TR201911078A2 - IMAGING DEVICE NETWORKS AND METHODS TO TURN ON AND OFF THE DEVICES - Google Patents

Abstract

The present invention provides a method for opening a plurality of display devices, each comprising at least one main processor and a visual display unit controlled by that main processor. Said main processor may comprise, for example, a central processing unit mounted on the main circuit board of the display device. The method at least includes turning on the main processor of at least a major part of the display devices at a first time t2 and turning on the visual display units of the majority of said display devices at a later time tn. The present invention also provides a network comprising a plurality of such display devices and a server connected in communication with each of the plurality of display devices, together with a method of shutting down such multiple display devices by performing a similar sequence of operations in reverse time order. wherein said server configures the main processor of at least a major portion of the display devices to turn on or off at a different time than turning on or off respectively the visual display unit of the same display devices. These methods and the advantage of this type of network are to reduce the strain placed on this power distribution network by spreading the total change (dPi) in electrical power consumed from a power distribution network over a finite time period (dt).

Description

DESCRIPTION IMAGING DEVICE NETWORKS AND METHODS OF TURNING DEVICES ON AND OFF The present invention, with the method of turning on multiple display devices according to claim 1, With the method of turning off multiple display devices according to T and multiple according to claim 12 relates to a network with multiple display devices. PRIOR ART Large public facilities such as shopping malls, metro stations, airports and the like to view advertisements, arrival and departure information, facility maps and so on. may contain a number of display devices. These display devices can simultaneously often networked to display similar or related information at a different point is connecting. At least some of these display devices are sometimes It can also be interactive, allowing a user to access, for example, food outlets or a private interacting with the location of the store in the facility with a touch screen allows it to be determined. These imaging devices typically have a large surface area. area (for example 2 square meters or more) and a high level of lighting visual display units such as OLED or plasma display screens that require contains. This is typically a display device installed such as a screen backlight. obtained with the lighting unit. Therefore, these imaging devices have only one The electrical power consumption of one can be, for example, 150 watts. As a result many this type of display device, for example 200 units of this type of display device combined power consumption can be 200 x 150 = 30 kW.

This combined power consumption is high, for example before the public facility opens in the morning. If all display devices turn on simultaneously, there is a problem with the power-on process. creates. Sudden and large increase in electrical power consumption at such a moment, electrical power can create an unacceptably high load on the distribution network. draws a high current that the power supply cannot handle, and at the same time, have an undesirable chaining effect on other loads connected to the same power distribution network. can happen.

Thus, it is known in the prior art that there are various solutions that address this problem.

A possible solution that has been used is to finitely use multiple display devices that are different from each other. multiple viewing, randomly opening at different relevant times in the time period It is to spread the power-on of the device over a finite period of time, for example 5 minutes. This is possible the solution is to spread the increase in electrical power consumption over a longer time period Although it has the advantage of unacceptably high on the power distribution network, carrying the risk of creates a high load and the power supply still cannot handle draws a mind.

Therefore, a possible second solution that has been used is from multiple display devices. different ones at different times spanning randomly over a finite period of time Instead of turning on multiple display devices, different ones to a finite time period. emitted is to program it to open at the respective different selected times and the selected here times, a network communication associated with each respective from multiple display devices The module is programmed according to a unique media access control (MAC) address. This the possible solution has the advantage of reducing the risk of overloading the power distribution network control the process of turning on display devices at different times from each other. may require additional hardware to operate, this situation increases the cost and It also has the disadvantage that it may not be suitable for use in contexts.

Therefore, a possible third solution that has been used is from multiple display devices. different ones manually at different relevant times in a finite time period, e.g. to open it using a graphical user interface. However, this possible solution is risk of error and at the same time increase in labor costs. has.

In this regard, multiple display devices such as those found in large public facilities An advanced method of opening is needed.

PURPOSE OF THE INVENTION Therefore, the object of the present invention is the method of opening multiple display devices, a multi-display device shutdown method and a network with multiple display devices is to develop.

DISCLAIMER OF THE INVENTION For the purpose of the invention, with the method of opening multiple display devices according to claim 1 is reached. Each display device has at least one main processor and includes a visual display unit under the control of the processor. mentioned main The processor is for example a central processing unit mounted on the main circuit board of the display device. may contain the unit. The method at least requires imaging devices to at least trying to open the main processor of a part of it at a first time and turn on the visual display units of most of your devices at a later time. contains.

This solution typically means that the main processor of a display device is the display device. consumes only a small part of the total electrical power consumed by other components of the display device, for example, the visualization of the device display unit and the screen backlight to illuminate this visual display unit. It is useful because it makes a lighting unit like a light. For example, the total power consumption is 150 watts about 5 watts of power consumed by the main processor in a display device with in other words, the total power consumed by the display device. When the main processors of the large part are turned on at the first time, multiple views The combined power consumption of the device increases only by a small amount, and this amount is As in the previous art, multiple devices in which the devices are turned on completely at once is a very small amount of the combined total power consumption of the display device.

Each of the visual display units of most display devices after the first time each display device's processors are powered on. It can be opened at a given time or times. Multiple display devices the load given to the power distribution network is thus spread over a finite period of time, The current drawn from the said power distribution network decreases and in this way, the power distribution network strain also decreases.

Advantageous embodiments of the invention comply with any request and/or the following description. can be configured.

In some implementations, the method is to initialize the main processor of all imaging devices at the first time. open and the respective visual display units of multiple display devices, each may include opening at different relevant times after the first time. More than one turning on the main processor of the display device at the first time higher power than just turning on the main processor of most of them at the first time. consumption by each display device, while the main processor Since the power consumption network consumes only a small part of the total power, all of these It can easily overcome the opening together. On the other hand, this solution a ready-to-use base processor of the entire multi-display device It has the advantage that it can be launched as related visual display units of the device will spread the load given to the power distribution network. It can be opened at different relevant times in this way.

In other applications, the method is used after the first time but before the next time. at least one of the display devices, at least one of the display devices Receiving and displaying a notification that the main processor is running on a server display for at least one of their devices to open the visual display unit may include issuing a command from said server to at least one of its devices.

This solution allows the server to visualize at least one of the display devices. the main processor of at least one of these display devices before turning on the unit. It has the advantage that it can be sure that it is ready to work. same method preferably It can be applied to at least a large part of imaging devices, it is more preferred. the same method as in fully applicable.

Alternatively or additionally, in some embodiments, the method may use the visual display unit as the first. may include opening at a predetermined time after time, where predetermined time, by the visual display unit of the main processor. a time it takes to load an image file ready for viewing more than the period. Said image file is for example a part of the display device. It can be loaded from memory or by the display device, for example from a server. can be obtained. Predetermined time, eg visual display of main processor how much to upload an image file ready to be viewed by the unit visual display unit, by experimentally testing that it needs time After the main processor mentioned before powering on is turned on, the visual display unit is once notice that the image file appears immediately in the visual display unit when opened It can be determined in advance by increasing the time taken until the

This solution works as soon as the image file is opened by the visual display unit. has the advantage of being viewed.

In some applications, at least some of the display devices each loudspeaker, a sound processing unit for processing the sounds to be emitted by the speaker motionless and/or moving images to be displayed by the visual display unit a Video processing unit for processing images, a visual display unit a powered device, such as one or more of a lighting unit, etc. for lighting or more additional components. In such a case, the method its additional components, respectively, at the first time or after the first time, to the next time It may also include opening at the relevant times, up to or including this. This the solution is that the process of turning on at least some of the display devices is thus has the advantage of being converted to a series of correspondingly, increasing much less than the total power consumption for the display device. correlates with a corresponding increase in power consumed by display devices, thus further assists in spreading the load placed on the power distribution network. Same The method preferably works with at least a large number of imaging devices. can be applied, more preferably the same method, multiple viewing It can be applied to all display devices in the device.

A loudspeaker of one or more powered additional components will be emitted by the speaker. a sound processing unit for processing sounds, said visual display unit A tool for processing still images or moving images to be viewed by a lighting for illuminating the video processing unit and the visual display unit the method also includes said audio processing unit and video processing unit. turn on the unit at the first time, the speaker from the first time, to the next time to turn on and the lighting unit at a time as long as or including this time. may include opening at or near the next time. This As soon as the solution is switched on, the speaker and visual display unit, the audio processing unit and the Video an audio signal to the speaker and a Video to the visual display unit, respectively, of the processing unit. it has the advantage that it can be ready to provide the signal, thus moving images are produced by said visual display unit itself and is displayed as soon as the lighting unit is turned on and the speaker is stationary and/or as soon as motion pictures start or before they start, still and/or motion pictures It is ready to emit any sound involving images.

The technique of the present invention can also be applied in reverse. Thus, the present invention one of which is at least one main processor and an image that is under the control of that main processor. also related to the method of turning off multiple display devices including the display unit wherein said method is at least one of the relevant multiple display devices. shutting down the visual display units at the relevant third times and multiple the main processors of the respective ones from the display device, each from the respective third time the subsequent corresponding fourth time includes closure. described here similar to the method of turning on multiple display devices, This method of turning off multiple display devices finitely the load given to a power distribution network by spreading the shutdown process over a period of time. has the advantage of reducing the power drawn by the said power distribution network. The magnitude of sudden changes in total power and the strain in the power distribution network are reduced.

In some applications, the corresponding fourth tenses are substantially the same time. can happen. Interconnect the main processor of all multiple display devices at the same time, turning off, on power consumption, the main processors of display devices While it creates a larger decrease than closing at different times from each other, the main The processor is only a small part of the total power consumed by each display device. Since it consumes the part of the power distribution network, it is easy to turn off all together. is able to overcome. On the other hand, this solution allows multiple display devices It has the advantage that it can be closed together.

In other embodiments, at least one of the display devices is powered by one or more may contain additional components. In such a case, the method is the most efficient of the imaging devices. at least one of them is powered by additional components, respectively, mentioning display devices up to or including the fourth time for at least one at the third time or third time for at least one of these display devices may include shutting down at relevant times after that time. This solution does not display thus converting the process of turning off at least one of its devices into a series of steps each of these steps has the advantage that at least one of the imaging devices correlates with a corresponding decrease in the power consumed by the It helps to lower the given load more easily.

Preferably, between the first time and the next time, or between the third time and the fourth time. a time period between 100 seconds and 1000 seconds, more between 200 seconds and 800 seconds as preferred, again more preferred Its shape is between 300 seconds and 600 seconds. On the one hand, these time periods By correcting sudden changes in the load given to the distribution network, on the other hand, a suitable short completely turning multiple display devices on or off over time. is, in turn, more successful in striking the balance between the need for realization.

The present invention also uses one or more of the methods described herein. a computer program product or a program code or relates to the system.

The present invention also includes each of at least one core processor and a plurality of display devices comprising a visual display unit under its control; and connected to communicate with each of the multiple display devices a primary processor, at least most of the display devices. to open at the same time and visualize a large part of the said imaging devices. containing a server that is configured to turn on the imaging unit at a later time. a master is related to a network. Said server preferably contains all display devices. it is configured to boot its main processor at the same time as each other.

In some applications, multiple display devices and servers communicate with each other in two ways. the main processor of each of the multiple display devices, a notification to the server that it has been run after it is turned on and running can be configured to send and said server Upon receipt, one of the display devices to turn on the visual display unit can be configured to command one of them.

In other applications, multiple display devices and servers are bidirectionally interconnected. can be in communication, the main of at least one of the multiple display devices processor by the visual display unit after it is turned on and powered up. upload a ready-to-view image file and send it to the server for visual display a message indicating that it has uploaded the image file ready to be viewed by the unit. can be configured to send notifications and said server display to open the visual display unit upon receipt of the notification It can be configured to give a command to one of the related devices. Preferably, the main processor of at least most of the display devices, again more display devices on multiple display devices as preferred the main processor of all is configured in this way.

In some implementations, the server also stores the corresponding ones of multiple display devices. will turn off the visual display unit at the corresponding third times, and multiple display the main processor of the corresponding ones of the device, each of which comes after the corresponding third time. it can be configured to command to turn off at fourth times.

Other benefits, objects and features of the present invention are examples of components of the invention. will be explained through the following explanation of the attached figures. At least the function Components and methods of systems according to the invention, which are essentially overlapping, are in the same reference may be marked with , where such components may be marked in all such figures. or not required to be disclosed.

The invention is described in the following description by way of example only by reference to the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES Figure 1 is a prior art method of turning on multiple display devices. is a graph that schematically represents; Figure 2 is a schematic block diagram of an application for a display device network; Figure 3 is a schematic crap diagram of an implementation of a display device; and Figure 4 schematically illustrates an application for the method of turning on multiple display devices. DETAILED EXPLANATION OF SHAPES Figure 1 is a prior art method of turning on multiple display devices. show semantically. The x-axis of time measured in seconds in the graph in Figure 1 or on the apse, and power in watts is plotted on the y-axis or ordinate. This is the previous In the method belonging to the technique, all of the multiple display devices are opened at t1 time, which is the power of multiple display devices as indicated by dP1 in Figure 1. leads to a large increase in consumption. Such a large increase in dP1 power consumption undesirable effects on other loads connected to the same power distribution network. creates a strain that can have a chaining effect.

Figure 2 schematically illustrates an application related to a display device (10) network (1). 10q, 10r, 102) and a server (20). Multiple in the app shown connected in one-way communication. However, in other possible applications, multiple the display device can only be connected to the server (20) in one-way communication, the server mentioned here can send commands to each display device however, multiple display devices can only be used to receive and process such commands. configured, however, it cannot transmit information to the server. shown connected to the server (20) in a star-shaped configuration. However, other possible 102) can be connected to the server (20) in many different possible configurations. For example, suddenly it can also be connected to the server (20) via a common bus. at least, as both will be explained in detail in relation to Figure 3 below. It includes a main processor and a visual display unit. Server (20), below Each display in a way that will be explained in more detail in relation to Figure 4, to turn on the main processor of the device at a first time and ensure that each display device it is configured to open the visual display unit at a later time. Each The main processor of the display device is sent to the server (20) after it is turned on and powered up. It is configured to send a notification when it has been run, and the server upon receipt of said notification, to open the visual display unit It is configured to command a corresponding one of the display devices.

Display devices (10) such as those found in the network (1) shown in Figure 3, Figure 2 schematically shows an example application of one of them. a viewing This example implementation of the device (10) consists of a main processor (2), one or more speakers. (4) is a sound for processing sounds to be emitted by one or more speakers (4). processing unit (6), a visual display unit (8), said visual display unit (8) for processing still and/or moving images to be viewed by backlight for illuminating the video processing unit (12), the visual display unit (8) such as a lighting unit (18). Said main processor (2), either directly or Video processing with the audio processing unit (6), which is in two-way communication with the main processor (2). Check the operation of the other components of the display device (10) via the unit (12). is doing.

The main processor (2) is, for example, a display device (10) mounted on a main circuit board. may include the central processing unit. This central processing unit is a single integrated circuit. or it may contain more than one integrated circuit. Main circuit board, central processing unit as well as different auxiliary components mounted therein. For example, at least one of the audio processing unit (6) and the video processing unit (12) it can also be mounted on the main circuit board of the display device (10). Image the display unit (8) displays, for example, an OLED display screen or a plasma may include display screen.

Display device (10); a primary for powering one or more loudspeakers (4) a power unit, a second power unit for powering the lighting unit (18), a memory, a network communication module, a coprocessor, etc. such as one or the other not shown in Figure 3 may contain more other components. On the other hand, the one shown in Figure 3 Example application of display device (10) for both speaker (4) and sound processing unit (6), this display device (10) may not be featured, so in such a device (10) the components (4, 6) may not be available, so you can only view silent still and/or moving images. can view.

Figure 4 is for opening multiple display devices such as those shown in Figure 2. schematically shows an application of a method. In the chart in Figure 4 time measured in seconds is again plotted on the x-axis or abscissa, and power measured in watts is again plotted on the x-axis or abscissa. Drawn on the y-axis or ordinate. In this method, multiple views at time t2 By turning on only the core processors (2) of the device (10), multiple display devices can be This causes an increase in power consumption as indicated in Fig. From Figure 4 As can be seen, this increase in power consumption (dPg) corresponds to the prior art shown in Figure 1. The artistan in power consumption (dP1) of the respective method is considerably less. shown in Figure 4 In the embodiment of the method, one or more of the multiple display devices (10) loudspeaker (4), visual display unit (8), lighting unit (18), etc. other components such as are opened sequentially at consecutive times (t3, t4, tm, tn_1 and tn). From Figure 4 As can be seen, each of these sequential trips is in power consumption (dPs, dP4, dPn-2, dPm and dPm) lead to a corresponding increase, each of which is shown in Figure 1. substantially less than the increase in power consumption (dP1) of the prior art method shown is happening. Thus, the increase in power consumption (dP1) of each display device is the same as in Figure 1. in contrast to the step change indicated by dP1 in the prior art method, a finite time It is spread over the period (dt). In addition, the overall increase in power consumption spreads said finite time period (dt) is determined by the visual display unit of the main processor. time required to load an image file ready for viewing more than the period. Therefore, as soon as the visual display unit is turned on at tn time, image file ready to be viewed by said visual display unit is happening.

An application of how to turn off multiple display devices is shown in Figure 4. may have a graph-like appearance, where each display device Progressive shutdowns to shut down various different components are reversed over time. is converted, but the total decrease in power consumption (dpi) of each display device and the finite time period (dt) over which this drop in power consumption spans remains the same.

In summary, the present invention therefore requires at least one core processor and each of that core processor multiple display devices including a visual display unit under its control. It provides a method for opening it. The main processor mentioned is, for example, imaging It may include a central processing unit mounted on the main circuit board of the device.

The method is at least the main part of at least most of the imaging devices. turn on the processor in a first time and a large amount of said display devices includes turning on the visual display units of the part at a later time. Available The invention also provides for multiple such operations by performing a similar sequence of operations in inverse time order. multiple such display device and in communication with each of the multiple display devices provides a network containing a connected server, wherein the server mentioned is the main processor of at least most of the display devices, the same display different from turning the visual display unit of the devices on or off respectively. It is configured to open or close at any time. These methods and such a The advantage of the network is that the total change in electrical power consumed from a power distribution network is finite. spread over a period of time, this is to reduce the strain placed on the power distribution network.

Claims (15)

REQUESTS 1. A method for turning on a plurality of display devices (10), each comprising at least one processor (2) and a visual display unit (8) controlled by that processor, such that at least: most of the display devices (10) turning on at least a large portion of the CPU (2) at a first time (tz); and turning on the visual display units (8) of a large portion of said display devices (10) at a time (tn) after the first time (t2). 2. A method according to claim 1, comprising turning on the main processor (2) of all imaging devices (10) at the first time (t2); and turning on the respective visual display units (8) of the plurality of display devices (10) at different respective times each following the first time (tz). A method according to claim 1 or claim 2, wherein after the first time (tz) and before the next time (tn): at least one of the display devices (10), the main processor (2 of the at least one of the display devices (10) ) receiving a notification on a server (20) that it has been run; and giving a command from said server (20) to at least one of the display devices (10) to turn on the visual display unit (8) of at least one of the display devices (10). 4. A method according to any of the preceding claims, wherein the visual display unit (8) turns on at a predetermined time (dt) after the first time (t2), the predetermined time (dt) the visual display unit (8) of the main processor (2). ) for more than a period of time to load an image file ready to be viewed. A method according to any one of the preceding claims, wherein at least some of the display devices (10) each further comprise one or more powered additional components (4, 6, 12, 18) and said method: additional powered components (4, 6, 12, 18). . A method according to claim 5, wherein one or more powered additional components (4, 6, 12, 18) comprise a loudspeaker (4), a sound processing unit (6 for processing sounds to be emitted by the speaker (4)). ) comprises a Video processing unit (12) for processing still and/or moving images to be displayed by said visual display unit (8) and a lighting unit (18) for illuminating the visual display unit (8) and method: said sound processing turning on the unit (6) and the Video processing unit (12) at the first time (Trace); turning on the loudspeaker (4) at a time after the first time (t2), up to or including the next time (tn); and turning on the lighting unit (18) at or near the next time (tn). 7. A method for shutting down multiple display devices (10), each comprising at least one processor (2) and a visual display unit (8) under the control of that processor, said method comprising at least: more than one display device (10) ) to turn off the visual display units (8) of the relevant ones at the relevant third times; and shutting down the core processors of the respective ones of the plurality of display devices (2) at respective fourth times each after the respective third time. 8. A method according to claim 7 wherein the respective fourth times are substantially concurrent with each other. A method according to claim 7 or claim 8, wherein at least one of the imaging devices (10) also comprises one or more additional powered components (4, 6, 12, 18) and the method: one of the imaging devices (10) ) additional components (4, 6, 12, 18) of at least one powered up, respectively, to at least one of the display devices (10) up to or including the fourth time for said at least one of the display devices (10). It includes closing at the third time or after the third time at the relevant times (tg, t4, tn_2, tn_1). 10. A method according to any preceding claim, wherein a time period (dt) between the first time (t2) and the next time (tn) or between the third time and the fourth time is in the range of 100 seconds to 1000 seconds. 11. A computer program product or a program code or system for performing a method according to any preceding claim. 12. A network (1) comprising multiple display devices (10a, 10b, 10c, 10n, 10p, 10q, each of which includes at least one core processor (2) and a visual display unit (8) controlled by that core processor. 10r, 102); and to turn on the main processor (2) of at least a large part of the display devices (10) in communication with one of them at a first time (Trace), and to turn on the visual display unit (8) of a large part of said display devices (10) at a later time. It includes a server (20) configured to open at time tn. 13. A network according to claim 12, wherein: (20) are in two-way communication with each other; one's main processor (2) is configured to send a notification to the server (20) that it has been up and running after it has been powered up; and the server is configured to command one to open the visual display unit 8 upon receipt of said notification. A network according to claim 12 or claim 13, wherein: (20) are in bidirectional communication with each other; the main processor (2) of one of the lesser ones is configured to load an image file ready to be viewed by the visual display unit (8) after it is turned on and run, and to send a notification to the server (20) that it has uploaded the image file ready to be viewed by the visual display unit (8). ; and the server is configured to command one to open the visual display unit 8 upon receipt of said notification. A network according to any one of claims 12 to 14, wherein the server (20) shuts down the visual display unit (8) of the respective ones of the plurality of display devices (10) at the respective third times; and the respective ones of the plurality of display devices (10) may be configured to command the main processor (2) to shut down at the respective fourth times each after the respective third time.