identical DCS values) are removed before evaluation.
    This procedure prevents duplicates as well as outliers from unjustifiably influencing the proof evaluations.
  • The Evaluate tool supports all color spaces as either reference data or reference ICC profile. In addition, it checks whether the selected wedge is actually suitable for evaluation and displays a corresponding message.
  • The Evaluate tool is available from ColorAnt L.

The Evaluation tab immediately shows the categories related to the chosen standard, the deltas to the reference, and a score with either a ✓ (passed) or an ✕(failed).

An overall score indicates if the proof has passed or failed.

There are two ways of selecting your reference:  

  • Choose reference data: This drop-down menu contains all data loaded under Data Sets that fit the selected proof measurement data as a reference, which means the number of patches and the color space must match. Select the reference that you want to compare with the selected media wedge measurement data. If dynamic media wedges were used in ZePrA, the corresponding reference data can be used for the proof evaluation in ColorAnt.

    Using reference data from ZePrA:
    1. Open the reference file of the ZePrA configuration in ColorAnt. It is located in ZePrA’s Report folder of the corresponding queue.
    2. Select Measure to measure the media wedge in the proof printout
    3. Open the resulting measurement file and click the Evaluate button.
    4. Select the original reference file from ZePrA under Choose reference data in the Proof Evaluation window.
  • Choose reference ICC profile: This drop-down menu contains all ICC profiles that fit the selected proof measurement data as reference in terms of the same color space. Choose the reference ICC profile that you want to compare with the selected media wedge measurement data.
    Note: The ICC profile is used to create virtual reference values (absolute colorimetric). Depending on the accuracy of the ICC profile, the quality of the reference data can vary from very exact (e.g., CMYK profiles created by CoPrA) to less exact (e.g., small Multicolor profiles).  

Evaluation method: Select a method to either evaluate a Contract Proof according to the ISO 12647-7 standard, a Validation Print according to the ISO 12647-8 standard, to evaluate your data according to Fogra’s PSD standard (ProcessStandard Digital), or to check the measurement data for G7® conformity. The PSD standard is based on the tolerances defined by Fogra and provides guidelines to increase process stability in digital printing. Further information can be found on the Fogra website.

ISO 12647-7 (Contract Proof 2016): For the evaluation of a binding contract proof use this method. 

ISO 12647-8 (Validation Print 2021): Checks the conformance of printing systems that produce a hard-copy validation print, directly from digital data, which is intended to simulate the expected appearance of material printed per a characterized printing condition. The method considers the latest tolerances published in 2021.

G7 gray balance: This method checks the measurement data for G7® conformity to ensure accurate and consistent color reproduction. G7® is an internationally recognized method for calibrating printing presses and proofing systems.

Notes

  • Recently, other visualizations of the final printed product have found a place in the printing/proofing workflow because designers and print buyers prefer not to go to the expense of using an ISO 12647-7 compliant contract proof any earlier in the process than necessary. In many situations, participants in the workflow require a hardcopy visual reference of lesser quality than a contract proof. In the past, those prints varied widely in quality and were often referred to as design proofs, concept proofs, layout prints, etc. That quality level is here being referred to as a validation print.
  • The All Patches ratings do not include Boundary Patches for wedge evaluations.
  • Wedge evaluation: For small charts with less than 150 patches, such as Media Wedges, all Boundary Patches are omitted.
  • Chart evaluation: For larger charts with more than 150 patches, such as the IT-8, the Boundary Patches are taken into account.

PSD Evaluation

The PSD reflects the different customer requirements for the degree of color match with three different quality levels, the quality types A, B and C. Here, A represents a better approximation than B, which in turn is better than C. The overall rating depends on the lowest rated Category. If a value exceeds the tolerance limit, a red X indicates that the evaluation has failed. Quality types A to C thus indicate that all values are within the respective tolerances and that the evaluation has passed (shown in shades of green).

This gradual evaluation of the quality with regard to color reproduction can be achieved with two different evaluation methods: Side-by-Side or Media Relative.

PSD Evaluation (FOGRA PSD 2022 Side-by-Side): Side-by-side is a long-established method based on simultaneous and immediately adjacent color matching. The deviation tolerances apply to the comparison of the target values, defined by the color reference, and the measured values of the OK sheet.

From the Fogra PSD Handbook: Deviation tolerances for Side-by-Side reproductions. Version: PSD 2022

From the Fogra PSD Handbook: CIEDE2000 tolerances for spot colors. Version: PSD 2022

PSD Evaluation (FOGRA PSD 2022 Media Relative): The media-relative evaluation consists of two steps. First, the similarity between the reference and the current output color gamut is checked using the white and black points. A similarity is mandatory to perform the colorimetric evaluation in the second step.

From the Fogra PSD Handbook: CIELAB tolerances for gamut differences to check if media-relative is applicable. The color differences for the white color are very similar when using ΔE ab or CIEDE2000. The CIEDE2000 tolerances shall take precedence. CIELAB 1976 color differences are given in brackets. Version: PSD 2022

The calculation of the media-relative CIELAB color values only takes place if the criteria specified for the first step are met. They are the starting point for the final color evaluation based on all control patches in the second step.

From the Fogra PSD Handbook: Deviation tolerances for media-relative reproductions. Version: PSD 2022

Note: Reliable results can only be achieved with absolute colorimetric measurement data, so please do not use relative or scaled (e.g., converted with perceptual rendering intent) measurement data.

Specify spot colors: When evaluating Multicolor measurement data, the additional colors can be evaluated as process colors or as spot colors. In most cases, with typical Multicolor media wedges, all colors are process colors, but with ZePrA-created dynamic media wedges, additional spot colors may also be included in the file.
Specify spot colors opens a dialog where you can define whether a color is included in the selected Evaluation Method calculation as a Process color or as a Spot color.

By default, all channels of Multicolor data are defined as process colors and included in the evaluation All Patches.

However, if spot colors are present and should not be treated as process colors, e.g., in the case of dynamic media wedges in ZePrA, they can be defined as spot colors. In this case, they are not included in the All Patches evaluation, but are evaluated separately and displayed in a separate Spot color evaluation line.

Note: The button for the Specify spot colors dialog is shown for Multicolor data only.

Report

The available input fields depend on the selected Evaluation method. Enter the required information according to the selected ISO standard.

Save Report: Saves the report in the location and format (PDF, HTML, XML) specified in Settings.

The report contains all the information that you have entered, the summary from the evaluation dialog, a list of all patches with their names or IDs, the device color space, the Lab reference values, the Lab measurement value and the delta.

Label

Allows you to print a label with the evaluation results directly from within ColorAnt. The tab shows a preview of the label to be printed. The label contains the data entered in the Report tab and a table with the data from the Evaluation tab. It also indicates if the print is Accepted or if the evaluation has failed (X) and provides space for a signature.

Note: The label layout is optimized for DYMO 99012 labels (format 89mm x 36mm). For other formats, adjustments may be necessary to achieve optimum results.

Video Tutorial

How to Use the Proof Evaluation Tool in ColorAnt in combination with ZePrA

Learn step-by-step how to use the Proof Evaluation tool in ColorAnt for the evaluation of a proofing media wedge created with ZePrA. In this example, we will be demonstrating the special feature of ZePrA to create a dynamic media wedge using process and spot colors and how to use the supplied reference data from ZePrA for evaluation of a Contract Proof.

ZePrA | Push 2 ZePrA

Push-2-ZePrA

Process PSD files directly from Photoshop

What is Push-2-ZePrA ?

Push-2-ZePrA is an Adobe Photoshop extension that allows color converting an image file selected in Photoshop with ColorLogic’s color server ZePrA from Photoshop. Depending on the color server settings high quality color conversions with DeviceLink profiles will be performed leading to better color rendering of images than typical color conversion with Photoshop. Even spot colors can be converted if the selected ZePrA configuration is set up accordingly. The converted file will be opened up in Photoshop so that you do not need to leave Photoshop in order to get the best possible color converted images.

Push-2-ZePrA System Requirements

System Requirements for Push-2-ZePrA version 3

  • macOS 10.15 and higher
  • Windows 10 and higher
  • Adobe Photoshop CC 2021 and higher.
  • ZePrA 11
  • Supported file formats: TIFF, JPEG, PSD and PSB
  • Unsupported file formats: PNG, PDF and EPS
  • On macOS systems with M1/M2 Apple Silicon processors make sure that you start Photoshop via Rosetta. The Push-2-ZePrA extension does not run natively on M1/M2 chips.

System Requirements for Push-2-ZePrA version 1 and 2

  • macOS 10.13 and higher
  • Windows 8 and higher
  • Adobe Photoshop CC 2017 and higher.
  • Supported file formats: TIFF, JPEG, PSD and PSB
  • Unsupported file formats: PNG, PDF and EPS
  • On macOS systems with M1/M2 Apple Silicon processors make sure that you start Photoshop via Rosetta. The Push-2-ZePrA extension does not run natively on M1/M2 chips.
  • ZePrA 9 and higher/Push-2-ZePrA v2 and higher: The 2nd edition of Push-2-ZePrA has network capability. This eliminates the need for ZePrA to be installed on the same computer as Photoshop.

Note: Push-2-ZePrA is integrated with a 1-client license in ZePrA XL and XXL. Additional 5-client or 10-client multi-user licenses can also be purchased. For ZePrA Entry, Basic and L, the Push-2-ZePrA Photoshop extension single and multi-user licenses can be purchased as add-ons.

Installation
  1. Use the installer for macOS or Windows for your respective operating system.
  2. Close Photoshop before installation and follow the easy-to-use installer.
  3. Once installed, start Photoshop, go to Window/Extensions and select Push-2-ZePrA to open the extension.

Note: The installer on macOS systems will take an additional step to prepare Photoshop. Hence Photoshop must be closed before installation. The warning message is displayed twice. Just click the Allow button twice to install.

Using Push-2-ZePrA locally

Using Push-2-ZePrA locally

Configuring the Push-2-ZePrA clients in Photoshop:

  1. Once the Push-2-ZePrA extension is installed, start Photoshop, go to Windows/Extensions and select Push-2-ZePrA to open the extension.
  2. Click the Gear icon. There are two ways to connect to the ZePrA server: locally or remotely. If your Photoshop/Push-2-ZePA installation is on the same computer as the installed ZePrA color server you should always prefer the ZePrA Local option as this is much faster than communicating via the network. Click ZePrA Local.

  3. Under ZePrA Path navigate to the ZePrA.app on macOS or zcmd.exe on Windows and select it.
  4. Define your Local Output Path (where converted files are to be saved) and click the Home button. You can then immediately use the extension.

Using Push-2-ZePrA locally

When ZePrA is installed on the same computer as Photoshop:

  1. In Photoshop, open the image to be color converted.
  2. Click on the Push-2-ZePrA extension.
  3. On the Home tab select a ZePrA Configuration from the drop-down menu. The drop-down list will show all the configurations set up in ZePrA.
    Note: A search option is available here, where any number and letter can be entered and only the configurations containing these numbers and letters are listed in the drop-down menu below. This makes it easier to search for specific configurations, especially if the list of configurations in ZePrA is very long.
  4. Choose a configuration that fits your requirements in terms of Target Color Space and retaining of Photoshop Layers. This information is shown below the drop-down menu and picked from the selected configuration.
  5. Click Convert.
  6. After a few seconds, the progress will be displayed, and the converted file will be opened up in Photoshop.
  7. Output folder for local use: Converted files are always saved in the same location as the original file and the configuration name will be appended to the original file name.
    Notes: If the original file has been edited or copied in Photoshop without saving, a temporary file needs to be created by Push-2-ZePrA. The edited and the converted temporary files are saved in the output folder defined under Local Output Path.
    If the original file is located in a read-only folder, the user will be asked if the converted file is to be saved in the output folder defined under Local Output Path.

Note: ZePrA’s Command Line Interface (CLI) is used for the conversion but not the ZePrA application itself. Therefore, you won’t find any of the images that have been converted via the Push-2-ZePrA extension in ZePrA’s Overview or hot folders.

    Using Push-2-ZePrA over the network

    Connecting Push-2-ZePrA with ZePrA over the network

    Note: Requires ZePrA 9 or higher and Push-2-ZePrA v2 or higher.

    Push-2-ZePrA is network capable from version 2. This eliminates the need for ZePrA to be installed on the same computer as Photoshop.

    ZePrA 9 and higher have an integrated Push-2-ZePrA remote server, while the Push-2-ZePrA extension acts as a client application that can access ZePrA from a remote Photoshop installation over the network.

    Therefore, several users who have the extension installed in their Photoshop application can remotely access the same ZePrA server. The Photoshop clients can thus be used on different computers, but also under different operating systems than the ZePrA server.

    Establishing a connection

    Configuring the ZePrA server:

    1. Open the Server Settings from the Tools menu in ZePrA.
    2. Specify the IP address of the computer ZePrA is running on and set a Port. See your system administrator for IP and port information. You will need to enter both the IP address and the port number in the Push-2-ZePrA extension on all client computers.

    3. Click Start to activate the server. The Status changes to Server is running and the License Status indicates the number of licenses in use as well as the number of available licenses.
    4. Stop closes the server and the extensions will no longer work. Closing ZePrA does not stop the server service but shutting down the computer will. So when restarting the computer make sure to restart the ZePrA server in the Server Settings dialog so that the extensions can access it.

    Note: Under macOS the IP address of the computer can be found in the System Preferences/Network settings. Under Windows the IP address can be found under Settings > Network & Internet > Status > View hardware and connection properties.

    After a ZePrA update, stop the server and restart both ZePrA and the server. This way the newest version of the server will be used.

    Configuring the Push-2-ZePrA clients in Photoshop
    1. Install Push-2-ZePrA and open it in Photoshop.
      Note: On Macs with Apple Silicon M1 chip make sure to start Photoshop with Rosetta – see System Requirements.
    2. Click the Gear icon.
    3. There are two ways to connect to the ZePrA server: locally or remotely. If your Photoshop/Push-2-ZePA installation is on the same computer as the installed ZePrA color server you should always prefer the ZePrA Local option as this is much faster than communicating via the network. If your Photoshop/Push-2-ZePA installation is on a different computer, use the ZePrA Remote option.

    4. To use the ZePrA Remote option, enter the previously defined ZePrA server settings (Server IP Address and Server Port Number) under ZePrA Remote and click the Connect button under Test Connection. The connection status is displayed.
    5. When the connection is successfully established, define your Local Output Path (where converted files are to be saved) and click the Home button. You can then immediately use the extension.

    Note: If all available licenses are linked with the ZePrA server, additional Photoshop extension users will not be able to connect to the ZePrA server. The licenses are linked to the ZePrA server on a first come first served basis.

    Note: In order to use the Photoshop extension, the ZePrA remote server must be running. Once the server has been started in ZePrA, it will run even if the ZePrA application is closed later on. Only when the computer is shut down, the server is also shut down and must be restarted in ZePrA after the computer is restarted.

    Use the Question mark icon to access the Push-2-ZePrA online help page, and the Exclamation mark icon to get the version numbers of the extension and the ZePrA Remote server.

    Using Push-2-ZePrA remotely

    When ZePrA is accessed over the network:

    1. Open up an image in Photoshop to be color converted.
    2. Click on the Push-2-ZePrA extension.
    3. Select a ZePrA Configuration from the drop-down menu. The drop down list will show all the configurations set up in ZePrA.
      Note: A search option is available here, where any number and letter can be entered and only the configurations containing these numbers and letters are listed in the drop-down menu below. This makes it easier to search for specific configurations, especially if the list of configurations in ZePrA is very long.
    4. Choose a configuration that fits your requirements in terms of Target Color Space and Photoshop Layers retaining. This information is shown below the drop-down menu and picked from the selected configuration.
    5. Click Convert.
    6. After a few seconds, the progress will be displayed, and the converted file will be opened up in Photoshop.
    7. Output folder for network use: Converted files and temporary files are always placed in the output folder defined under Local Output Path and the configuration name will be appended to the original file name.
      Note: If the original file is located in a read-only folder, the user will be asked if the converted file is to be saved in the output folder defined under Local Output Path.

    Note: ZePrA’s Command Line Interface (CLI) is used for the conversion but not the ZePrA application itself. Therefore, you won’t find any of the images that have been converted via the Push-2-ZePrA extension in ZePrA’s Overview or hot folders.

    Recommendations and Troubleshooting

    Best Practices

    For image conversions, we recommend setting up Direct Color Conversion configurations in ZePrA with the help of the Auto Setup Wizard. With a direct conversion from the image color space to the Target Color Space, double conversions are avoided. It is not recommended to use a Normalize and Convert queue as this can lead to converting the image two times (a double conversion – from the image color space to the Document Color Space and then to the Target Color Space), which typically is not wanted for image conversions.

    For any changes in terms of PSD or TIFF file layers handling, color conversion or spot color conversion, please adjust the appropriate ZePrA configuration in the ZePrA color server. The Push-2-ZePrA Photoshop extension uses the configurations, but editing configurations is not supported.

    Error Handling

    When working with the Push-2-ZePrA extension potential issues might happen:

    1. When updating Photoshop to a newer version, the Push-2-ZePrA extension may no longer be loaded. In this case, it is recommended to re-install the Push-2-ZePrA extension.
    2. The Push-2-ZePrA Photoshop extension version 3 is only executable with ZePrA 11.
    3. The maximum file size that can be processed via the remote connection using the zcmdServer of ZePrA 10 is 512 MB. Larger files can be processed directly via ZePrA Queues.
    4. The zcmdServer included in ZePrA 11 allows the processing of image files up to a size of 2 GB.
    5. Please do not use the zcmdServers of ZePrA 10 and 11 at the same time. Make sure the server in ZePrA 10 is stopped (click the Stop button in the Server Settings dialog). After that open the Server Settings dialog in ZePrA 11 and click on Start to activate the zcmdServer of ZePrA 11.
    6. Select the proper file for conversion: When several images are open in Photoshop keep in mind that only the selected, active document will be converted with Push-2-ZePrA.
    7. Incomplete conversions: When clicking the Convert button it may take a few seconds until the image is converted. During processing (the progress will be displayed), do not close the Push-2-ZePrA extension nor minimize Photoshop. This will immediately stop the conversion.
    8. Restricted folders and locations: A warning message appears when trying to save a file in a restricted location. If the selected location (folder) is read-only (for example, the application folder of an operating system), a warning message is displayed prompting you to cancel the conversion or save the converted file to the Local Output Path.
    9. Troubleshooting job warnings: An error message with the selected configuration appears. In such a situation, check the corresponding configuration in the ZePrA application and check for the cause of the error. It may be that the image file and the setting in the configuration do not match. In such a case, it is suggested to convert the image file in the ZePrA application with the same configuration used in the Push-2-ZePrA extension. The same job warning message may show in ZePrA. Troubleshoot the issue and change the settings in the ZePrA application, until the file conversion works as desired. Once the configuration has been saved in ZePrA go back to the Push-2-ZePrA extension, close it and reopen the extension to update the list of configurations and settings and convert the file in Photoshop again.
      Note: Push-2-ZePrA supports the same image file formats as ZePrA, e.g. TIFF, JPEG, PSD and PSB. Unsupported file formats, such as PNG, PDF or EPS, will generate file format errors.
    10. Changes and updates to configurations: When changes or updates to ZePrA configurations have not been applied in the Push-2-ZePrA extension, make sure that the edits have been saved in ZePrA before heading to the Photoshop extension. Then close the extension and start it again so that it refreshes the list of configurations and their settings.
    11. Support for prior ZePrA versions: ZePrA versions prior to v9 are not supported. The extension may show the settings of configurations from older ZePrA versions, but will not convert files. We do not recommend selecting prior ZePrA versions with the extension and will not be supporting prior versions in future releases.
    12. Avoid special characters in configuration names: characters such as | < > * ? / \\ : in configurations names with ZePrA. While ZePrA will handle such characters the Push-2-ZePrA extension does not.

    ColorAnt | Color Editor

    Color Editor

    Manual editing of patches and best possible spot color conversion

    Color Editor

    The Color Editor tool covers several applications:

    1. Best possible conversion of colors (usually spot colors) using ICC profiles.
    2. Saving spot colors converted with Color Editor in various color formats for use in other applications.
    3. Manually changing color names.
    4. Manually changing Lab values and device values assigned to a color patch.
    5. Adding or removing color patches.

    Overview of the Color Editor

    On the left side is a table with the colors of the loaded measurement file. It contains the following information:

    • Color: Name of the color
    • Measurement: Measured color values in Lab (spectral values are retained but shown as Lab)
    • Current (DCS): Specifies the current device values. Displays the device values after applying the settings and functions on the right side.
    • Profile (DCS): Displays the device values resulting from a conversion using the selected profile on the right-hand side.
    • dE00 (Current): Displays the absolute colorimetric DeltaE 2000 values, which result from the measured Lab values and the current device values.

    Single, multiple or all color values can be selected in the table and then edited with the tools on the right. The color table can be sorted by Color or dE00 (Current) by clicking on the column headings.

    Below the table are two buttons to Add or Delete patches as well as the Invert Selection button.

    Invert Selection: Provides a quick and easy way to reduce a large number of displayed colors of a large data set to only a few colors. Simply select the desired color patches, click Invert Selection followed by the Delete button. Now you are working on your individual color selection.

    Search: Helps to find and edit specific colors of large data sets. Type in the name of the desired color and the list will show only colors with those name components.

    Tip: Combine the Search with Invert Selection

    If, for example, you would like to edit all colors with the name component ‘Red’ of a Pantone library as a small list, enter ‘Red’ in the Search.

    Select the colors found, then delete the search term and click on Invert Selection.

    By pressing the Delete button, only the colors with the name component ‘Red’ remain in the list. All others are removed.

    Spot Color Report: Generates a PDF report that can be used to check the conversion of spot colors before actually printing.

    The spot color report shows the results achieved by a spot color conversion in relation to deltaE00, deltaE76, and the separation into process colors. This allows the accuracy of spot color conversions to be checked before processing or printing, and to determine in advance how spot colors (e.g., Pantone® or HKS and other colors) of specific PDF and image files are converted.

    A spot color library with multiple spot colors such as Pantone, HKS or other colors can be color converted with a target ICC profile to check for the resulting process color breakdowns (DCS). The report provides the color name for each spot color, the process color breakdowns, the expected deltaE2000 and deltaE76 values, and an overall evaluation in terms of average and maximum deltaEs.  It also includes the median and how many colors are reproduced within a tolerance of 1 and 2.5 dE00 as well as within the user-defined dE00 limit.

    The report also contains an information column that shows, among other things, whether a color is out of gamut.

    Measurement Information

    Shows the Name, the measured Lab value (CIE) and the current device value (DCS) including the color space for the selected color field.


    Color Conversion Settings

    After selecting an ICC Profile, first the DCS values are calculated using the Absolute Colorimetric rendering intent.

    However, these are not always the best possible color values, neither with regard to the smallest DeltaE nor to printability.

    Therefore, various optimization modes are available in the Color Conversion Settings, which can be applied to the colors selected on the left side of the table.

    It is also possible to apply different modes and colors to individual colors.

    Define the Profile and the Mode for the conversion of the measured values. Six modes are available for the color conversion:

    1. Precise Match – Proofing
      Spot colors are reproduced as accurately as possible on a proof printer. This method is not suitable for production as it may use all process colors for spot color simulation to achieve the best result (based on DeltaE 2000). The full tone is calculated with the aim of achieving the smallest possible DeltaE 2000 value. No channel reduction or print optimization is applied.
    2. Visual Match – Utilize More Channels
      Produces visually the best possible conversion with high color accuracy and with excellent printing properties. Full tones of spot colors are converted with as few channels as possible and still remain colorimetrically accurate. This method is suitable for digital printing, large format inkjet printing or offset printing with a fine screen ruling and good register accuracy.
    3. Use the least Amount of Channels possible
      A good method to convert full tones of spot colors with a minimum number of channels and still get colorimetric accurate results. Choose this method for packaging printing where pure colors are desired. One or two-color combinations are also included in the search for the best possible color combination.
    4. Use one Output Channel only
      Useful for print packaging production. The spot colors used for text and bar codes will be converted using a maximum of one process color.
    5. Use a Maximum of two Channels
      Uses one or two output channels. Best for one or two process colors providing the best colorimetric match selected for each spot color automatically. The results are very clean separations that are easily printed, but not necessarily very exact in colorimetric terms. It is recommended to only use this function for individual, manually created spot colors.
    6. Use a Maximum of three Channels
      Uses one to three output channels. Similar to the calculation method Use the least Amount of Channels possible. No more than a maximum of three channels should be used. Choose this method for packaging printing, where the purest possible colors are to be produced and not more than three process colors for spot color conversion must be used. Single-color and two-color combinations are also included in the search for the best color combination.

    dE00 Limit: Colors exceeding the set threshold are marked with a warning symbol.


    Optimize Output Values

    Displays the current device values for the selected ICC profile.

    By clicking on dE76 or dE00 the deltaE can be minimized for each color.

    Automatic: Uses the selected ColorLogic calculation mode, typically reducing the number of channels for better printability.
    Note: By deactivating the checkboxes for the color channels, the values displayed in the number fields are fixed (for example 0% or 100%) so that they are not changed when applying dE76 or dE00. However, this does not apply to Automatic, here, all channels are always taken into account.

    Revert: Undoes all changes and reverts back to the original DCS values initially calculated using the selected ICC Profile.

    Color Information

    Displays various information about the selected color:

    Reference: Measured Lab value of the color
    Profile: Shows the color value calculated with the process colors of the target profile
    Current: Optimized color value of the process colors
    dE76: Expected color difference in DeltaE 76
    dE00: Expected color difference in DeltaE 2000
    Paper white simulation: Considers the coloration of the substrate for the target color space
    Note: It is recommended to activate the Paper white simulation.
    Divided color preview: The divided color preview shows how the original color (upper bar), the non-optimized color by means of the profile (left lower square), and the optimized color (right lower square) would look like when printing. The color preview is displayed in true colors on a calibrated and profiled monitor.

    Comparison of original color (Reference), non-edited color (Profile) and edited color (Current)

    Note: A warning message is displayed below the color preview when one of the three colors is out of the monitor’s gamut.

    After editing the measured values, a file with the optimized device and/or measured values is created by clicking on Start.

    Note: The Color Editor tool is grayed out if the file loaded under Data Sets does not contain any measured values. Once a single measurement file has been selected, it can be opened in the Color Editor (multiple files cannot be opened simultaneously).

    Color Editor Use Cases

    Example: Best possible conversion of (spot) colors

    Measurement data from spot colors loaded into ColorAnt can be converted into any color space using the Color Editor and ICC profiles. All color spaces including RGB, CMYK and Multicolor are supported.

    Note: The Conversion of Multicolor profiles requires an L license.

    To convert a spot color to RGB, CMYK or Multicolor, follow these steps:

    1. Load the measurement data file including individual full tone spot colors (for example a spot color library as CxF file) under Data Sets in ColorAnt, select the file and then click Color Editor.
    2. Under Color Conversion Settings, select the desired ICC Profile from the drop-down menu.
    3. The table on the left side fills with the device values. Initially, the device values are identical for Current (DCS) and Profile (DCS), since no optimizations have yet been made.
    4. Select the color you would like to optimize from the table and a Mode under Color Conversion Settings.
      The calculation mode specifies how ZePrA should convert one or more spot colors to the target color space.
    5. Choose one of the three modes described above. Under dE00 Limit, enter the threshold value in DeltaE 2000 from which colors in the table are to be marked with a warning symbol.

    6. The control panel Optimize Output Values shows the device values (Current DCS) calculated with the selected ICC profile. The calculation is always absolute colorimetric.

    7. Now click on Automatic to convert the colors using the selected calculation mode. Alternatively, perform the calculation according to DeltaE76 (dE76) or DeltaE 2000 (dE00). However, these two methods do not include ColorLogics high-quality calculation modes. The device values are displayed immediately after application of the calculation.

      By clicking on Revert the changes can be undone.
    8. The Color Information panel shows the measured Lab value of the color under Reference, the color value calculated with the process colors of the target profile under Profile and the optimized color value under Current. Additionally, the expected color difference is displayed in dE76 (DeltaE 76) and dE00 (DeltaE 2000). Activating the checkbox Paper white simulation takes the coloration of the substrate for the target color space into account. The calculation of the Lab values for Current and the color distance (DeltaE) are performed accordingly.
      Note: It is recommended to activate the Paper white simulation.
      Divided color preview: The divided color preview shows how the original color (upper bar), the non-optimized color by means of the profile (left lower square) and the optimized color (right lower square) would look like when printing. The color preview is displayed in true colors on a calibrated and profiled monitor.

      Comparison of original color (Reference), non-edited color (Profile) and edited color (Current)

    9. If you want to make fine adjustments, manually optimize the percentages in the Optimize Output Values control panel and see the effects directly under Color Information.
    10.  If you are satisfied with the optimization, continue optimizing more colors. Optimized colors are updated directly in the table. With a click on Start the editing is completed using the device values shown under Current (DCS) and the dialog will close. Please note that colors that have not been optimized will only be converted using the normal profile conversion and may therefore not achieve the best possible result.

    Specifics

    • If you would like to optimize several or all colors in the table at once, select the desired colors and click on the desired calculation (Automatic, dE76 or dE00).
    • If two or more colors are selected, device and color values are grayed out in the panels Optimize Output Values and Color Information.
    • If a file previously optimized with an ICC profile in the Color Editor is re-opened in Color Editor, the previously used ICC profile is preselected automatically.
    • If you change the ICC profile, typically, the device values have to be recalculated. To do so, activate the checkbox Recalculate DCS values and confirm with OK.

    Confirm recalculation of the DCS values

    Example: Saving color-converted spot colors to other formats
    Spot colors converted with Color Editor can be saved in various color formats supported by ColorAnt and used in other applications.

    •    CxF or CxF/X-4 for use in many modern applications
    •    Adobe Swatch Exchange (ASE) for use in Adobe Illustrator and InDesign
    •    ACO for use in Adobe Photoshop
    •    ICC Named Color Profiles for use in programs that support this special ICC format.

    The complete list of supported formats can be found here.

    Note: Spot colors converted with Color Editor contain the original color values (Lab or spectral values) and the optimized device values for the selected ICC profile.

    Example: Manual Editing

    The Color Editor also allows to manually change color patch names or color names, to manually change the measurements and device values associated with a color patch, and add or remove individual color patches. Make the appropriate changes in the topmost control panel Measurement Information.

    Under Name change the name of (spot) colors or color patches of test charts.

    Under
    CIE edit the measured values of the color, under DCS edit device values (if present). Typically, DCS values are not available in a pure spot color measurement file.

    Using the buttons below the table (Add, Delete), selected colors can be removed or one or more colors can be added. Added colors are placed at the end of the table. A default name and a medium gray are preselected, which can be changed under Measurement Information as required.

    Specifics

    • Measurements of profiling test charts often have no name designations. For such measurements, the Color Editor automatically adds an identifier, for example #1 for the first patch.

    • Spectral measurement data can also be edited in the Color Editor. They are then displayed as Lab values with D50/2 degree standard observers. In the final file, however, the spectral values are preserved.
    • If the CIE values of spectral measurements are edited as Lab values, the spectral properties of the color are retained.
    • We recommend not to change or optimize DCS values in test charts if the data is used for profiling purposes.
    • When selecting an ICC profile, typically, the device values don’t have to be recalculated. Deactivate the checkbox Recalculate DCS values and confirm with OK.

    Recalculating colors without changing the DCS values

    CoPrA | User Interface

    Main Window

    Access CoPrA’s functions from one central location

    Special Features

    Profile search in drop-down menus
    All profile drop-down menus function like search fields. Simply type in some letters of the desired profile and only those profiles containing these letters will be shown in the list. To select a profile simply click on it.

    Alternatively you may open the drop-down menu with the arrow on the right and select a profile from the full list as usual. Right-clicking on the arrow displays the most recently created ICC profiles available for selection from the list.

    Loading data files
    Load opens and displays existing measurement data files.
    A right click on Load opens a list with recently used files. Selecting an entry in the recently used files list while pressing the CMD key takes you to the folder containing the file.
    Alternatively, drag and drop the data into the window to extract and view the data.

    Context menus
    A right-click on an entry in a list or table opens a context menu with useful tools specific to the respective table or list content. This is especially true for the Profile Manager, where the context menu contains many interesting features.

    Next and Back buttons
    The two buttons Next and Back at the bottom of most windows allow navigating within tools.

    Notifications
    CoPrA contains a notification message service (similar to ZePrA’s Troubleshooting) that allows multiple messages to be displayed at the bottom of the window. If more than one notification or warning is available, this is shown in the icons with the number of warnings. When clicking on the icon or the warning text, all warnings are shown.

    Sidebar

    Sidebar

    The controls to configure and use CoPrA can be found in the Sidebar. Clicking on the Home icon at the left of the window opens the Sidebar which allows a quick selection of the desired tools.

    To launch a specific module, click on the corresponding button of the Sidebar. The colored bar of the upper left corner under Color Profiling Application indicates the active module.

    Printer Profiling

    New Printer Profile

    Create printer profiles 

    Update Profile

    Update profiles using optimized measurement data

    DeviceLink Profiling

    DeviceLink

    Create DeviceLink profiles from standard ICC profiles

    Editing

    Create DeviceLinks using individually modified test charts

    SaveInk

    Create ink saving DeviceLink profiles

    Iterate

    Improve DeviceLink profiles

    Linearization

    Optimize primary color gradations

    Recalculate

    Recalculate DeviceLink profiles with a different profile

    Tools

    Image Conversion

    Convert image files for profile evaluations

    Profile Manager

    Manage profiles in one convenient place

    Batch Overview

    Monitor and manage profiling jobs or reports

    Menu Bar

    CoPrA

    CoPrA (macOS only): Allows access to the dialogue About (see below), Preferences and Services and quits CoPrA.

    Preferences: Define CoPrAs settings, such as the preferred starting page, overwriting of preview profiles or report settings.

    Detailed Information can be found here.

    Navigation

    Navigation (Windows only): In this menu, change the Preferences and select CoPrA’s various modules (the modules can also be accessed via the sidebar). The menu also shows the shortcuts for the individual modules.

    Navigation (macOS only): Select CoPrA’s various modules (the modules can also be accessed via the sidebar). The menu also shows the shortcuts for the individual modules.

    Tools

    Import Settings: Import CoPrA settings to the preset menu

    Export Settings: Export CoPrA’s settings for backup or to load in another system

    Cleanup Settings: All settings found under the entry [EDITED] will be deleted automatically when using the command Cleanup settings from the Tools menu.

    Open EditTargets folder: Opens the EditTargets folder:

    Windows: C:\Program Files(x86)\CoPrAX\EditTargets

    macOS: Applications\CoPrAX\EditTargets

    Open Testcharts folder: Opens the Testcharts folder:

    Windows: C:\Program Files(x86)\CoPrAX\Testcharts

    macOS: Applications\CoPrAX\Testcharts

    Help

    Online Help: Opens CoPrA’s Online Help (internet connection required).

    Quick Start Guide: Opens the online help page for the Quick Start Guide (internet connection required).

    What’s New: Links to the online help page with the new features and bug fixes in CoPrA (internet connection required).

    readme.txt: Contains the release notes with short information about the latest changes.

    Registration: Load and activate licenses, request a demo license or get more information about the licenses.

    Check for update: Checks whether a new program version is available (internet connection required).

    Save Support Data: Creates a compressed and encrypted text file that contains important support information.

    About: Opens the registration dialog. Contains information about the version and build number.

    CoPrA | New Printer Profile

    New Printer Profile

    Create printer profiles

    Creating a Printer Profile

    Every printer profiling requires a test chart containing various color patches of the corresponding color space as a basis. There are two ways to get measurement data for the creation of a printer-specific ICC profile:

    1. Measure and optimize the test chart and measurement data using appropriate software, such as ColorAnt, then open the measurement data in CoPrA, or
    2. Measure the data in CoPrA directly using the Measure Tool.

    Adding ColorAnt for measurement data processing is advantageous, to eliminate measurement errors, printing errors and other artifacts (for example inhomogeneities). Analyzing and optimizing the measurement data results in an increased profile quality which then results in improved reliability in production.

    Note: For CMYK printing processes it is recommended to use the test chart IT8.7/4. For RGB printers, use test charts with many test patches (900 and more). For Multicolor profiling, either use the test charts provided by CoPrA or create test charts using ColorAnt.

    Load or Measure Data

    Load or Measure

    Load: Opens and displays existing measurement data files.
    Note: A right click on Load opens a list with recently used files. Selecting an entry in the recently used files list while pressing the CMD key takes you to the folder containing the file.
    Alternatively, drag and drop the data into the
    Printer Profiling window to extract and view the data. CoPrA supports a variety of device manufacturer formats. Measurement and reference data can be processed three different ways:

    1. Use reference data provided by organizations such as FOGRA, ECI or IDEAlliance.
    2. Use data from a profile. Many manufacturers of profiling software save the measurement and reference files used for profiling within an ICC profile. Simply drag and drop the ICC profile to the Printer Profiling window and the data will be extracted and displayed. Alternatively, the profile can be opened and extracted using the button Load. If an error message pops up, the ICC profile does not contain measurement data.
    3. Measure test charts using ColorAnt or measuring tools from other instrument manufacturers, save the data and open in CoPrA.

    Measurement data for printer profiling

    Measure: As an alternative to working with pre-existing measurement data, test charts can also be measured using CoPrA’s Measure Tool. Open Measure Tool by clicking Measure and measure with a supported device. Further information on the measurement of test charts can be found here.

    Chart preview area: The preview of the reference data of a profiling chart shows the correct colors. This allows for a visual comparison of the reference and the measured data.
    Note: When previewing the reference data of a chart with White ink, the correct color of the white point is displayed.

    Data of red substrate such as a red shirt


    Data of black substrate such as a black shirt

    Setting: Select the applied printing method. CoPrA contains a large number of standard settings for common printing methods (e.g. digital and inkjet printing).

    Customize: In order to achieve the best possible profile quality, further settings can be adjusted under Customize, such as settings for Color Generation or the specification of the first printed tone.

    Fit to Width: By activating this checkbox the color patches of a row will be fit to the window width. Especially for large test charts with many color patches and many rows, the color patches will be displayed larger.

    Show reference data: The device values such as CMYK or RGB and measurement data (i.e. Lab or spectral values) are shown on a split color patch. The data can be quickly compared for incorrect or faulty data.

    Patch
    Patch: Information is available for the selected color patch, such as the number of the patch, the total number of color patches, the color space and composition of the color and the Lab value.
    Working with Profile Settings

    Import, Export or Cleanup of Profile Settings

    Profile settings for Printer, DeviceLink and SaveInk profiling can be selected in the drop-down menu Setting.

    The package CoPrA Basic allows selection of default predefined settings. The package CoPrA M and higher provides access to all the parameters of the profile which can be customized.

    To adjust these profile parameters, select Customize. Custom settings can be saved, imported and exported which provides the ability to exchange personal profiling settings easily with other CoPrA users or make them available for support purposes.

    Import setting: Settings can either be imported as configuration file via the Tools menu using the entry Import setting or by dragging an ICC profile with the desired settings on the drop-down menu Setting. The name of imported profiles receives the suffix (imported). If an inappropriate profile (for example an RGB profile for CMYK profiling) is dragged on the drop-down menu Setting, an error message appears.

    Export setting: Customized profile settings can be selected in the drop-down menu Setting and exported as configuration file by using the entry Export setting from the Tools menu.

    However, CoPrA's default settings cannot be exported. Standard settings are listed in the drop-down menu Setting under the entry [PREDEFINED] and can be customized, but they cannot be overwritten. After customizing any setting the name receives the suffix (edited). It is now a custom setting which is listed under the entry [EDITED] and thus can be exported. Edited settings can be saved under any name. Saved settings will be removed from [EDITED] and listed under [SAVED]. Saved and edited settings can be deleted manually.

    Cleanup settings: All settings found under the entry [EDITED] will be deleted.

    Presets

    Default: Start with this preset if none of the other presets match your requirements. Then adapt to your needs.

    Digital Printer: Standard presetting, which provides a good starting point for adaptations to special requirements.

    Gravure TAC360: Automatically selects appropriate Black Generation (GCR), GCR Amount, Black Start and Black Width settings for gravure printing. Limits the total area coverage to 360% in the printer profile.

    InkJet: Standard presetting, which provides a good starting point for adaptations to special requirements.

    Newspaper TAC240: For newspaper printing. Automatically selects appropriate Black Generation (GCR), GCR Amount, Black Start and Black Width settings. Limits the total area coverage to 240% in the printer profile.

    No Black Separation: Creates a printer profile without black separation. Black Generation (GCR), GCR Amount, Black Start and Black Width settings are automatically selected and grayed out.

    Offset coated TAC330: For offset printing. Automatically selects appropriate Black Generation (GCR), GCR Amount, Black Start and Black Width settings. Sets the Black Calculation to Balance CMY and limits the total area coverage to 330% in the printer profile.

    Offset uncoated TAC280: For offset printing. Automatically selects appropriate Black Generation (GCR), GCR Amount, Black Start and Black Width settings. Sets the Black Calculation to Balance CMY and limits the total area coverage to 280% in the printer profile.

    Default – Multicolor: Standard presetting, which provides a good starting point for adaptations to special requirements.

    Digital Printer – Multicolor: Automatically selects the Multicolor Mode (Smooth) and appropriate Black Generation (MaxK), GCR Amount, Black Width and Black Start settings. Limits the total area coverage to 330% in the printer profile.

    Industrial Printing and Packaging: Presetting for packaging printing.

    White ink + 4 Primary Colors – Printing on Black: For color managed color prints on black substrates, such as textiles, white ink must be used first and colors must be applied on top of the white ink to obtain colorful graphics. This preset uses White for the separation. It automatically selects the appropriate Multicolor Mode  – either CMY+White_on_Black or CMYK+White_on_Black – while all other Color Generation controls are disabled.
    Note: To create profiles with White, special test charts are required, which can be found in the test charts subfolder Special for the two cases CMY+White_on_Black and CMYK+White_on_Black.

    General

    Perceptual Rendering

    Compared to the ICC framework, which only supports perceptual rendering in applications, ColorLogic provides a choice of Perceptual Rendering options when creating profiles. In order to use a ColorLogic profile created with one of the special Perceptual Rendering options, the perceptual rendering intent must be set in the target application.

    Note: All Perceptual Rendering options in the drop-down menu, including the Advanced Perceptual Rendering Options (such as Saturation, Chroma, Lightness, Gray Balance), are also applied to the Saturation Rendering Intent.

    CoPrA offers the following methods in relation to perceptual rendering:

    Standard Compression: This is the default method. It uses a perceptual conversion that is well suited for all types of gamuts, i.e., also for conversions between color spaces of different sizes. Neutral tones are converted using a relative colorimetric approach, and the appearance of the gray axis always depends on the paper white of the target profile. Therefore, the gray axis of the transformed file will appear yellowish on a very yellowish paper. The same gray axis will appear bluish on a bluish paper. For very small color gamuts, for example in newspaper printing, the dark tones are raised slightly to achieve more image definition in these areas.

    Blackpoint Compensation: Use Blackpoint Compensation to achieve the same results with a perceptive conversion as with “Relative Colorimetric with Black Point Compensation”. When converting from large to small color spaces, the image definition is preserved in the highlights and shadows, unlike with a pure Relative Colorimetric conversion. Neutral tones are converted using the Relative Colorimetric intent. Out-of-gamut colors are cut off.

    Absolute Compression: This method is based on the absolute colorimetric rendering intent in terms of color reproduction and is recommended when the paper tones differ significantly (the color gamuts can be similar or different). In contrast to the Standard Compression and Blackpoint Compensation, the paper tint is compensated in the gray balance. The rendering of neutral colors is based on the absolute colorimetric rendering intent, without paper tone simulation in the highlights. If, for example, the paper white is significantly more yellow than in the reference, the gray axis appears neutral despite the yellowish paper tone. This ensures that the color appearance of the original file is preserved as best as possible on a target medium with a different paper tint. The contrast range in the highlights and shadows is adapted to avoid any loss of image definition.

    Minimum Compression (Paper Absolute): This method is largely similar to the absolute colorimetric intent and only compensates close to the black and the white point.
    In addition, the white point of the source color space is not simulated, but scaled to the white point of the target color space, thus ensuring a pure paper white.
    Use this rendering intent to achieve a close reproduction, for example when using print standards such as ISO Coated V2 or GRACoL2006 Coated1v2 on a digital printer.
    Note: As for the absolute colorimetric rendering intent, ensure that the target color space is larger or has at least a similar size to avoid any loss of image definition. For color conversions from larger to smaller color spaces use Absolute Compression to maintain the gray balance of the source color space.

    Minimum Compression (Paper Relative): This method is largely similar to the relative colorimetric intent and only compensates close to the black and the white point. It is similar to Minimal Compression (Paper Absolute) but uses relative colorimetric instead.

    Advanced Perceptual Rendering Options: The drop down menu allows changes to the overall Chroma, Lightness or Saturation of the profile using a slider. Chroma can be used to reduce or increase the chroma of highly saturated colors in the range between -20 and +20. Saturation can be used when highly saturated colors are required. As with the setting Chroma, the gray balance is not affected when moving the slider. Saturation can be used especially for large color spaces such as gamut extending Multicolor in order to achieve more brilliant colors.


    Notes: ColorLogic intentionally keeps the chroma effect moderate. However, when increasing the chroma, ensure that the setting neither causes a loss of image definition in highly saturated colors, nor adversely affects colors such as skin tones.

    The effect of each of these settings is shown in the gamut graph on the right. Increasing the saturation results in higher chroma and lower lightness, so more saturation will slightly darken the colors and they will appear more vibrant. In contrast, more chroma can result in high chroma colors being out-of-gamut and these colors would not be rendered by the given profile.

    Gray Balance: Allows adjustment of the gray balance to create a cooler or warmer gray axis. cooler shifts the gray balance towards more bluish colors (negative b* values), warmer shifts it towards yellowish colors (positive b* values). The effect of the slider setting is visualized in the graphic.

    Note: The setting Gray Balance works independently from the selected Perceptual Rendering method which has already an effect on the gray balance and allows visual adjustments based on personal color preferences.

    Black Calculation: Three different settings can be selected for black point calculation:

    Auto: Sets the black point of the profile to the well-defined value of RGB=0/0/0.

    Neutral: Calculates a neutral black point with a*=b*=0 taking the measured data into account. With non-neutral measured values, this can lead to the RGB values no longer being RGB=0/0/0 and possibly losing contrast.

    Darkest: Calculates the darkest possible black point, which can also be colored depending on the measurement data. In many cases this option results in the same RGB black point as Auto.

    CoPrA displays the calculated Lab value based on the values you entered for the Black Calculation. This enables you to immediately understand the color effect on the black point resulting from the option you have selected.

    Gamut plot

    The gamut plot illustrates two typical gamuts of a profile when converting from device color space to Lab. These plots show the gamuts for the two different rendering intents Absolute colorimetric (the blueish part) and Perceptual (the greenish part). Typically the perceptual gamut is larger because it is scaled from absolute white (Lab = 100/0/0) to absolute dark (Lab = 0/0/0) and the absolute colorimetric gamut is smaller as it represents the gamut based on the measurement data.

    Note: The gamut plot is a graphical visualization based on virtual data, to show the effects of the ColorLogic Perceptual Rendering methods on the perceptual gamut. The gamut plot is not based on your actual loaded measurement data.

    The plot of the absolute gamut does not change but the perceptive gamut plot changes depending on the chosen perceptual method. Besides the different sizes and shapes of the gamut, the gray balance is shown in the plot, too. For the absolute intent, the gray balance is shown as a red line and it is positioned in the yellowish part of the color space since the white point of this virtual data is also rather yellowish. The dotted line represents the gray balance of the perceptual gamut and depends on the selected perceptual method. Therefore, the perceptual gamut plot changes depending on the selected perceptual method.

    If the perceptual method is rather paper relative, such as Standard Compression, Blackpoint Compensation or Minimum Compression (Paper relative), the dotted line remains in a neutral position, which means it does not take the yellowish-gray balance into account. If the perceptual method is rather paper absolute, e.g. taking the yellowish-gray balance into account, the dotted line converges to the red line of the absolute gamut. Paper absolute perceptual methods include Absolute Compression and Minimum Compression (Paper absolute).

    Changes in the Advanced Perceptual Rendering Options such as Saturation, Chroma, Lightness or the Gray Balance are also visible in the perceptual gamut plot. More saturation results in a larger and slightly darker perceptual gamut and a warmer Gray Balance causes the dotted line to shift to the left to be more yellowish.

    General Settings for RGB Profiling

    Perceptual Rendering

    ColorLogic provides a choice of Perceptual Rendering options when creating profiles compared to the ICC framework which only supports perceptual rendering in applications. To use a ColorLogic profile created with one of the special Perceptual Rendering options, the perceptual rendering intent must be set in the target application.

    Note: All Perceptual Rendering options in the drop-down menu, including the Advanced Perceptual Rendering Options (such as Saturation, Chroma, Lightness, Gray Balance), are also applied to the Saturation rendering intent.

    CoPrA offers the following methods in relation to perceptual rendering:

    Standard Compression: This is ColorLogic’s standard method which is well suited for most applications. Neutral tones are converted using a relative colorimetric approach. If the paper white of the used printing medium is significantly more yellow than the reference, the gray axis will look more yellow as well. The contrast range will be adapted for small color gamuts to preserve image definition.

    Black Point CompensationUse Black Point Compensation to achieve the same results with a perceptive conversion as with “Relative Colorimetric with Black Point Compensation”. When converting from a large to a small color space, the image definition is preserved in the highlights and shadows, unlike with a pure Relative Colorimetric conversion. Neutral tones are converted using the Relative Colorimetric intent. Out-of-gamut colors are cut off.

    Absolute Compression: This method is based on the absolute colorimetric intent but with some differences. The contrast range in the highlights and shadows is adapted to avoid any loss of image definition. The rendering of neutral colors is based on absolute colorimetry without paper color simulation in the highlights. If the paper white of the used printing medium is significantly more yellow than the reference, the gray axis will look neutral despite the yellowish paper white.

    Minimum Compression (Paper Absolute): This method is  similar to the absolute colorimetric intent and only compensates close to the black and the white point.
    In addition, the white point of the source color space is not simulated but scaled to the white point of the target color space, thus ensuring a pure paper white.
    Use this rendering intent to achieve a close reproduction, for example when using print standards such as ISO Coated V2 or GRACoL2006 Coated1v2 on a digital printer.
    Note: As for the absolute colorimetric rendering intent, ensure that the target color space is larger or has at least a similar size to avoid any loss of image definition. For color conversions from larger to smaller color spaces use Absolute Compression to maintain the gray balance of the source color space.

    Minimum Compression (Paper Relative): This method is  similar to the relative colorimetric intent and only compensates close to the black and the white point. It is similar to Minimal Compression (Paper Absolute) but uses relative colorimetric instead.

    Advanced Perceptual Rendering Options: The drop-down menu allows changes to the overall Chroma, Lightness or Saturation of the profile using a slider. Chroma can be used to reduce or increase the chroma of highly saturated colors in the range between -20 and +20. Saturation can be used when highly saturated colors are required. As with the setting Chroma, the gray balance is not affected when moving the slider. Saturation can be used especially for large color spaces such as gamut extending Multicolor in order to achieve more brilliant colors.

    Notes: ColorLogic intentionally keeps the chroma effect moderate. However, when increasing the chroma, ensure that the setting neither causes a loss of image definition in highly saturated colors, nor adversely affects colors such as skin tones.

    The effect of each of these settings is shown in the gamut graph on the right. Increasing the saturation results in higher chroma and lower lightness, so more saturation will slightly darken the colors and they will appear more vibrant. In contrast, more chroma can result in high chroma colors being out-of-gamut and these colors would not be rendered by the given profile.

    Gray Balance: Allows adjustment of the gray balance to create a cooler or warmer gray axis. Cooler shifts the gray balance towards more bluish colors (negative b* values), warmer shifts it towards yellowish colors (positive b* values). The effect of the slider setting is visualized in the graphic.

    Note: The setting Gray Balance works independently from the selected Perceptual Rendering method which has already an effect on the gray balance and allows visual adjustments based on personal color preferences.

    Pure Black: Sets absolute Lab Black to the RGB value 0/0/0.

    Pure Gray: For RGB printer profiles, Pure Gray builds up the gray balance with equal amounts of color. This option can be useful for printer drivers that are driven by RGB if the printing system already prints mostly neutral in the gray axis and slight fluctuations with equally proportional RGB gray values are to be prevented.

    Note: The options can change and even cancel the black calculation and the perceptual rendering. These two options should therefore only be used in justified and exceptional cases.

    Black Calculation: Three different settings can be selected for black point calculation:

    Auto: Sets the black point of the profile to the well-defined value of RGB=0/0/0.

    Neutral: Calculates a neutral black point with a*=b*=0 taking the measured data into account. With non-neutral measured values, this can lead to the RGB values no longer being RGB=0/0/0 and possibly losing contrast.

    Darkest: Calculates the darkest possible black point, which can also be colored depending on the measurement data. In many cases this option results in the same RGB black point as Auto.

    CoPrA displays the calculated Lab value based on the values you entered for the Black Calculation. This enables you to immediately understand the color effect on the black point resulting from the option you have selected.

    Gamut plot

    The gamut plot illustrates two typical gamuts of a profile when converting from device color space to Lab. These plots show the gamuts for the two different rendering intents Absolute colorimetric (the blueish part) and Perceptual (the greenish part). Typically, the perceptual gamut is larger because it is scaled from absolute white (Lab = 100/0/0) to absolute dark (Lab = 0/0/0) and the absolute colorimetric gamut is smaller as it represents the gamut based on the measurement data.

    Note: The gamut plot is a graphical visualization based on virtual data to show the effects of the ColorLogic Perceptual Rendering methods on the perceptual gamut. The gamut plot is not based on your actual loaded measurement data.

    The plot of the absolute gamut does not change but the perceptive gamut plot changes depending on the chosen perceptual method. Besides the different sizes and shapes of the gamut, the gray balance is shown in the plot, too. For the absolute intent, the gray balance is shown as a red line and it is positioned in the yellowish part of the color space since the white point of this virtual data is also rather yellowish. The dotted line represents the gray balance of the perceptual gamut and depends on the selected perceptual method. Therefore, the perceptual gamut plot changes depending on the selected perceptual method.

    If the perceptual method is rather paper relative, such as Standard Compression, Blackpoint Compensation or Minimum Compression (Paper relative), the dotted line remains in a neutral position, which means it does not take the yellowish-gray balance into account. If the perceptual method is rather paper absolute, e.g., taking the yellowish-gray balance into account, the dotted line converges to the red line of the absolute gamut. Paper absolute perceptual methods include Absolute Compression and Minimum Compression (Paper absolute).

    Changes in the Advanced Perceptual Rendering Options such as Saturation, Chroma, Lightness or the Gray Balance are also visible in the perceptual gamut plot. More saturation results in a larger and slightly darker perceptual gamut, and a warmer Gray Balance causes the dotted line to shift to the left to be more yellowish.

    Measurement Processing

    When creating or updating printer profiles it may be necessary to optimize the measurement data. The Measurement Processing in CoPrA includes the optical Brightener Compensation, the Measurement Correction and the specification of a Viewing Condition.

    Brightener Compensation: Recommended for bright white papers that contain optical brighteners. This correction weakens the effect of optical brighteners, which are evaluated differently by a measuring device compared to the human eye, and prevents negative accompanying effects such as a yellowish color reproduction.

    Recommendation: Work with spectral measurement data whenever possible. When working with spectral measurement data, the function Brightener Compensation can achieve an optimum correction. The correction will only be executed,in contrast to colorimetric measurement data (Lab measurement data), if CoPrA recognizes the paper color as an optical brightener. However, it will not be carried out if CoPrA does not recognize the paper color as optical brightener, which, for example, is true for a blue-colored paper.

    As a result of the viewing condition changes according to ISO 3664:2009, The updated standard makes it easier to spot the effects of optical brighteners (OBAs). So a minor correction is needed for devices using the M0 measuring method.

    As a result of the viewing condition changes according to ISO 3664:2009, optical brighteners in papers are more strongly excited, a small correction is therefore also necessary for measuring instruments using the M0 measuring method.

    Selecting Brightener Compensation and Measurement Correction

    Note: To specifically correct the effects of optical brighteners, use ColorAnt's Brightener tool before profile creation in CoPrA and disable the corresponding checkbox in CoPrA to avoid double compensation.

    Measurement Correction: Identifies and resolves measurement errors without changing the printing behavior. Redundant measurement values, which occur in typical test charts such as ECI2002 or IT8.7/4, are taken into consideration for detecting consistent printing properties and will be intelligently included in the correction. Further corrections, like the removal of redundant measurement values or Smoothing, can be done in the separate measurement data processing program ColorAnt.
    Recommendation: For your own measurement data select Measurement Correction as the default setting. However, this correction should be disabled for measurement values that have already been smoothed (such as FOGRA measurement values) or for measurement values that have already been processed with ColorAnt. If you have already made a correction in ColorAnt, CoPrA warns you of unnecessary double correction when activating the measurement data correction and/or brightener correction.

    G7 Correction: Corrects the tonal value curves of the measurement data to correspond to the gray balance conditions of the G7® method and includes these adjustments in the resulting ICC profile.

    With the G7® method, the CMY curves are adjusted to produce the most neutral gray hue possible with defined lightness across the entire gray balance.

    The G7 Correction is defined to work with CMYK only. However, it is possible to apply the G7® method to the CMYK parts of a Multicolor measurement file and the additional (Multicolor) channels will be corrected according to ISO 20654 (also known as SCTV, Spot Color Tone Value).

    The G7 correction option is also included in the Profile Report.

    Viewing Condition

    Viewing Condition: Typically, printer profiles are optimized for D50 viewing conditions and 2 degrees standard observer, however, for different tasks, e.g. textile printing with D65 and 10 degrees observer, photos in a gallery under incandescent light (roughly corresponds to viewing condition A) or presentation displays under a trade fair lighting with suboptimal lighting conditions (e.g., fluorescent light), the lighting conditions can be considered when creating the profile.

    To do so, select one of the four predefined viewing conditions or manually enter the measured viewing condition as Kelvin value or as XYZ value and change the standard Observer if required.

    Alternatively use the Emission option. To apply a spectral emission light measurement, select the entry Emission in the drop-down menu Viewing Condition and then select your measurement data file in the subsequent dialog (TXT, CXF or CSV file) or just drag and drop your measurement data file onto the value field. CoPrA extracts the white point from the file and displays the value.

    If spectral data are available, CoPrA uses this information to calculate a printer profile that makes your prints (with the selected viewing condition) appear as if they had been profiled with D50 and viewed under the standard viewing condition D50.

    When using spectral measurement data of a test chart and spectral data of a viewing condition (e.g., the options D50, D65, A, Equal Energy Spectrum, Kelvin or Emission), CoPrA will use a spectral color model to convert to Lab. If no spectral data is available a chromatic adaptation model according to CIECAM02 will be used, which in terms of quality is not the preferred method.

    Changing the Observer is only possible for spectral data, so if the Observer options are disabled, this is an indication that spectral data is not available.

    Note: CoPrA remembers the last used settings including the selected Viewing Condition. When creating new profiles, please check whether the selected viewing condition is in accordance with the purpose of the profile. If no specific viewing condition is required, always select the default D50 and 2 Degrees Observer.

    Highlights

    In flexo printing, the first printed tone is often subject to a rather high tone value increase. Additionally, in some flexo printing processes there is no transfer of tone values below a certain percentage in the highlight areas. However, the simulation of those process properties is particularly important for proofing applications to truly simulate the final print result in the highlights. It may also be necessary to increase the tone values in the highlights when using the profile for production or separation.

    For that reason, we integrated four different settings in CoPrA to adjust the Highlights.

    Default: Results in 'normal' profiling behavior in highlight areas. Use this setting for all printing processes that don't require any adjustment of the first printed tone.

    First Printed Tone (Preserve White): Defines when the first printed tone of the profile will be considered and appear in the proof (hard copy or soft proof). When the profile is used for separation, the paper white is maintained and small tonal values are immediately increased to the set tonal value resulting in a strong slope.

    First Printed Tone (Minimal Tone): Defines when the first printed tone of the profile will be considered and appear in the proof (hard copy or soft proof). When the profile is used for separation, a tonal value corresponding to the set percentage is already printed in the white of all channels.

    Printed Tone at 1 % (Proof): This setting defines the tone value to be achieved at 1% in proof direction of the profile. In separation direction of the profile, the setting Default is used (in contrast to other highlight settings).

    Based on data: If the loaded measurement data contains enough data points in the highlights, CoPrA also provides information about the start of the first printed tone (see screenshot). This information may be used as a guide to assess the value that should be entered in the input field to the right.

    Note: The information Based on data will only be displayed when one of the Highlight settings is selected from the drop-down menu and the data allows a different recognition of the first printed tone compared to the Default setting. Before using the value for profiling, we suggest analyzing the data in ColorAnt.

    The Highlights settings are not available for RGB profiling.

    Color Generation

    Color Generation for Multicolor Profiling

    Multicolor Mode: Determines how colors will be built up in individual separations. Is only available when Multicolor measurement data has been loaded. A Multicolor license is required to use Multicolor features.

    Note: Multicolor modes that are not recommended for the loaded measurement data are marked red in the drop-down menu.

    In some cases, a warning or information message is shown below at the bottom of the window in case the loaded data may require a different mode than the selected one.

    In CoPrA, the first three channels represent primary colors (usually CMY). They should form a sound color space (gamut) and should also be able to create a gray axis. The fourth channel should be black if a separation with UCR/GCR is desired. If black is absent in the Multicolor measurement data while automatic Black Calculation is selected, it will be recognized by CoPrA and the separation will not be generated. Black separation is disabled if the value for Max. Black in the Black Point and TAC setting is 0%. Additional spot color channels (e.g., Orange, Green or Violet in a CMYK-OGV 7 color data set) are regarded as color space expanding colors. The Multicolor Mode determines how color space expanding colors are factored in together with primary colors.

    Strong: As much spot color as possible will be applied. Accordingly, less primaries will be used in the highly saturated color areas. This results in a greater use of color space expanding spot colors and therefore in highly saturated colors in the printout.

    Smooth: Use this method when more CMY is required and if a particularly smooth and harmonious separation with the extended colors is needed.

    Note: The two Multicolor modes Smooth and Strong are similar but Smooth uses less color space expanding spot color channels.

    Generate separations with sparse inks: Is of interest for the packaging market as color separations are created in such a way that a certain hue uses as much as possible of a related spot color and very little or no primary colors. For example, in order to create a red hue as much as possible of a reddish spot color is used but very little to no magenta or yellow. A maximum of two or three colors are used for each color segment and, therefore, this Multicolor mode is practical to save process colors. However, black generation cannot be controlled and is based on the (separation) mode MaxK.

    Note: In contrast to the Multicolor modes Smooth, Strong and Use CMYK only, the Multicolor mode Generate separations with sparse inks does not allow regulation of the Black Generation. Accordingly, these settings are grayed out.

    Use CMYK only: Selecting this method results in a Multicolor printer profile that creates the desired number of channels (e.g., 7 channels) but is only composed of CMYK. The color space expanding spot color channels are not used for the separation but are used for the simulation of colors.

    Notes:

    1. In package printing, there is sometimes a request for images and vectors composed of CMYK to be generated with only minimal changes to CMYK values and without spot colors - despite conversion into a Multicolor space. In this case, only spot colors, like Pantone colors, which are present as DeviceN in the PDF should be converted into the large Multicolor space. Such a workflow is possible in two easy steps:
      (1) Creation of a separation-preserving CMYK-to-Multicolor DeviceLink profile in CoPrA using the Multicolor method Use CMYK only.
      (2) Spot color conversion of the PDF using ColorLogic's color server ZePrA.
    2. In CoPrA all settings of Color Generation (i.e. the entire tab) depend on black being present in the measurement data. Therefore, black must be present in the measurement data or ICC profiles as fourth channel.
      If black is not present in the measurement data as the fourth channel, this channel will be treated as if it were the black channel. As an example, if blue is present as the fourth channel, then all settings in the tab Color Generation will still treat the fourth - now blue - channel as a black channel. In this situation, spot colors can be used for the calculation of the gray balance and the black point.

    CMY+White: If the measurement data includes White as a color channel in addition to 3 primary colors, this Multicolor Mode must be selected. CMY refers to any 3 primary colors that form a sound color space and include a gray balance. This mode predefines the separation settings to use the color of the background (e.g., the black substrate) and the white ink within the separation. It automatically selects the optimal settings so that all other Color Generation controls are disabled and only the overall TAC can be adjusted under Black Point and TAC.

    Please be aware that the resulting ICC profile is a Multicolor profile (4CLR profile).

    CMYK+White: If the measurement data includes White as a color channel in addition to Black and 3 primary colors, this Multicolor Mode must be selected. CMY refers to any 3 primary colors that form a sound color space and include a gray balance. This mode predefines the separation settings to use the color of the background (e.g., the black substrate) and the white ink within the separation. It automatically selects the optimal settings so that all other Color Generation controls are disabled and only the overall TAC can be adjusted under Black Point and TAC. The assumed black point, e.g., the darkest color, uses a predefined combination of 100% Black printed on the black substrate.

    Please be aware that the resulting ICC profile is a Multicolor profile (5CLR profile).

    Background: For color managed color prints on black substrates, such as textiles, white ink must be used first and colors must be applied on top of the white ink to obtain colorful graphics.

    Note: To create profiles with White, special test charts are required, which can be found in the test charts subfolder Special for the two cases CMY+White_on_Black and CMYK+White_on_Black.

    Black Generation: Defines the method for the generation of black in the target color space and therefore influences the separation comprehensively.

    The following modes are available in the drop-down menu:

    Auto: Uses a medium GCR amount which is based on the measurement data.

    UCR: Allows adjustment of the settings Black Start and Black Width.

    GCR: Additionally allows the adjustment of the setting GCR Amount.

    MinK: Uses only a minimal amount of black and generates a separation using the maximum amount of CMY.

    MaxK: Uses a maximal amount of black and generates a separation using the minimum amount of CMY.

    The methods UCR, GCR, MinK and MaxK generate a new separation, regardless of the separation of the target profile.

    GCR Amount: Defines the amount of CMY that is replaced by black. At 0 only a low GCR amount is used which mainly impacts the shadows whereas at 100 a very strong GCR is used which affects the shadows and the highlights.

    Black Start: Defines the starting point for the black generation. Black will be used if the minimum amount of CMY exceeds this limit.

    Black Width: Defines the range in which black is generated outside the color-neutral area. The lower the value, the less black will be generated outside the color-neutral area.

    Additional Options

    100% Black: Prevents a pure black RGB text from being printed in four colors after conversion into a CMYK profile which would result in a blurred looking text. This is often the case with Office documents. Enabling 100% Black converts an RGB value of 0-0-0 to CMYK 0-0-0-100 (i.e. 100% black).

    Pure Gray: Enabling this checkbox in a CMYK printer profile results in a gray balance which is composed of black ink only. However, this only makes sense if the printing system features a very neutral black from shadows to highlights.

    Enabling Pure Gray in an RGB printer profile results in a gray balance which is composed of equal amounts of RGB values. This proves to be useful in RGB controlled (inkjet) print drivers.

    Avoid Dot-on-Dot: Prevents Black and Violet/Blue color combinations that could produce dot-on-dot effects in AM printing. Replaces some of the Black by CMY, therefore avoiding dot-on-dot effects.

    Background: When using gamut extending process colors in traditional AM screening, such as CMYK+Orange+Green+Violet/Blue, the process colors Violet or Blue are often on the same screening angle as Black which can cause dot-on-dot issues leading to color and lightness variances. However, avoiding Black and Violet/Blue color combinations in separations would reduce the available gamut considerably and would also prevent dark bluish spot colors from being reproduced faithfully. By activating this feature, the separation uses more of the CMY colors instead of Black thereby preventing dot-on-dot effects. For this function to work best, use a late Black Start and a rather weak GCR or even a UCR Black Generation setting.

    Note: Other color combinations using the same AM screening angles such as Cyan and Orange or Magenta and Green are not affected by this feature as those combinations are rarely used in separations anyway.

    Used Channels: Displays the channels to be used in a profile. Excluded channels are grayed out and marked with an X. All settings that affect channels, such as channel definition, channel combination, or enabling/disabling channels, can be configured in the Channel Settings. This can be done both automatically and manually.

    The effect of selecting or excluding colors on Curves and the Gamut is immediately visualized in the graphic and the Black Point value.

    Note: The excluding channels function is particularly intelligent for Multicolor profiles, as it searches for replacement colors in the Multicolor channels when excluding a channel (e.g., Cyan), which can compensate for the missing channel in the gray balance. The alternatively calculated Multicolor channels are displayed grayed out in the panel Black Point and TAC (further information can be found in the toggle Black Point and TAC).

    Example: If a brown chocolate artwork is intended to be printed in CMYK without using any Cyan in the separation, a CMYK printer profile can be created which only uses MYK. These types of profiles avoid unwanted Cyan dots in the separation and the converted artwork would appear visually close to a conversion with a complete CMYK profile. Obviously such a profile should not be used if the artwork contains Cyan based color combinations, such as cyan tones and blue or violet colors.

    Channel Settings: By default, all channels of the profile are enabled, and all Channel Settings are set to Auto. Channels can be enabled or disabled by clicking on the icon of the desired channel. It is possible to exclude multiple channels.

    Note: In CoPrA, the default channel order in the measurement data has always been: Three primary colors (P), optional black (K) and optional additional (other) colors (O). This definition was applied regardless of whether the order could be handled correctly or not.

    The Channel Settings option allows editing channels that are not defined in the correct order so that they can be used correctly in CoPrA.

    Definition: The channel Definition determines the assignment of the channels, i.e., whether it is a primary color (e.g., CMY), black or another gamut-extending (spot) color. This assignment can be done automatically or manually. By default, the order is set automatically (Auto).

    An important element of the channel Definition is the inherent flexibility to achieve the maximum gamut volume from the measurement data used.

    Note: There are several reasons why measurement data do not comply with the required printing sequence.
    For example, in some applications, a specific color sequence must be adhered to on printing presses, and the RIP assigns a linearization to this sequence. The profiling chart is then defined and printed based on this sequence.
    In other applications, such as ceramic printing, standardized CMYK colors are not used, and a specific sequence is not provided.
    In addition, different densities of the colors used can result in colors being swapped to obtain a larger color space (e.g., Magenta and Red).

    If Auto is enabled, CoPrA automatically calculates and selects the ink definitions and the combinations with the largest gamut. The size of the Gamut Volume and the combined channels are displayed.

    Manual Definition: If required, the channels can be manually assigned a custom definition. There are three options per channel available.

    Primary: The data must contain three primary colors.

    Black: One channel can be defined as black.

    Other: Additional colors get the status Other.

    After defining the channels and confirming the settings with Apply the Gamut Volume is calculated and displayed. By clicking OK the changes are applied and the window is closed.

    Combination: The channel Combination specifies the Multicolor channels which are to be combined to expand the color gamut. This can be assigned automatically (which is the default for measurement data ≥4CLR) or manually.

    Auto: This checkbox is enabled by default for all Multicolor presets. When enabled, CoPrA automatically calculates and selects the ink combinations with the largest gamut and indicates the combined channels. The combined channels are displayed in the Channel Settings window and also below the Curves and Gamut previews. In both previews CoPrA shows the impact of the combined colors by the Gamut Volume number.

    If the Auto checkbox is disabled, the channels can be defined manually by clicking the checkboxes of the desired combinable channels. If the additional inks are not to be combined with the four standard inks, the channels of the additional inks can be disabled.

    Note: All profile settings, including those from the Channel Settings window, are embedded in the profile, and can be imported and used to reproduce settings by dragging an ICC profile onto the Setting drop-down menu. The name of imported profiles is given the suffix (imported).

    Background: The channel Combination option is intended for creating Multicolor printer and DeviceLink profiles used in industrial applications such as ceramic printing, glass or metal decoration or textile printing, with Multicolor inks.
    In these industries, special inks different from CMYK are often used in order to increase the color gamut in the shadows and some colorful areas, or to reduce costs.
    For example, a dark Red ink can be combined with a Magenta ink of similar hue to extend the color gamut in the dark areas of the ceramic print. Similarly, a light Gray can be used in combination with the Black channel in Flexo printing to create a smoother gradient from light to dark grays.

    CoPrA 8 and higher automatically detects if additional inks are either typical gamut-extending colors or special inks and will use them accordingly. For example, two inks with a similar hue but different chroma or lightness can be combined in a single channel.

    Example: If the Auto checkbox is activated, CoPrA calculates for the 6 color inks of the example data set (see screenshot) that the second channel (Magenta) can be combined with the 5th channel (a dark Red ink) to increase the gamut in the dark areas.

    The Curves show that Magenta is used for lighter colors, while more of the dark Red channel is used for darker colors with the Magenta channel being reduced to a minimum.
    On the other hand, the 6th channel (Orange) is a typical gamut-extending color and as such is automatically used by the selected Multicolor Mode in the Magenta-Yellow range of the color space.
    The Auto function determines the best combination of additional inks and their combination with the 4 standard inks to achieve the largest color Gamut Volume.

    Note: Typical gamut-extending colors used in ECG printing such as Orange, Green or Violet can not be combined with the 4 standard inks (CMYK).

    In industrial printing, it may be necessary to use combinations other than those recommended by the Auto function. By deactivating the Auto checkbox you can select custom channel combinations, provided that a combination of inks is applicable.
    Regarding the example in the screenshot, when the Auto checkbox is deactivated and channels can be combined, Magenta and dark Red are combined, and Yellow and Orange are combined, resulting in two channels under Combination.
    If the dark Red channel is disabled under Combination, only the Yellow and Orange inks are combined. Switching to the Gamut view allows comparing the impact of the combinable channels on the Gamut Volume number.

    Note: The channel Combination differs from the Used Channels! Channels that are disabled under Used Channels are not used in the separation. Usually, it is recommended to use all channels and not to disable any channel if you want to combine channels.

    It is recommended to use the default Auto setting for the channel Definition and Combination, as it automatically calculates and selects the ink definition and combinations with the largest gamut and indicates the combined channels.

    In our example the Magenta and Orange channel will be used as a Primary Color and Yellow is now combined with Orange.

    Curves and Gamut: Visualize the effects of the selected color separation and Black Point settings. The Gamut view shows changes of the gamut shape immediately when altering settings and provides a real time preview of the loaded measurement data. In addition, the Gamut Volume is calculated and expressed in Lab units using absolute colorimetric rendering intent which allows finding the settings that produce the largest gamut (highest number) easily.

    Example: The gamut view allows you to observe how a low Black Width setting or a very late Black Start reduces the ability of a profile to render dark colors.

    Graphical representation of the gamut

    Gamut Zoom: Increase or decrease the Gamut view with the mouse wheel, or by pressing cmd (macOS) or ctrl (Windows) and the left mouse button while moving the mouse forward (to zoom out) or backward (to zoom in).

    Color Generation for CMYK Profiling

    Multicolor Mode: Not applicable for CMYK profiling.

    Black Generation: Defines the method for the generation of black in the target color space and therefore influences the separation comprehensively.

    The following modes are available in the drop-down menu:

    Auto: Uses a medium GCR amount which is based on the measurement data.

    UCR: Allows adjustment of the settings Black Start and Black Width.

    GCR: Additionally allows the adjustment of the setting GCR Amount.

    MinK: Uses only a minimal amount of black and generates a separation using the maximum amount of CMY.

    MaxK: Uses a maximal amount of black and generates a separation using the minimum amount of CMY.

    The methods UCR, GCR, MinK and MaxK generate a new separation, regardless of the separation of the target profile.

    GCR Amount: Defines the amount of CMY that is replaced by black. At 0 only a low GCR amount is used which mainly impacts the shadows whereas at 100 a very strong GCR is used which effects the shadows and the highlights.

    Black Start: Defines the starting point for the black generation. Black will be used if the minimum amount of CMY exceeds this limit.

    Black Width: Defines the range in which black is generated outside the color-neutral area. The lower the value, the less black will be generated outside the color-neutral area.

    Additional Options

    100% Black: Prevents a pure black RGB text from being printed in four colors after conversion into a CMYK profile which would result in a blurred looking text. This is often the case with Office documents. Enabling 100% Black converts an RGB value of 0-0-0 to CMYK 0-0-0-100 (i.e. 100% black).

    Pure Gray: Enabling this checkbox in a CMYK printer profile results in a gray balance which is composed of black ink only. However, this only makes sense if the printing system features a very neutral black from shadows to highlights.

    Enabling Pure Gray in an RGB printer profile results in a gray balance which is composed of equal amounts of RGB values. This proves to be useful in RGB controlled (inkjet) print drivers.

    Used Channels: Displays the channels to be used in a profile. Excluded channels are grayed out and marked with an X. All settings that affect channels, such as channel definition, channel combination, or enabling/disabling channels, can be configured in the Channel Settings. This can be done both automatically and manually.

    The effect of selecting or excluding colors on Curves and the Gamut is immediately visualized in the graphic and the Black Point value.

    Channel Settings: By default, all channels of the profile are enabled, and all Channel Settings are set to Auto. Channels can be enabled or disabled by clicking on the icon of the desired channel. It is possible to exclude multiple channels.

    Note: In CoPrA, the default channel order in the measurement data has always been: Three primary colors (P), optional black (K) and optional additional (other) colors (O). This definition was applied regardless of whether the order could be handled correctly or not.

    The Channel Settings option allows editing channels that are not defined in the correct order so that they can be used correctly in CoPrA.

    Definition: The channel Definition determines the assignment of the channels, i.e., whether it is a primary color (e.g., CMY), black or another gamut-extending (spot) color. This assignment can be done automatically or manually. By default, the order is set automatically (Auto).

    An important element of the channel Definition is the inherent flexibility to achieve the maximum gamut volume from the measurement data used.

    Note: There are several reasons why measurement data do not comply with the required printing sequence.
    For example, in some applications, a specific color sequence must be adhered to on printing presses, and the RIP assigns a linearization to this sequence. The profiling chart is then defined and printed based on this sequence.
    In other applications, such as ceramic printing, standardized CMYK colors are not used, and a specific sequence is not provided.

    If Auto is enabled, CoPrA automatically calculates and selects the ink definitions with the largest gamut. The size of the Gamut Volume is displayed.

    Manual Definition: If required, the channels can be manually assigned a custom definition. There are three options per channel available.

    Primary: The data must contain three primary colors.

    Black: One channel can be defined as black.

    Other: Additional colors get the status Other.

    After defining the channels and confirming the settings with Apply the Gamut Volume is calculated and displayed. By clicking OK the changes are applied and the window is closed.

    Use case: How to create a CMYK profile from KCMY data

    By default, measurement data which uses a different channel order than CMYK (e.g., KCMY) is treated as 4CLR data, even when the Channel Definition is set to Auto, in order to assign the correct definition per channel and achieve the maximum gamut volume.

    As a result, the Multicolor ModeStrong” is used to create a profile without Black (CMY only) with a maximum Gamut Volume of 312949 (Lab Units).

    However, the recommended Multicolor ModeUse CMYK only” creates a black separation with Black, increasing the Gamut Volume to 378490 Lab Units.

    Therefore, to create a CMYK color space profile based on KCMY data, it is necessary to select the option Calculate CMYK Profile. This CMYK profile can be used, e.g., in DeviceLink profiling as a source or target profile or in image editing applications.

    Note: All profile settings, including those from the Channel Settings window, are embedded in the profile, and can be imported and used to reproduce settings by dragging an ICC profile onto the Setting drop-down menu. The name of imported profiles is given the suffix (imported).

    Curves and Gamut: Visualize the effects of the selected color separation and Black Point settings. The Gamut view shows changes of the gamut shape immediately when altering settings and provides a real time preview of the loaded measurement data. In addition, the Gamut Volume is calculated and expressed in Lab units using absolute colorimetric rendering intent which allows finding the settings that produce the largest gamut (highest number) easily.

    Example: The gamut view allows you to observe how a low Black Width setting or a very late Black Start reduces the ability of a profile to render dark colors.

    Graphical representation of the gamut

    Gamut Zoom: Increase or decrease the Gamut view with the mouse wheel, or by pressing cmd (macOS) or ctrl (Windows) and the left mouse button while moving the mouse forward (to zoom out) or backward (to zoom in).

    Black Point and TAC

    Under Black Point and TAC the overall Total Area Coverage (TAC) and the TAC for the black point (Black TAC) can be defined. The black TAC represents the darkest color value of the profile which is usually identical with the maximum TAC.

    The graphical display of each color contains a number field showing the amount of ink used in the profile. Depending on the selected Black Calculation the number fields are either enabled or disabled.

    Note: The default window size sometimes truncates the input fields for Multicolor channels. Enlarge the window to display the input fields for all colors.

    Customize TAC settings

    Black Calculation: Four different settings available for Printer Profiling (see screenshot below).

    Black Calculation settings

    Auto: The calculation of the optimal black point (dark and neutral) is based on the measurement data. The values entered for Black TAC and Max.Black define limits which must not be exceeded, but may be lower if technically possible.
    All channels are used to generate the black point (Black TAC), therefore individual channel editing is disabled. This mode will not use any Multicolor channels beside the first four channels (usually CMYK).
    Note: If you do not have a default value for the Black TAC it is recommended to use 400% for the Black TAC as a starting point for the calculation.

    Balance CMY: This setting adapts the CMY values to a pre-defined Max.Black value and generates a neutral black point. Define the Black TAC and TAC in accordance with the printing conditions. Max.Black should be set to the ideal value for the selected substrate. Similar to the setting Auto those values are regarded as maximum values which may be underrun if a neutral black point is not achievable.
    Allows customization of the black channel (or in general the 4th channel) and the addition of Multicolor channels. Entered Multicolor color values are fixed - like the Max.Black value - and CMY values will be adjusted accordingly.

    Note on excluding channels:

    Basically, Balance CMY allows editing of the black channel (or in general the fourth channel) and the Multicolor channels. The CMY channels are grayed out (see screenshot).

    However, if a channel is excluded, the Multicolor channels are searched for a replacement color that can compensate for the missing channel in the gray balance. The replacement Multicolor channel is grayed out in the control panel Black Point and TAC (see screenshot).

    Darkest: Calculates the darkest possible black point with maximum density/lowest L*. Allows generation of a black point without neutral a* and b* values and darker L* if available.

    The values entered for Black TAC and Max.Black define limits which are not exceeded but may be lower if technically possible. Darkest uses the first 4 channels, usually CMYK. Possible Multicolor channels are added, but cannot be changed manually. If this is required, the Custom option must be selected.


    Custom
    : Allows definition of the black point in the input boxes. The Black TAC value will then be recalculated. Allows editing of all channels.

    Notes:

    • CoPrA calculates the Lab values based on the entered custom values. When changing custom values the resulting effects can be seen immediately. If you prefer CoPrA's recommendations, select the settings Balance CMY or Auto.
    • For Multicolor profiles with more than four channels you can use the extra Multicolor channels for the black generation besides the first four channels (typically CMYK). However, the total area coverage (TAC) cannot exceed 400%. Values for the Multicolor channels can be entered manually when using the settings  Balance CMY or Auto and these values will then be used to calculate the Black TAC. Usually, it is not necessary to use those channels but sometimes a dark Multicolor channel adds desired contrast and definition. This can easily be checked by viewing the Lab values below the Custom fields. If the addition of a certain Multicolor channel decreases L* while a*b* values are not significantly altered, using this channel can be considered. However, the gray balance will use additional channels as well.

    How CoPrA calculates Lab values

    Note: With the settings Auto or Balance CMY CoPrA tries to use neutral a* and b* values for the Black Calculation. In contrast, selecting the setting Custom allows generation of a black point without neutral a* and b* values. Keep in mind that this can lead to a colored black point, which you can recognize by the a* and b* values.

    TAC: The value for the maximum total area coverage can be entered in the input box TAC (value range: 0 to 400%). This value must not be exceeded. This also applies to Multicolor profiles. The TAC can also be set for 2 or 3 channel profiles.

    Black TAC: The Black TAC is the sum of all color values. The value for the black point (Black TAC), which results from your settings, will be displayed after a short calculation time below the text box Custom (outlined in red in the screenshot below).
    Note: The sliders limit each other, so the TAC can never be lower than the Black TAC (but it can be higher).

    Max.Black: Here you specify the maximum amount of black ink to be used by the separation (value range: 0 to 100%). Note that the entered value always refers to the fourth channel which, in Multicolor cases, may not be black but a chromatic color. Furthermore, the fourth channel of the Black TAC is always used for the darkest point of the profile, the black point.

    Black Point and TAC

    The Total Area Coverage (TAC) and the TAC for the black point (Black TAC) can be defined by Black Point and TAC. The Black TAC represents the darkest color value of the profile which is usually identical to the maximum TAC.

    Many modern printing systems allow a black point that is generated by using a low amount of ink. Sometimes the darkest color (Black TAC) can be printed using pure black which means that in extreme cases a black point of 100% K may be sufficient. Obviously, such a low TAC does not work for other color areas – it would not even be possible to print a true red, green or blue! Therefore, we separated the Black TAC from the general TAC. This allows using the best setting for Black Calculation without restricting the color space.

    Adjusting the Black TAC value

    The Lab value is particularly handy for assessing the effect on the black point when changing the TAC or Black TAC. The smaller the L* value, the deeper the black and the higher the contrast. 

    TAC and Black TAC can be adjusted separately in CoPrA
    The total area coverage (TAC) - defined by the separation - and the Black TAC are identical in traditional printing systems. However, industrial printing applications and many digital printing systems show that the black point can be selected much lower than the total area coverage. To achieve a sound gray balance with a high contrast while maintaining highly saturated colors it is necessary to separate these two settings.

    Advantages of a separate Black TAC
    We would like to demonstrate how important it is to adjust the Black TAC independently from the total area coverage (TAC) using a digital printing system. Let's assume the Black TAC and TAC could not be set separately and we had to use identical values for both of them. If you selected the setting Auto to calculate the black point and set a TAC of 300% (and therefore a Black TAC of 300% as well), CoPrA would calculate the best black point for this case. The result would be a total area coverage of 275% with a neutral black point (a* and b* are 0 respectively), but with a very light L* of 22.0 (outlined in red in the screenshot).

    CoPrA allows the setting of the Black TAC separately from the total area coverage (TAC). As pure black is used in some digital printing systems as darkest printing color, the Black TAC can be reduced to 100% which results in a black point with a significantly darker (lower) L* value of 9.8. Using a separate setting for the Black TAC achieves a significantly higher and better contrast than a TAC which is linked to a Black TAC of 275%. Additionally, a total area coverage (TAC) of 300% ensures highly saturated colors. These precise settings are only possible with separate TAC values.

    Profile Processing

    Format, Size and Further Processing

    In the last step of the profile creation, assign a Name and choose the Format and Size of the profile (see screenshot).

    Name: Type in a Name for the profile.

    Templates: Allows to select and combine name components from a list of options and save them as custom templates. The last selected template is used when creating new profiles, so the naming of profiles is automated. 

    Available naming options depend on the current profile type and include Date, Date/Time, Measurement data file name, Source and Target profiles, Name of the current preset and others. Each name component can be added at a user-defined position under Template (the position is selected with the mouse pointer). The Example section below shows the resulting name. Additionally, user defined text can be added at any position within the Template field.

    Format: Define the Format of your profile. An ICC format in accordance with specification v2 is recommended as basic setting however, the newer format ICC v4 can also be chosen. In this case, please ensure that your programs support this format correctly.
    Note: ColorLogic products handle and use ICC v4 profiles consistently and correctly.

    Size: The setting Large is recommended. The size specifies the number of grid points in the profile and determines the amount of disk space required for the generated profile. Small profiles should only be used for test purposes. Very Large profiles can slow down further processing in subsequent programs. Additionally, some programs are not able to handle very large profiles.

    Note: The profile Format and profile Size are embedded in the profile. They can be imported and used to reproduce settings by dragging the ICC profile onto the Setting drop-down menu. The name of imported profiles is suffixed with (imported).

    Further processing

    Create Profile Report: Recommended to activate. The PDF report provides an overview of the quality of the profile based on statistics, diagrams of gray balances, gradients and gamut representations as well as color separations of converted test files.
    Under Preferences, the Default save path for the reports and the Default report format can be selected. If XML is selected as the format, the corresponding XSD files will be created automatically as well.

    Calculate Multicolor Profile Variants: This option creates various combinations of the currently used Multicolor profile. You can either automatically create different variants like 3CLR, 4CLR as well as CMYK+ at the same time or select them individually.

    Multicolor profile variants, e.g., of a 7C output profile, are useful for determining whether fewer than 7 colors, e.g., 5 or 6 colors, or even the CMYK colors alone are sufficient for printing a given job. After all, it is not always necessary to use all available process colors and costs can be saved by using fewer channels.

    Note: The creation of 4CLR variants also creates a CMYK profile.

    The following rules apply when creating the variants:

    • A maximum of one spot color is used for 3CLR variants, e.g., CMO, MYG, CMV, …
    • A maximum of one spot color is used for 4CLR variants, e.g., CMYO, CMYG, CMYV, …
      Note: When the black channel is used in 3 or 4CLR variants, it is always the last channel, e.g., CMK, COK, YVK, CMOK, MYOK, …
    • For CMYK+ profiles, 5CLR and higher variants are created using CMYK and all spot color combinations, e.g., CMYKO, CMYKG, CMYKOG, CMYKOV, …
      Note: When the black channel is used in 5CLR and higher variants, it is always the fourth channel.

    For example, for a CMYKOGV inkset, the following number of profile variants are calculated:

    7CLR printer profile: 3CLR (22 variants) + 4CLR (13 variants) + CMYK+ (6 variants) = 41 variants

    For other printer profiles, the following numbers of variants result:

    4CLR printer profile: 3CLR (4 variants) + 4CLR (0 variants) + CMYK+ (0 variants) = 4 variants

    5CLR printer profile: 3CLR (10 variants) + 4CLR (5 variants) + CMYK+ (0 variants) = 15 variants

    6CLR printer profile: 3CLR (16 variants) + 4CLR (9 variants) +CMYK+ (2 variants) = 27 variants

    8CLR printer profile: 3CLR (28 variants) + 4CLR (17 variants) + CMYK+ (14 variants) = 59 variants

    9CLR printer profile: 3CLR (34 variants) + 4CLR (21 variants) + CMYK+ (30 variants) = 85 variants

    The names of Multicolor profile variants are based on the name of the printer profile and the letters of the channel names.

    Note: If a channel name is not recognized, its channel number is used instead. For example, if a channel is not recognized in a 7CLR printer profile, the resulting name would contain its channel number, e.g., CMYKO6G, and as a result, one of its variants would be named Name_CMYKO6.icc.

    If no channel name is recognized, numbers are used for all channels.

    Note: The profile PDF report is created only for the initial Multicolor profile – not for the Multicolor profile variants. A profile report for a Multicolor profile variant can be created by enabling the checkbox Create Multicolor Profile Variant Reports or in the Profile Manager. In Profile Manager, select the desired profile variant, open the context menu and select Create Profile Report (PDF) or (XML).

    Create Multicolor Profile Variant Reports: Based on the selection of the calculated Multicolor Profile Variants the dedicated Profile Variant Reports will be created and stored in the dedicated Documents folder.

    macOS: /Users/USERNAME/Documents/CoPrA/Reports/

    Windows: C:\Users\USERNAME\Documents\CoPrA\Reports

    Calculate 3CLR profile variants: Only available for CMYK printer profiles. This option creates 3CLR variants from the CMYK profile.

    Note: The following 3CLR variants will be created out of a CMYK printer profile: CMY, CMK, CYK, MYK.

    Calculate CMYK Profile: Only available when creating Multicolor printer profiles. Uses only the CMYK part of Multicolor data to create a CMYK profile or 4CLR profiles. For example, this can be useful for Multicolor PDF files to enable the display of the CMYK part of a conversion in PDF viewers without Multicolor support.

    Save Preview Profile: Is only available in Multicolor printer profiling. By activating this checkbox an ICC preview profile will be created in addition to the printer profile. It can be used as soft proof profile in Adobe Photoshop.

    Notes: Preview profiles are only suitable for proofing purposes. Either a preview profile or a CMYK profile can be created in one profiling step, but not both.

    Save: Creates the printer profile and saves it in the folder Profiles (macOS) or Color (Windows), (macOS: /Users/Username/Library/ColorSync/Profiles, Windows: C:\Windows\System32\spool\drivers\color). Demo and encrypted profiles will be saved in a different location only relevant for ColorLogic applications.

    Note: CoPrA-SP profiles are stored in the ColorLogic subfolder Licensed-Profiles.

    Preview Profiles

    Introduction: Using Preview Profiles for Soft Proofs

    Preview profiles allow soft proofing of image files in DeviceLink profiling and Multicolor printer profiling, without converting a file. Multicolor preview profiles provide a true color representation of images to be converted into the Multicolor color space in order to review the achievable result prior to the actual Multicolor conversion (More information can be found further down in the text). The same applies to DeviceLink conversions. Here, too, the DeviceLink preview profile can be used in Photoshop with the original data to visually review how the result of such a conversion would look like.

    Preview profiles can be created together with DeviceLink or Multicolor printer profiles by activating the checkbox Save Preview Profile (see screenshots). Preview profiles have the suffix ‘preview‘ and are saved in the folder Profiles (macOS) or color (Windows), (macOS: /Users/Username/Library/ColorSync/Profiles, Windows: C:\Windows\System32\spool\drivers\color). Right clicking on the preview profile and selecting the menu entry Show file in the context menu will take you directly to the location of the selected profile.

    Creating preview profiles in Multicolor printer profiling


    Creating preview profiles in DeviceLink profiling

    A preview profile is a printer profile with the same color space as the source profile of the DeviceLink. It can be used as soft proof profile, for example in Adobe Photoshop. Preview profiles can be created for the following DeviceLink combinations:
    RGB-to-CMYK, CMYK-to-CMYK, RGB-to-Multicolor and CMYK-to-Multicolor

    Note: The creation of preview profiles is not available for DeviceLink profiles using more than four channels in the source color space since only preview profiles of the color spaces Gray, RGB or CMYK can be used in Photoshop. Multicolor printer profiles are not affected as their preview profiles are always RGB profiles which can be used in Photoshop.

    Example: To adapt your RGB image data in RGB mode to the desired CMYK printing condition, use the preview profile of your RGB-to-CMYK DeviceLink as soft proof profile in Adobe Photoshop to check how the image would look like after the conversion. This allows specific RGB adjustments without the need to convert the RGB file early on. A preview profile is a very useful feature, particularly in view of storing RGB image data in media-neutral workflows.

    Preview profiles can also be created for Multicolor printer profiles which allows a true color simulation of the color representation prior to application of the Multicolor profile. Although Adobe Photoshop CS4 or higher is able to convert image data using Multicolor profiles, the display of multichannel files is not a true color representation in Photoshop. So far, a true color representation of multichannel files is only possible using additional plug-ins and causes an increased workload. The preview profile function generates an RGB printer profile which features the same color visualization as the original Multicolor profile. Use this preview profile on an original image data for soft proofing.

    Note: Preview profiles are only intended for soft proofs and should never be used for the actual conversion. A preview profile provides an excellent visual preview of the expected result of a DeviceLink conversion. However, the special features of the DeviceLink, such as preserving color purity, cannot be 100% emulated.

    Using Preview Profiles for DeviceLinks in Adobe Photoshop

    1. Open the original image data to be converted using a DeviceLink profile in Adobe Photoshop.
    2. Either assign the Preview profile from CoPrA to this image file, or select the Preview profile in the dialog Customize Proof Condition as Device to Simulate (see screenshot).
      Note: The color space of the preview profile is based on the color space of the DeviceLink’s source profile. It is an RGB preview profile for RGB-to-CMYK DeviceLinks and a CMYK preview profile for CMYK-to-CMYK DeviceLinks.
    3. Click Preserve CMYK Numbers to get a virtually exact preview of the expected color representation for the DeviceLink conversion.
      Note: Pipette values do not correspond to the final DeviceLink conversion. Only the color representation in the soft proof does.

    Using Multicolor Preview Profiles in Photoshop

    1. Open the original image data to be converted using a Multicolor printer profile in Adobe Photoshop (for example an RGB image).
    2. Select the Preview profile from CoPrA in the dialog Customize Proof Condition as Device to Simulate. Find the profile in the list of RGB profiles. The naming is based on the Multicolor profile name: Profile name_preview.icc
    3. Select the desired Rendering Intent and disable the checkbox Preserve RGB/CMYK Numbers.
      Note: Eyedropper values do not correspond to the final DeviceLink conversion. This is only for a soft proof.
    Profile Reports

    Profile reports can be created for Printer or DeviceLink profiles. To do so, activate the checkbox Create Profile Report in the last step of the profiling or, when updating profiles, the checkbox Create Profile Comparison Report.

     

    Depending on the type of profile the report contains various statistical data, such as statistics about profile precision (Integrity, Precision, Black Point, White Point etc.), graphic representations of curves and gamuts (Gray Balance, Gradients etc.), conversions of test images, separations and color patches to evaluate the smoothness or the purity of colors. All this facilitates the detection of artifacts that may be present.

    Profile reports can be created at any time in Batch Overview or in Profile Manager which, by the way, is not restricted to ColorLogic profiles.

    Under Preferences you can define some basic settings for the creation of the profile report, such as the Default save path, the Default report format (PDF or XML) or the DeltaE method (dE76 or dE2000). If XML is selected as the format, the corresponding XSD files will be created automatically as well.

    Note: If a profile comparison report is created when updating a profile, the measurement data obtained from the update test chart will be compared to the data of the original profile (reference profile).

    If the checkboxes Brightener Compensation or Measurement Correction have been activated, the data of the original profile will not be compared to the measurement data from the update test chart but to the data modified by these options.

    Multicolor Profiling and Chart Creation

    Generating Multicolor Profiles in CoPrA

    General Information

    CoPrA supports three main chromatic primary colors which should span a suitably large gamut encompassing the gray balance. Typically, this is CMY but it can be any other appropriate chromatic color combination.

    Black can be added optionally as a 4th channel. If black is used it must be the fourth channel.

    Up to two gamut extending colors can be used in between each section of the main primary colors.

    Note: Following this approach, printer profiles of up to 10 channels can theoretically be created by CoPrA 5 and higher. However, it is not recommendable to use printer profiles with more than 8 channels in production as every additional channel increases the profile size exponentially so that either a very low grid size or an exorbitantly large profile had to be used.

    Examples

    Typical Multicolor Application
    When using a typical Multicolor color space with CMYK parts, the additional inks Green, Orange and Violet extend the gamut in each section of the three primary colors. In between each section, a single gamut extending color is used creating a color space with 7 colors.

    Advanced Multicolor Application
    Some inkjet printers use Red and Orange in addition to the standard CMYK inks. CoPrA is able to profile such a 6 color printer since Orange and Red are two gamut extending colors of the main primary color sections Yellow and Magenta.

    Note: When working with two gamut extending colors, special test charts must be used. CoPrA provides appropriate Multicolor test charts which are available via Tools > Open Testcharts folder > Multicolor.

    Special Inks
    In industrial printing, such as ceramic printing, the main colors are often supplemented by additional light (e.g. Pink) or dark (e.g. Brown) inks. Another example is Flexo printing, where a Gray ink supplements the Black ink to better render lighter grays in the artwork. These colors are what we call special inks, and they can be used with the special Multicolor Modes in CoPrA.

    Supported Color Systems

    CoPrA allows to create printer and DeviceLink profiles for all types of color spaces Gray, RGB, CMYK and Multicolor. Cross color space profiles are also supported, such as RGB to CMYK, CMYK to Grayscale or RGB/CMYK to Multicolor.

    The following color systems are supported:

    • 2- and 3-color systems
    • 4-color systems with CMYK
    • 4-color systems with CMY + either Red or Green or Blue, without Black
    • 5-color systems: CMYK + either Red or Green or Blue
    • 5-colour systems: CMY + either Red+Green, Red+Blue or Green+Blue, without black
    • 6-colour systems: CMYK + either Red+Green, Red+Blue or Green+Blue
    • 6-colour systems: CMY + Red+Green+Blue, without Black
    • 7-colour systems: CMYK + Red+Green+Blue
    • 8-color systems: CMYK + Red+Orange+Green+Blue
    • 9-color systems: CMYK + Red+Orange+Green+Blue+Violet
    • Special ink combinations such as CMYK+Gray, CMYK+Pink+Brown, etc.
    • The CMY channels can even be exchanged for other similar colors, e.g. Magenta for another reddish color or Yellow for Beige and so on.
    • Creation of DeviceLinks with up to 9 channels
    Using Multicolor Test Charts

    To create Multicolor profiles various test charts (multichannel Photoshop PSD files) with associated reference files are available for measuring with ColorAnt (or any suitable measuring software). These Multicolor test charts can be found in the folder Testcharts (in CoPrA's installation folder). The folder can be opened directly in CoPrA (menu Tools > Open test chart folder). The contained Multicolor test charts are specifically optimized for the algorithms used by CoPrA. Alternatively, you can create your own test charts for your multicolor process using ColorAnt/Custom Chart.

    Selection of the correct test charts for your printing process is facilitated by the naming. Therefore, please note the following naming conventions:

    • The name of the test chart contains the number of channels, the color combination and the number of color patches.  The test chart name CL-CMYKB-2140 reflects that it is a 5-channel test chart with the color combination CMYK+Blue and 2140 color patches.
    • However, by 'Blue' we mean a fairly broad color range of reddish to greenish blue. For example, it contains violet as well.
    • The following color abbreviations are used in folder and file names: R = Red, G = Green, B= Blue, V= Violet, O = Orange, Yg= Yellow-Green.
    • For a Hexachrome printing process with CMYK+Orange+Green, use the corresponding test chart, CL-CMYKRG. Here, CMYKRG stands for CMYK+Red+Green, whereby red includes orange.
    • For 7-color printing use the test chart CL-CMYKRGB. In addition to the colors CMYK it also contains the additional colors Red+Green+Blue.
    • Nine special test charts for 6C and 7C color combinations have been available for two Gamut-extending colors (e.g. CMYK+Red+Orange). They can be found in the folder Special.
    • The layout of the supplied test charts is designed to fit on A4 or US letter size and is optimized for the hand-held measuring devices supported by the Measure Tool. As all patches cannot go on one page the Multicolor charts are split in multiple pages which need to be measured in corresponding sequence (1_6 means it is the first of six pages).

    Important Notes

    • The total area coverage (TAC) of 400% is not exceeded in any of the test charts, not even in Multicolor test charts.
    • Please make sure that the RIP or the output system of the printer supports Photoshop multichannel PSD files. If this is not the case please open the test charts in Photoshop (or another suitable image editing program) and save them as DCS2 files.
    • The test charts are optimized for the X-Rite i1Pro measuring device, but can also be measured with other any single color measuring devices.
    • For measurements with the X-Rite i1iO, Barbieri Spectro LFP and Konica-Minolta FD-9, we recommend creating a customized test chart file based on the corresponding reference file using ColorAnt’s Export Chart tool.
    • To use a measuring device that is not supported by ColorAnt MeasureTool, it is necessary to create a test chart which is suitable for that measuring device and the intended printing process. Make sure to select the reference file matching the color system. We recommend creating the corresponding reference files with ColorAnt/Custom Chart. Please note that our reference files use a maximum total area coverage of up to 400%, even for 7 channel color systems.
    • For Multicolor profiling - in contrast to CMYK Profiling - the test charts has to be adapted to the calculation algorithms in order to minimize color patches, otherwise, test charts would be exceptionally large.
      Note: Multicolor profiling differs from manufacturer to manufacturer. If you would like to use measured Multicolor test charts from other manufacturers in CoPrA, please note that these test charts may not achieve optimal results in CoPrA.
    • If it is not possible to reprint CoPrA's test charts and use existing measurement data from Multicolor test charts of other manufacturers, it is recommended to optimize these measurement data using ColorAnt before creating profiles in CoPrA. The Rescale tool allows adaption the measurement and reference values in ColorAnt according to suitable CoPrA test charts. Any missing measurement values will be interpolated which may result in inaccuracies if alternative test charts of other manufacturers reveal many gaps.
    • Special test charts, such as CMY test charts for printing systems that do not use black, are also available in the Testcharts/Multicolor folder.

    For example, when working with CMY+Blue, use the appropriate test chart from the folder CMY+B.

    Note: Previously, many users worked with standard CMYK test charts, such as ECI2002 or IT8/7-4, for color combinations without black, replacing the K channel with blue, e.g. CMY+Blue. Although this approach seems practicable at first glance, it is not recommended, because the process color black plays an entirely different role to a gamut extending color blue in CMYK test charts. Accordingly, many color combinations in the CMYK test charts are unnecessary, or even missing for a blue process color. It is preferable to use CoPrA in combination with CMY+X test charts in order to obtain the best possible profile quality.