DE102012013330A1 - Web-based calibration system for monitors of smartphones, has commercially available smartphone camera module and arithmetic unit comparing resulting actual values with setpoint value and transmitting corrected setting data to monitor - Google Patents

Abstract

The system has a commercially available smartphone camera module and a memory containing latest data on color profiles of screens, smartphones, printers and reference images. An arithmetic unit has a smartphone recorded reference image of a monitor corresponding to maximum design color profiles of corrected smartphone camera, and compares resulting actual values with a setpoint value, and transmits the corrected setting data to a monitor. The corrected setting data for the monitor is transmitted on smartphones. An independent claim is also included for a calibrating method for monitors.

Description

Lifelong image reproduction on the monitor is a problem because monitors do not play 1: 1 in the color values and gradients, depending on quality, photos, and scanned images. Furthermore, color deviations occur in different image processing programs.

Monitors and image processing programs must therefore be individually calibrated, especially for professional use. This usually requires professionals.

The user is usually provided with software functions to As colors, white and gray values in the brightness, saturation, contrast, etc. to change. The individual change of values is difficult and usually leads to a poor result, u. a. due to the subjective color perception of the user. To minimize calibration errors, expensive devices are offered for calibration.

The novel web-based calibration system includes the ability to optimize the screen display in a simple and inexpensive way, in a few steps, to ensure lifelike color reproduction on the monitor, as well as output to the printer (eg personal or network printer). to calibrate and optimize.

The calibration of the image representation, in particular the color representation on a monitor, serves for many fields of application the purpose of achieving an image representation with defined values for the brightness, the contrast, the gradation and in particular the color representation.

Depending on the application for which images are to be displayed on a monitor, there are several objectives for calibrating the monitor. In the simplest case, the smallest and the largest values for the displayable brightness (black point and white point) are set to specific fixed values. Since the screen brightness can change over time due to various influences, such as temperature or aging, calibration at a defined black point and white point ensures compliance with an always uniform brightness range within which the brightness of the displayed image signal varies. This ensures that brightness fluctuations seen in the monitor display can be assigned to the image and not to other influences, such as the aging of the monitor. The calibration of the brightness range is also important if you want to display and compare in parallel on several images. Then all monitors must first be calibrated to the same values.

According to the prior art, the calibration of the brightness can be performed by means of a separate brightness sensor with which the brightnesses on the screen are measured. For example, a black area with the darkest brightness and a white area with the brightest brightness are displayed on the monitor by controlling the monitor with the smallest or the largest image signal. The sensor is connected to a control electronics with which the displayed brightness can be changed and set to specific values. This control electronics is located for example in the monitor itself and affects the signal level and gain of the image signal. It can also be located on the graphics card of a computer workstation. In the case of purely digital control, so-called lookup tables are used with which a range of values of digital input values can be converted to a modified value range of digital output values. The measured values of the sensor can then be fed to a control software that changes the contents of the lookup tables so that the brightness range of the monitor display is set to defined values.

In addition to the simple calibration of the brightness range, for many applications of the image processing also the course of the brightness between the black point and the white point, d. H. the gradation can be calibrated. For this purpose, surfaces with different brightnesses are usually displayed on the monitor, measured with the sensor and evaluated in the control electronics or the software in order to set a defined brightness value for each displayed image signal level.

Accordingly, the color representation can be calibrated on a monitor, wherein z. B. the color areas of the primary colors red, green and blue (R, G, B) are shown and measured in each case with the sensor. It must also be taken into account that the sensor for different colors may have a different sensitivity. The measured values are weighted according to the color-dependent sensitivity with known (ie previously measured) factors. In this way, the brightness range and the gradation in the three color channels of the monitor are calibrated to ensure a controlled color representation. In addition, if greater accuracy is required, the monitor must be calibrated to represent a desired defined color for a particular combination of red, green, and blue image signal levels. For this purpose, colors in a defined color system predetermined, z. In the CIEXYZ system or in the CIE Lab system.

On the one hand, the entire process is very time-consuming because the different primary colors and the resulting mixed colors have to be calibrated one after the other in a time-consuming process. In addition, extra sensors must be procured and calibrated to achieve the desired result. Object of the present invention is therefore to provide a simpler and faster system that allows the calibration of a monitor in terms of brightness, but also in terms of color representation. To achieve the object, a system according to claim 1 is provided according to the invention. Advantageous embodiments are the subject of the dependent claims.

• 1. Den zu kalibrierenden Monitor
• 2. Ein handelsübliches Smartphone mit Kamera
• 3. Einen Speicher enthaltend aktuelle Daten über die Farbprofile von Bildschirmen, Smartphones, Druckern und Referenzbildern
• 4. Eine Recheneinheit, die ein über eine Smartphone aufgenommenes Referenzbild eines Monitors entsprechend der bauartbedingten Farbprofile der Smartphone-Kamera korrigiert, die erhaltenen Werte mit einem Sollwert vergleicht und anschließend die korrigierten Einstelldaten an den Monitor übermittelt.

The calibration system according to the invention contains the following components:

• 1. The monitor to be calibrated
• 2. A standard smartphone with camera
• 3. A memory containing current data on the color profiles of screens, smartphones, printers and reference images
• 4. An arithmetic unit which corrects a reference image of a monitor recorded by a smartphone according to the design-related color profiles of the smartphone camera, compares the obtained values with a target value and then transmits the corrected adjustment data to the monitor.

The arithmetic unit and the database can hereby be internet-based, in particular cloud-based, (eg PureScreen, Calibrain, Realpic) with current databases via profiles of the smartphones, screens, printers and reference images.

Commercially available smartphones contain cameras that are able to check the calibration of a screen in terms of resolution and color fidelity. For this purpose, a program "App" is loaded on the smartphone, which provides the smartphone with the essential functions.

Operation of the invention

The user is registered via an "App" (iCalibrate) program to be loaded by the user and given the opportunity to make contact with the data center or to calibrate, for example, a calibration. B. a monitor or printer to link.

• 1. Formblatt zur Angabe der a. zu kalibrierenden Geräte (z. B. Bildschirm HP LP2475w) b. Modell des Smartphones (z. B. Samsung Galaxy II) c. Daten zur „Remote-Desktopverbindung”, in der Regel eine exe-Datei.
• 2. Der Anwender erhält als Download d. ein oder mehrere Referenzbilder auf sein Smartphone e. ein oder mehrere Referenzbilder auf seinen Monitor.
• 3. Das Referenzfoto wird f. auf den Monitor geladen g. vom Smartphone fotografiert (ähnlich wie ein Barcodescanner) h. vom Smartphone erkannt, teilverarbeitet und auf den Server geladen i. Auf dem Server werden die aufwändigeren Analysen durchgeführt, z. B. in den Farbwerten und Verläufen verglichen, bewertet und aufeinander abgestimmt.
• 4. Sofern Farbabweichungen auftreten, werden die Kalibrierungsdaten (z. B. ROT 95%, Grün 87% etc.) an den PC gesendet, um den Monitor „online” automatisch zu kalibrieren.
• 5. Das Kalibrierungssystem gibt es als Einmal- oder Mehrfachanwendung und in unterschiedlichem Funktionsumfang, je nach Bedarf des Anwenders.

The app provides the smartphone (eg with iOS, Android or Windows operating system) with the following:

• 1. Form for indicating a. Devices to be calibrated (eg HP LP2475w screen) b. Model of the smartphone (eg Samsung Galaxy II) c. Remote desktop connection data, typically an exe file.
• 2. The user receives as download d. one or more reference pictures on his smartphone e. one or more reference pictures on his monitor.
• 3. The reference photo is f. loaded on the monitor g. photographed by the smartphone (similar to a barcode scanner) h. detected by the smartphone, partially processed and loaded on the server i. On the server, the more complex analyzes are performed, for. B. compared in the color values and gradients, evaluated and matched.
• 4. If color deviations occur, the calibration data (eg RED 95%, green 87%, etc.) will be sent to the PC to automatically calibrate the monitor "online".
• 5. The calibration system is available as a single or multiple application and in different functional scope, as required by the user.

Decisive for the functional basis of the system is that the color profile of each individual smartphone model is already contained in a database in order to compensate for the smartphone-related color error. For this, the color profiles of all commercially available smartphones are set in a database. In a particular embodiment of the invention, a color print is provided with a test image photographed under standard lighting conditions (5,600 Kelvin). In this way, the exact color profile is determined for unknown smartphone models and also inserted into the database.

The system first provides the monitor with a reference image, which is recorded by the smartphone. The smartphone also receives the recorded reference image. After recording the image of the reference image on the monitor, the smartphone compares the stored image with the recorded image to eliminate errors in recording (such as blurring, distortion, etc.). If the images match, the captured image is sent to the server. First, a correction of the color representation takes place on the server in order to correct the design-related color errors of the respective smartphone model. Subsequently, the actual color representation is compared with the desired color representation. Should deviations from the setpoints occur, then a new set of calibration data is sent to the monitor to calibrate it. If the color fidelity requirements are higher, the procedure is repeated to test the success of the calibration and, if necessary, to be able to continue to adjust it.

The data and transmission protocols necessary for the various data transmission operations are known to the person skilled in the art and need no further discussion at this point.

The invention therefore also relates to a method for calibrating monitors as shown above. Monitor can also be understood as a television monitor (TV set).

Claims (5)

Calibration system for monitors, comprising the following components: 1. the monitor to be calibrated 2. a standard smartphone with camera module 3. a memory containing current data on the color profiles of screens, smartphones, printers and reference images 4. An arithmetic unit which corrects a reference picture taken by a smartphone of a monitor according to the design-related color profiles of the smartphone camera, compares the obtained actual values with a set value, and then transmits the corrected setting data to the monitor. Calibration system for monitors according to claim 1, characterized in that the corrected setting data for the monitor are transmitted on-line (via Internet connection) to the monitor. Calibration system for monitors according to claim 1, characterized in that the corrected setting data for the monitor are transmitted to the smartphone and then manually set by the user. Method of calibrating monitors by means of a smartphone, comprising the following steps: a) download an app the smartphone, b) Loading the app with the following information b1. monitor to be calibrated b2. Smartphone model b3. Remote desktop connection of the monitor c. Download from c1. one or more reference pictures on the smartphone c2. one or more reference pictures on the monitor d) Recording of one or more reference images displayed on the monitor by the smartphone e) image recognition on the smartphone by comparison with the reference image from c1 f) sending the recorded reference image to a server g) Image analysis on the server by target / actual comparison of the recorded reference image with the actual reference image h) Transmission of the calibration data to the monitor. Method for calibrating monitors by means of a smartphone according to claim 4, characterized in that the calibration method is repeated one or more times.