EP3628623A1 - Configuration of a graphical user interface for elevator control devices - Google Patents

Abstract

The invention relates to a configuration system, a method and an elevator with a configuration system for a graphical user interface of a control panel (COP), which is provided in the interior of an elevator (CAR), comprising: an application (A) for controlling the user interface; Network connection (NW) between the application and a server (S, GS) on which at least one update for configuration of the user interface can be loaded; the application (A) being designed with a GET UPDATE message to the server (S, GS) access to read in the update and execute it directly.

Description

The invention is in the field of elevator technology and control electronics and relates in particular to the configuration of a user interface for an application for elevator control.

The electronic controls of passenger transportation systems, such as elevators, require the input of user control signals. Graphical user interfaces are often used for this.

The graphical user interfaces include a hard-coded component that defines the design and the functional behavior of the user interface. This component is available as compiled program code. Is it now - e.g. during the operation of the elevator - if the surface has to be adapted to the current operating conditions (e.g. the floor names change or a floor should no longer be accessible due to construction work), it is customary to adapt predefined parameters. These are read in by the application. To apply the new parameters, however, the application must be recompiled. In the case of the user interfaces known in the prior art, it is therefore a disadvantage that the program code of the user interface has to be re-compiled (recompilation), which is associated with increased expenditure of time and resources. In tall buildings, there are sometimes long elevator travel times. This requires additional safety measures and functions for the passenger compartment during elevator travel. For example, Building-specific emergency programs are used if one of the people carried in the elevator e.g. has a psychological or medical problem. It is important to be able to adapt the emergency programs to the respective operating conditions (e.g. longer maximum travel time, building height, etc.). In the prior art, this was only possible to a limited extent or not at all due to the limited possibilities due to the predefined parameter set.

Browser-based user interfaces (e.g. so-called BUIs - browser graphical user interfaces) generally offer a more flexible adaptation of the design of the interface, but they cannot be used for applications for operating and controlling elevators, since the application and its configuration are used for security reasons The responsibility of the elevator manufacturer or operator must remain. It must be excluded that third parties influence the application. In addition, it should be possible that the configuration can be implemented directly on the executable program code of the application.

So it shows EP 3 015412 B1 an example of the design of a user interface for a floor control panel of an elevator, a so-called representation description on a local server is available. The arrangement of a touch-sensitive control panel in the interior of the elevator and corresponding applications for the control panel are not described in this document.

Starting from the known state of the art, the present invention has set itself the task of being able to implement building-specific security measures by means of an expanded configuration option for the design of graphical user interfaces, which are provided on a control panel in the interior of the elevator and enable corresponding functions. In addition, the adaptability of the user interface-based control system for an elevator system is to be improved. Furthermore, the disadvantages described above from the prior art are to be overcome.

This object is achieved by the respective subject matter of the attached independent claims, in particular by a configuration system, an elevator with a configuration system, a method, the use of the method and a computer program. Advantageous embodiments are the subject of the dependent claims, the description and the drawings.

• Eine Applikation zur Steuerung der Benutzeroberfläche;
• Eine Netzwerkverbindung zwischen der Applikation und einem Server, auf dem zumindest ein Update zur Konfiguration der Benutzeroberfläche ladbar ist;

wobei die Applikation ausgebildet ist, mit einer GET UPDATE Nachricht auf den Server zuzugreifen, um das Update einzulesen und direkt auszuführen.According to a first aspect of the invention, the object is achieved by a configuration system for a graphical user interface of a control panel, which is provided in the interior of a passenger transport unit. The passenger transport unit is, in particular, an elevator. The control panel is preferably integrated or installed as a touch-sensitive control panel in a wall of the elevator that can be operated from the interior. The control panel can be detachably fastened with security measures in order to make it easy for a maintenance person to replace it in the event of a fault. The security measures are designed in such a way that it is not possible for the elevator operator to steal the control panel, but rather to perform certain actions that are only available to maintenance personnel (e.g. digital or analog keys, etc.). The configuration system includes:

• An application to control the user interface;
• A network connection between the application and a server on which at least one update for configuration of the user interface can be loaded;

the application is designed to access the server with a GET UPDATE message in order to read in the update and execute it directly.

In other words, the solution relates to the global provision of a definition or configuration file for the configuration of a user interface, the definition file being able to be read in, interpreted and executed without having to restart the system or the application. This advantageously makes it possible to create a graphic Provide control panel directly in the elevator, the user interface of which can be flexibly adapted to dynamically changing operating conditions of the building without the need to restart the application. The configurations can relate in particular to the implementation of local security functions (building-specific). This can improve the security of the system for the user.

In a preferred embodiment of the invention, the server is designed as a local web server. The local web server is located in the local network of the elevator and can be addressed by the application via an internal network connection (e.g. LAN). He can e.g. in the administration area of the elevator (e.g. in a shaft area that is not accessible to the public). Alternatively, the server can also be arranged as a central entity which is in data exchange via a network connection. This has the advantage that cross-elevator or cross-building and global configurations are possible for several elevators or buildings. It is also possible to combine the two alternatives above, so that a local server and a global server are integrated into the system in order to carry out corresponding configurations (local or global in nature). The local server is then in data exchange with the global server (and is configured with a configuration interface) in order to e.g. read global configurations.

In a further advantageous embodiment of the invention, the update is provided in a configuration file and can be carried out without compiling the application. The configuration file or the update is preferably provided in a script language. This has the advantage that the update can be carried out immediately by interpreting the source text and without a separate translation phase. The changes can e.g. be recorded via an XML file. This has the advantage that the configurations can be implemented immediately and without loss of time, especially during the runtime of the application.

In a further advantageous embodiment of the invention, the application sends the GET UPDATE message to at least one server based on events and / or periodically. This has the advantage that it is ensured that the configurations are kept continuously updated. The time pattern or the trigger events can advantageously be configured.

In a further advantageous embodiment of the invention, a configuration means is provided in order to change, delete and / or create the configuration file on the server. The configuration of the user interface (also called UI) by means of the configuration means is used for building-specific adaptation of the UI to dynamically changing requirements (eg changing the floor name). Here in particular, safety-related Functions are implemented (e.g. in the case of a hospital elevator, adjustment of the door opening times to emergency events).

The above-mentioned object is further achieved by an elevator with a configuration system as described above.

• Senden einer GET UPDATE Nachricht von einer Applikation zur Steuerung der Benutzeroberfläche an einen Server;
• Zugreifen des Servers auf einen Speicher, um zu prüfen, ob ein Update zur Konfiguration der Benutzeroberfläche verfügbar ist und bejahendenfalls:
• Laden des Updates durch die Applikation und Anwenden des Updates zur Konfiguration der Benutzeroberfläche.

In a further aspect, the invention relates to a method for configuring a graphical user interface of a control panel, which is provided in the interior of an elevator. The process includes:

• Sending a GET UPDATE message from an application to control the user interface to a server;
• Access the server to a memory to check whether an update for the configuration of the user interface is available and if so:
• Loading the update by the application and applying the update to configure the user interface.

According to a preferred embodiment of the invention, the loading and application of the update can be carried out at runtime of the application. This means that the update can be applied without restarting the application and without recompiling the application. In practice, this proves to be an important advantage, since minor adjustments can be implemented quickly, easily and without complications. In particular, the building manager can access a local maintenance tool that enables an intuitive user interface for entering the configurations. This has the advantage that it is not necessary for the building manager to have software know-how to e.g. To be able to make changes to the XML files. In addition, the building manager's powers and access rights can be limited and monitored using the maintenance tool.

According to another preferred embodiment of the invention, the update relates to the execution of building-specific, safety-related functions of the elevator. In this way, emergency call functions can be implemented that can be triggered from the inside of the elevator while the elevator is moving, for example in the event of longer downtimes or in the event of an error. For example, a safety control panel can be configured which, by means of a graphic design of a safety field, indicates that an automatic safety function is carried out after a displayed period of time (e.g. an emergency call is activated). In particular, the safety function can include initiating a video conference between an (external) caregiver and the elevator occupants. The time period can preferably be displayed dynamically and graphically, for example in the form of a slider that can be moved on a time interval representation. Of the In the manner of a stopwatch, the slider shows the time remaining until the safety function is triggered if the safety field is operated in the intended manner.

In a further advantageous embodiment of the invention, the update is generated dynamically in response to sensor signals that were recorded in the elevator and preferably in the same time period (as for generating the update). This makes it possible to react immediately to operating conditions in the elevator during elevator travel. If e.g. Temperature sensors signal that the temperature exceeds a predefined threshold value, can be automatically configured so that the update outputs an air conditioning option on the user interface to enable the elevator occupants to choose the air conditioning (here cooling) of the elevator or to determine its value. This serves to be able to react quickly and immediately to the current requirements. Security functions can preferably also be configured here. If e.g. If it is sensed or by pressing a corresponding actuation button on the UI that an injured person is in the elevator, a configuration setting that offers automatic emergency doctor alarming on the UI can automatically be called up from the server.

The method described above can preferably be designed as a computer program for an elevator. The computer program can be loaded into an internal memory of an electronic unit and in particular into the application and can comprise software routines with which the steps of the method described above are carried out when the software routines are executed on the electronic unit. It is also possible for the computer program to be stored on a medium that can be read by the computer or the electronic device. The method and in particular the computer program are used to operate an elevator.

Another solution to the problem is a computer program product for a passenger transportation system that is loaded or loadable into a memory of a computer or an electronic device with a computer program for performing the method described in more detail above when the computer program is executed on the computer or the electronic device. The computer program product can be loaded into an internal memory of a digital control unit.

The terms of this application are defined below.

The update is preferably a digital file. For example, it can be defined in a scripting language. This has the advantage that - depending on the operating system used - no additional software and no translation is required for execution. However, it is sufficient to put the executable in one Copy directory that is located, for example, in the path of the operating system. The newly configured application or update can then be used directly by calling up a command line. The update can concern several parameters, in particular a selection of the displayed icons or control panel elements, an output speed of a video display (slow motion, accelerated, etc.), a resolution and other technical parameters.

The graphical user interface (hereinafter also referred to as GUI) is preferably installed on an electronic device which is arranged inside the elevator. The device can e.g. to be a tablet. The graphical user interface is preferably window-based and can comprise several layers, e.g. a graphic shell, a display server, a kernel, a window manager and the hardware. The graphical user interface can be integrated into an operating system and / or into the application. The graphical user interface is used to record user input and to control the application. The graphical user interface is specifically designed for the tasks in elevator operation, e.g. the display of the selectable or approachable floors with additional information if necessary. Icons (image symbols) represent access to files and functions. The GUI system enables windows and, if necessary, sub-windows (also dialogs and messages, such as security messages are windows) and, if necessary, changing their size and position, for example enlarging to total screen size, or hide it. Graphical user interfaces are available for many multi-purpose operating systems or even integrated into them. Other controls are buttons (buttons, knobs), switches and controls (sliders), toolbars (toolbars, toolbars), selection lists or menus.

The application can be integrated in an electronic calculation unit, which can be embodied in hardware as an integrated circuit (for example as an FPGA, field-programmable gate array) in an embedded system and / or in software. The application is used to calculate signals for a screen output. The application can be implemented directly in a graphics card or in a graphics chip or indirectly on a processor unit which is in data exchange with the graphics card and with a monitor. The graphics card writes data for the monitor to a graphics memory, which is usually designed as RAM (random access memory). The processor unit and / or the graphics chip or the graphics card read the memory in order to display the stored data - usually via a digital-to-analog converter - on the display. A video adapter can optionally be implemented, which uses the digital signals of the application program, stores them in the memory (eg video RAM) and converts them into an analog signal (using a D / A converter). The application is used for operating state-dependent control of the control panel to display the dynamically configured screen output in the elevator. The screen output can be regulated via sensor data of a sensor unit depending on the operating state of the elevator.

The control panel is installed inside the elevator, in particular at an operating height, that is to say in the average head height or viewing area on an inside wall of the elevator. The inside wall of the elevator is preferably not movable in order to simplify installation and assembly (no door element). The control panel is preferably designed as a touch-sensitive screen or touch screen. A capacitive sensor technology is preferably used for the screen elements.

In a preferred embodiment of the invention, a capacitive touchscreen technology, e.g. with multi-sensor functionality, in which simultaneous touches can also be detected. The touchscreen usually comprises a touchscreen sensor as the actual input and output unit, a controller that can be arranged in or on the touchscreen sensor and optionally a driver that can be arranged in the operating module. In an alternative and likewise preferred embodiment of the invention, the touchscreen sensor can be designed as a projected-capacitive sensor (usually called "PCT" = "Projected Capacitive Touch" or "PCAP"). The sensor uses two levels with a conductive pattern (e.g. stripes or diamonds). The levels are isolated from each other. If a finger is at the intersection of two strips, the capacitance of the capacitor changes and a larger signal arrives at the receiver strip. This signal change can thus be measured precisely on the basis of the X and Y coordinates, it also being possible to exactly define several contact points. The current flow from the corners of the touchscreen to the point of contact is proportional to the XY coordinates. The main advantage of this system is that the sensor can be attached to the back of the cover slip, since the touch detection is "projected" through the glass. It is operated on the practically wear-free glass surface. It is also possible to recognize gestures and multiple touches (i.e. multi-touch). In other embodiments of the invention, however, resistive or inductive or other sensor technologies can also be used for touchscreens. The control panel basically represents a user interface (in particular a graphical one) and includes the sensor for recording the input signals for controlling and operating the elevator, as well as a display on which interaction surfaces, switching elements, control fields and / or input fields for controlling the elevator can be shown.

Multi-touch screens represent an interactive user interface, a natural user interface (NUI) that interacts with finger movements. While a normal touchscreen reacts to the touch of a finger or pen, multi-touchscreens react to multi-finger input. With multi-touch screens, a distinction is made between touch screens that have two points of contact at the same time recognize and others who detect more than two fingers, so that several people can simultaneously make inputs on a larger multi-touchscreen.

In addition to the visual HMI interfaces, there are also acoustic ones, which can be important in certain elevator applications (e.g. in the medical field) and are designed for voice interaction with the elevator occupants and e.g. enable the user not to have to come into contact with the control panel to make entries, but to be able to move freely (e.g. transporting disabled people or in an emergency). These methods require multi-channel input and playback techniques as well as intelligent signal processing.

The configuration system is used to import configurations for the application to control the user interface. The user interface is used to operate passengers in the elevator while driving. In particular, destinations and other travel requests can be entered here. In addition, meta information about the entered destinations can be displayed, e.g. which institutions are located on the selected floor or, in the case of cross-floor institutions, which floor is the entrance and the reception.

In the following detailed description of the figures, exemplary embodiments to be understood in a non-restrictive manner are discussed with their features and further advantages with reference to the drawing.

Brief description of the figures

• Fig. 1 eine schematische Übersichtsdarstellung eines Konfigurationssystems anhand eines Ausführungsbeispiels;
• Fig. 2 eine detailliertere, schematische Ansicht einer Interaktion der Applikation und
• Fig. 3 ein Ablaufdiagramm für das Verfahren zur Konfiguration gemäß einer vorteilhaften Ausführungsform der Erfindung.

Show it:

• Fig. 1 a schematic overview of a configuration system based on an embodiment;
• Fig. 2 a more detailed, schematic view of an interaction of the application and
• Fig. 3 a flowchart for the method for configuration according to an advantageous embodiment of the invention.

Detailed description of the figures

The invention is described in more detail below on the basis of exemplary embodiments in connection with the figures.

In Figure 1 is a schematic overview representation of a configuration system according to an embodiment of the invention.

The in Figure 1 The elevator designated by the reference symbol CAR comprises an operating panel COP (car operating panel) inside. The control panel is designed as a touch-sensitive touch screen, which is controlled by an application A. The application can be installed on a computer unit, for example a microprocessor, and can be located locally in the elevator or in the administration area of the elevator outside the elevator. It is not freely accessible. The application A is in data exchange with a local server S, which is also located in the administration area of the elevator and in the building. The server can be designed to include a local maintenance tool LMT, which is used to operate the application and with which the caretaker can operate the application. The server S can be in data exchange with a global server GS, which can be web-based and is used for the global configuration of applications that are to be carried out across buildings. A system configuration tool SCT can be provided on the global server GS, via which an expert can make configurations. To do this, he can, for example, create XML files and load them onto the global server GS. These are then either read in by the local server S and forwarded to the application A, or read in directly by the application A.

Fig. 2 shows a section of an inner wall 10 of the elevator CAR with the control panel COP, which is controlled by the application A. The application A sends a GET UPDATE message according to a protocol (eg http or http / s) to the server S, which then accesses a memory DB, which can be designed as a database. The database DB can either be located locally in the server S or can be connected to the server as an external instance via a data connection. This is said in Figure 2 can be expressed by the dotted representation of the database DB. If an update is available, this is sent in a message to the application or to the platform on which application A is running. The message is preferably packed or compressed. In addition, it can be encrypted and / or signed in order to increase security and to guarantee the authenticity and integrity of the message (and thus the authorship of the instance issuing the update). Since this is a script, this can be implemented and executed directly by application A without the application having to be compiled and restarted. This improves the availability of the elevator when importing new configuration files.

Fig. 3 10 is a flowchart in accordance with a preferred embodiment of the invention. After the start of the configuration process, a GET UPDATE message is sent to the server S, GS in step S1. This checks in the database DB whether an update is available and, if so, sends it via the network NW to application A or the corresponding platform (eg to the LINUX kernel). The new configuration that has been transferred with the update can be implemented directly and can be carried out immediately.

The graphical user interface can preferably be an Android UI, e.g. in the form of an XML file. It can contain multiple, nested layouts - and within these layouts multiple views, such as text fields or buttons. Layouts and views can be designed using additional attributes. Size, colors, distances can be set relatively or absolutely. There are also corresponding editors that support the developers in designing the UI. The system configuration tool SCT is used for this. If you want to adapt a UI element at runtime, you can use an assigned ID / ID e.g. reference in Java and assign the desired attribute values. This can be done, for example: in a so-called activity - i.e. a class that manages the life cycle of the UI control panel COP. Various configurations, texts, images, animations, menus, color definitions, layouts, XML or (X) HTML files can be defined via the configurations.

All of the features explained and shown in connection with individual embodiments of the invention can be provided in different combinations in the subject matter of the invention in order to simultaneously realize their advantageous effects.

All process steps of the process can be implemented by electronic devices (circuits) which are suitable for executing the respective process step. Conversely, all functions that are carried out by objective features can be a process step of a process. For example, the step "sending a message" can be implemented by a transmitter module which has the appropriate functionality mentioned.

In conclusion, it should be pointed out that the description of the invention and the exemplary embodiments are in principle not to be understood as restrictive with regard to a specific physical implementation of the invention. All of the features explained and shown in connection with individual embodiments of the invention can be provided in different combinations in the subject matter of the invention in order to simultaneously realize their advantageous effects. It is e.g. likewise to integrate further instances for changing the application in addition to the server S, GS within the scope of the invention. It is particularly obvious to a person skilled in the art that the invention can be applied not only to individual elevators, but also to other passenger transportation systems and / or to a group of elevators, e.g. must be controlled and managed in one or more buildings.

Furthermore, the components of the configuration system can be implemented in several physical products.

The scope of the present invention is given by the claims and is not limited by the features explained in the description or shown in the figures.

Claims (15)

Configuration system for a graphical user interface of a control panel (COP), which is provided inside a passenger transport unit (CAR), comprising: - An application (A) for controlling the user interface; - A network connection (NW) between the application and a server (S, GS) on which at least one update for configuration of the user interface can be loaded; the application (A) being designed to access the server (S, GS) with a GET UPDATE message in order to read in the update and execute it directly. Configuration system according to the preceding claim, in which the server is designed as a local web server (S) and is arranged in the local network of the passenger transport system and / or in which the server is designed as a central instance and global server (GS) and via a Network connection is in data exchange. Configuration system according to one of the preceding claims, in which the passenger transport system comprises at least one elevator (CATR). Configuration system according to one of the preceding claims, in which the update is provided in a configuration file and can be carried out without compiling the application (A). Configuration system according to one of the preceding claims, in which the application (A) event-based and / or periodically addresses the GET UPDATE message to the server (S, GS). Configuration system according to one of the preceding claims, in which a configuration means (LMT) is provided in order to change, delete and / or create the configuration file on the server. Configuration system according to one of the preceding claims, in which the server (S, GS) comprises a configuration interface via which updates of the configuration file can be imported. Passenger transport unit (CAR) with a configuration system according to one of the preceding claims. Method for configuring a graphical user interface of a control panel (COP), which is provided in the interior of a passenger transport unit (CAR), comprising the following method steps: - Sending (S1) a GET UPDATE message from an application (A) to control the user interface to a server (S); - Access the server (S) to a memory (DB) to check (S2) whether an update for the configuration of the user interface is available and if so: - Loading (S3) the update by the application (A) and applying (S4) the update to configure the user interface. Method according to the preceding method claim, in which the loading (S3) and application (S4) of the update can be carried out at runtime of the application (A). Method according to one of the preceding method claims, in which the application (S4) of the update can be carried out without restarting the application (A) and without recompiling the application (A). Method according to one of the preceding method claims, in which the update relates to the execution of building-specific, safety-related functions of the passenger transport unit (CAR). Method according to one of the preceding method claims, in which the response to sensor signals which have been recorded in the passenger transport unit (CAR) and / or preferably in the same time period is generated dynamically. Computer program for a passenger transportation system that can be loaded into an internal memory of an electronic unit and comprises software routines with which the steps of the method according to the preceding method claims are carried out when the software routines are executed on the electronic unit. Use of the method according to the preceding method claim for operating a passenger transport system (CAR).

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