KR102627419B1 - LED Digital Signage Defect Checking Device - Google Patents

Abstract

The LED digital signage defect detection device includes a display unit with a plurality of LEDs arranged in a display area for displaying content, a power supply unit that supplies power to the plurality of LEDs, and a plurality of currents that detect the current supplied to the plurality of LEDs. The detection unit stores the normal consumption current range for multiple LEDs for each luminance, determines the luminance of the content to be displayed on the display unit, and determines the normal consumption current value supplied to the multiple LEDs detected in response to the identified luminance. It includes a control unit that determines that the power supply is defective if it is determined that the current amount is outside the range.

Description

LED Digital Signage Defect Checking Device}

The present invention relates to an LED digital signage defect confirmation device, and more specifically, to an LED digital signage defect confirmation device that can predict and detect accidents by detecting current.

There are several ways to check for defects in digital signage. One commonly used method is to check screen quality. To this end, signage displays may include test patterns that check pixels, brightness, color, etc. You can use this pattern to verify that your display is operating correctly.

Additionally, since digital signage devices generally require a network connection, you must also check the network connection status. To do this, you can test your network connection and make sure you are connected to the Internet.

To check for hardware defects in digital signage, you can check the power supply status of the device and, if necessary, try rebooting the power. Additionally, you can inspect hardware components of digital signage that may be problematic (e.g. cable connections, batteries, etc.).

To check software defects, you can check bugs, errors, permission settings, etc. of the digital signage software. To do this, you can analyze system logs or try reinstalling or updating software.

However, due to the aging of internal parts of digital signage, abnormalities in the LEDs of the display unit that display content are not accurately identified, so there is a problem in which accident prediction and accident detection, such as fires due to power reduction or overload, are not achieved.

Therefore, the purpose of the present invention is to provide an LED digital signage defect confirmation device that predicts and detects accidents such as fire by accurately identifying the aging of internal components.

An LED digital signage defect checking device according to the present invention for achieving the above object includes a display unit having a plurality of LEDs disposed in a display area for displaying content; A power supply unit that supplies power to the plurality of LEDs; a plurality of current sensing units that sense current supplied to the plurality of LEDs; and storing the normal current consumption range for the plurality of LEDs for each luminance, determining the luminance of the content to be displayed on the display unit, and determining the current value supplied to the plurality of LEDs detected in response to the identified luminance. It includes a control unit that determines that the power supply unit is defective when it is determined that the current consumption is outside the normal range. After accurately determining the LED brightness corresponding to the content to be displayed on the display, it is possible to determine whether the current value supplied to the LED is outside the normal current consumption range to identify defects in the power supply, so accident prediction and accident detection can be achieved. Safety can be improved.

Here, the control unit performs a plurality of display tests on the plurality of LEDs according to luminance for a plurality of contents, and calculates the standard of expected current consumption based on the performed display tests to determine the basis for the normal current consumption range. It is desirable to be able to provide it.

And the control unit, while controlling the display unit to display the content, the plurality of current detection units detect a plurality of current values supplied to the plurality of LEDs, and the calculated expected current consumption standard and the detected plurality It is preferable to calculate the error range using the current value and set the normal current consumption range because it is possible to set the range of current value within which the component can operate stably.

Here, the control unit stores a threshold value for a plurality of current values for the content to be displayed on the display unit, and when it checks whether the power supply unit is defective based on the stored threshold value, it repeatedly checks the component for the current value. Since it is possible to monitor changes in and use this to calculate the threshold, it is desirable to check for defects in the current supply of the power supply unit based on the threshold.

And it further includes a communication unit that communicates with an external device, wherein the control unit controls the communication unit to transmit the determined information to the operator terminal when it is determined that the power supply unit is defective, thereby notifying the user of the defective power supply unit, thereby causing an accident. It is desirable because preliminary measures can be taken before the action.

According to the present invention, after accurately determining the LED brightness corresponding to the content to be displayed on the display unit, it is possible to identify defects in the power supply unit by determining whether the current value supplied to the LED is outside the corresponding normal current consumption range, thereby improving accident prediction and accident detection. This has the effect of improving safety against accidents.

In addition, it is possible to establish a basis for the normal current consumption range and to set a range of current values within which components can be operated stably.

In addition, since it is possible to repeatedly monitor changes in components with respect to current values and use this to calculate the threshold, defects in the current supply of the power supply can be confirmed based on the threshold, and defects in the power supply can be reported to the user. Notification has the effect of allowing proactive measures to be taken before an accident occurs.

Figure 1 is a control block diagram of the LED digital signage defect confirmation device according to the present invention.
Figure 2 is a flowchart for setting the normal current consumption range.
Figure 3 is an explanatory diagram for setting the normal current consumption range using the error range.
Figure 4 is an explanatory diagram for checking defects in the power supply unit using an LED digital signage defect confirmation device.
Figure 5 is a flow chart for checking defects in the power supply unit using an LED digital signage defect confirmation device.

Hereinafter, the LED digital signage defect checking device 1 according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a control block diagram of the LED digital signage defect confirmation device (1) according to the present invention, Figure 2 is a flow chart for setting the normal current consumption range, and Figure 3 is a flow chart for setting the normal current consumption range using the error range. Figure 4 is an explanatory diagram showing a defect in the power supply unit 20 using the LED digital signage defect checking device 1, and Figure 5 is an explanatory diagram showing a defect in the power supply unit 20 using the LED digital signage defect checking device 1. This is a flowchart for checking defects in the power supply unit 20.

The configuration of the LED digital signage defect confirmation device 1 will be described with reference to FIGS. 1 to 5.

The LED digital signage defect confirmation device 1 includes a display unit 10, a power supply unit 20, a current detection unit 30, a communication unit 40, and a control unit 50.

The display unit 10 has a plurality of LEDs disposed in a display area for displaying content.

The power supply unit 20 supplies power to a plurality of LEDs.

The current sensing unit 30 is comprised of a plurality of components that sense current supplied to a plurality of LEDs.

The communication unit 40 communicates with external devices. The communication unit 40 is wired communication and Ethernet-based communication.

The control unit 50 stores the normal current consumption range for a plurality of LEDs for each luminance, determines the luminance of the content to be displayed on the display unit 10, and supplies power to the plurality of LEDs detected in response to the identified luminance. If the current value is determined to be outside the normal current consumption range, it is determined that the power supply unit 20 is defective.

The control unit 50 performs a plurality of display tests on a plurality of LEDs according to luminance for a plurality of contents, and can calculate a standard for expected current consumption based on the performed display tests.

In a state where the control unit 50 controls the display unit 10 to display content, the plurality of current detection units 30 detect a plurality of current values supplied to the plurality of LEDs, and the calculated expected current consumption standard and The normal consumption current range can be set by calculating the error range using multiple detected current values.

The control unit 50 stores threshold values for a plurality of current values for content to be displayed on the display unit 10, and can check whether the power supply unit 20 is defective based on the stored threshold values.

If it is determined that the power supply unit 20 is defective, the control unit 50 may control the communication unit 40 to transmit the determined information to the operator terminal 2.

Figure 2 is a flowchart for setting the normal current consumption range.

Color luminance is displayed on the display unit 10 (S1).

Measure the current using the current sensing unit 30 (S2).

The current luminance and current measurement values are converted into data and stored (S3).

Figure 3 is an explanatory diagram for setting the normal current consumption range using the error range.

A draft is displayed on the display unit 10 (S11).

The current is measured for 1 hour using the current sensing unit 30 (S12).

Analyze the current histogram using the measured data (S13).

Set the normal current consumption range by calculating the error range (example: ±5%) that can cover most of the measurement range at the point where the distribution is the largest.

Figure 4 is an explanatory diagram for checking defects in the power supply unit 20 using the LED digital signage defect confirmation device 1.

Content is displayed on the display unit 10 (S21).

Calculate the expected current based on the content (S22).

The current current is measured using the current sensing unit 30 (S23).

Compare whether the measured current value is within the normal current consumption range (S24).

If the measured current value is outside the normal current consumption range, it is judged as overcurrent/undercurrent and a defect in the power supply unit 20 is notified to the user (S25).

If the measured current value is within the normal current consumption range, repeat from step S21.

Figure 5 is a flowchart for checking defects in the power supply unit using the LED digital signage defect confirmation device (1).

For a plurality of contents, a plurality of display tests are performed on a plurality of LEDs according to luminance (S31).

Calculate the standard of expected current consumption based on the performed display test (S32).

With the display unit 10 controlled to display content, the plurality of current detection units 30 detect a plurality of current values supplied to the plurality of LEDs (S33).

The error range is calculated using the calculated expected current consumption standard and multiple detected current values to set the normal current consumption range (S34).

The normal current consumption range for multiple LEDs for each brightness is stored (S35).

The luminance of the content to be displayed on the display unit 10 is determined (S36).

It is determined that the current value supplied to the plurality of LEDs detected in response to the identified luminance is outside the normal current consumption range (S37).

It is determined that the power supply unit 20 is defective (S38).

Modifiable embodiments other than the above embodiments will be described.

The current measurement unit is responsible for measuring and collecting the amount of current at the output terminal of the power supply unit and transmits the collected current current value to the control unit.

The display unit is arranged at equal intervals along the horizontal and vertical directions in a display area that displays characters and includes a plurality of LEDs corresponding to pixels. Multiple LEDs can be turned on/off to display characters in the display area. Converts the display signal to an LED signal. Determine the defective state of multiple LEDs (if it is difficult to determine depending on the type of electronic sign and environment, display white on a module basis and determine the defective state by comparing it with the current measurement value). If a defective LED condition is confirmed, the LED abnormality is notified through the communication department so that the operator can be notified.

The control unit controls the operation of devices (FAN, heater) inside the display unit. The control unit is connected to the illuminance sensor, collects the current state, and performs overall luminance adjustment through the display unit.

The communication department enables mutual communication with the operator. It receives the operator's control signals (change in display plan, FAN ON, brightness change), etc. and transmits them to each role responsible for the relevant control.

An accident prediction model is created by learning the current value for each display of the electronic signboard, and based on this, the presence or absence of an accident is confirmed through the accident prediction model based on the real-time current value when the electric signboard is operated. In addition, current abnormalities can be measured in the same way even when a defect in the LED module occurs, so to prevent this, check whether the LED module is defective. If an accident or defect is determined, the operating software sends a real-time alarm to the operator to facilitate inspection of the electronic signboard.

The control unit receives real-time pixel information (number of RED dots, green, blue in the current display) and set luminance value from the display unit and compares the expected current consumption with the measured current consumption. The control unit notifies abnormalities in the power supply unit through the communication unit so that the operator can be informed of overcurrent or undercurrent through comparison.

If a module defect is determined in the display unit, notification is postponed because errors in judgment of overcurrent or undercurrent may occur.

To calculate the expected current consumption, a RED, GREEN, and BLUE display test for each luminance is performed before shipment to calculate the standard value of the expected current consumption.

In order to determine the reference point for judging overcurrent and undercurrent, an aging test is performed on standard drafts (n items) to determine measurement error.

Due to the above-mentioned LED digital signage defect check device (1), the LED luminance corresponding to the content to be displayed on the display unit is accurately identified, and then the current value supplied to the LED is determined to be outside the normal current consumption range, and the power supply unit Since defects can be identified, accident prediction and accident detection can be performed, and safety against accidents can be improved.

In addition, the basis for the normal current consumption range can be established and the range of current values within which the component can be operated stably can be set.

In addition, since it is possible to repeatedly monitor changes in components with respect to current values and use this to calculate the threshold, defects in the current supply of the power supply can be confirmed based on the threshold, and defects in the power supply can be reported to the user. With notification, proactive measures can be taken before an accident occurs.

1: LED digital signage defect confirmation device 2: Operator terminal
10: Display unit
20: Power supply unit
30: Current sensing unit
40: Department of Communications
50: control unit

Claims (5)

In the LED digital signage defect confirmation device,
A display unit having a plurality of LEDs disposed in a display area for displaying content;
A power supply unit that supplies power to the plurality of LEDs;
a plurality of current sensing units that sense current supplied to the plurality of LEDs; and
Stores the normal current consumption range for the plurality of LEDs for each luminance, determines the luminance of the content to be displayed on the display unit, and determines the current value supplied to the plurality of LEDs detected in response to the identified luminance. If it is determined that the current consumption is outside the normal range, it includes a control unit that determines that the power supply is defective,
The control unit,
A plurality of display tests are performed on the plurality of LEDs according to luminance for a plurality of contents, a standard for expected current consumption is calculated based on the performed display tests, and an accident prediction model is created by learning the current value for each display time. Based on this, when operating the display unit, the presence or absence of an accident is confirmed through an accident prediction model based on the real-time current value, and current abnormalities can be measured in the same way even in the event of a defect in the LED module consisting of the plurality of LEDs to prevent this. An LED digital signage defect confirmation device that checks for defects in the LED module and controls to send an alarm in real time to the operator if an accident or defect is determined.
According to claim 1,
The control unit,
An LED digital signage defect checking device, characterized in that it performs a plurality of display tests on the plurality of LEDs according to luminance for a plurality of contents, and calculates a standard of expected current consumption based on the performed display tests.
According to claim 1,
The control unit,
In a state where the display unit is controlled to display the content, the plurality of current detection units detect a plurality of current values supplied to the plurality of LEDs, and use the calculated standard of the expected current consumption and the plurality of sensed current values. An LED digital signage defect confirmation device characterized by calculating the error range and setting the normal current consumption range.
According to claim 1,
The control unit,
An LED digital signage defect checking device that stores threshold values for a plurality of current values for content to be displayed on the display unit, and checks whether the power supply unit is defective based on the stored threshold values.
According to claim 1,
It further includes a communication unit that communicates with an external device,
The control unit,
An LED digital signage defect confirmation device, characterized in that when the power supply is determined to be defective, the communication unit is controlled to transmit the determined information to the operator terminal.

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