DE102014210289A1 - Medical device with a control and processing unit, which has a single-user multitasking operating system - Google Patents

Abstract

The invention relates to a medical device (1) having a control and arithmetic unit (6) which has a single-user multitasking operating system (OS) which at the same time has several tasks in individual user interfaces (UI1-UI3) or windows defined screen areas on multiple screens (6.1-6.3) processed, for each of these screens (6.1-6.3) is an input device for inputting screen events and these with an input interface (I / O1-I / O3) of the control and processing unit (6 ) is connected to transmit the screen events with their respective screen position to the control and processing unit (6), wherein an additional software (ZS) is loaded and executed in operation, which performs the following functions: - it is the direct acceptance of Suppresses screen events (= touchscreen event or mouse pointer event) via the input interfaces (I / O1-I / O3) to the operating system (OS), - All simultaneously occurring screen events are continuously accepted by the additional software (ZS), the screen events are each assigned to an individual user interface (UI1-UI3), and transferred according to their assignment to the individual user interfaces (UI1-UI3).

Description

The invention relates to a medical device having a control and computing unit, which has a single-user multitasking operating system that processes several tasks in individual user interfaces or windows with defined screen areas on several screens at the same time, wherein an input device for each of these screens is present for the input of screen events and this is connected to an input interface of the control and processing unit to transmit the screen events with their respective screen position to the control and processing unit.

Modern medical devices, in particular medical imaging devices, such as CT or MRI devices, are usually controlled by a single user at a central workstation. In addition, other medical personnel are often in the examination room in use and can also make settings on the medical device on other application surfaces. The power of modern personal computers (PC), where most Microsoft Windows is implemented as an operating system, and their ability to operate multiple touch screens, basically provides the ability to control all required user interfaces in the form of window-based application interfaces from a single PC. For example, such a medical device could offer additional configuration options on a plurality of screens, in particular touchscreens, in the examination room, and additional advanced settings for the medical device at a central workstation equipped with a keyboard and mouse. The application interfaces, ie the touch monitors and the central workplace monitor, could be operated simultaneously by several users in order to simultaneously make different settings via several user interfaces. For example, the patient data could be entered on one monitor and the settings for a CT scan could be programmed, the settings for a contrast agent injection on another monitor and the positioning of the patient with the movable patient table on yet another monitor.

However, since the WINDOWS operating system is a typical single-user multitasking operating system, such an approach is not supported with multiple concurrent users. Although WINDOWS allows multiple user interfaces to be displayed in parallel across multiple screens, it is considered to be a large contiguous screen within the operating system. For example, if a user touches a touch monitor, the mouse of the system is automatically moved to that location on another application interface. Another user who has been working with the mouse at this time will inevitably be disturbed in his work.

Another problem is that the entry of touch events is only allowed on one touch screen at a time. For example, if a user touches one of the touch monitors, no inputs are possible on the other touch screens until the former user releases his touch.

Yet another problem is multi-finger gestures, such as the two-finger gesture for zooming screen content. Since the operating system uses all the touch events of a system to calculate multi-finger gestures, it is not possible for multiple users to use such gestures at the same time, or it can lead to unreasonable results.

To solve this problem, several independent PCs with their own monitor and operating system have been used for each user for the applications mentioned so far. This means a PC at the central workstation as well as other, separate PCs with touch monitors, which, however, entails additional costs. If still different operating systems are used, then there is the additional problem of segmenting the development environment, since now software has to be developed on different operating systems and the demands on the development departments are increasing. In addition, the possibility of reusing software components is made more difficult.

It is therefore an object of the invention to provide a medical device with a control and processing unit, which has a single-user multitasking operating system, so that next to each other several user interfaces can be operated simultaneously on multiple monitors, at the same time without mutual interference by the user interfaces Screen events can be used.

This object is solved by the features of the independent claims. Advantageous developments of the invention are the subject of the subordinate claims.

The inventors have realized that it is possible the built-in mechanisms of single-user multitasking operating systems - especially MS-Windows, especially in versions 7 and 8 - namely the mutual exclusion of simultaneous screen events in different user interfaces, and the Support of only one user to work around. This makes it possible, in one, preferably imaging, Medical device with such an operating system, especially in a CT or MRI system, to receive inputs simultaneously from several operators on several screens running on different screens inputs.

The solution proposed by the inventors describes the treatment of the screen events, so-called touch inputs or mouse pointer inputs on multiple monitors under a single-user multitasking operating system, such as the WINDOWS operating system, and their processing. The touch events can be triggered in parallel by several users. The running in the user interface software can remain unchanged.

According to the invention, the treatment of screen events, in particular of touch events, is globally deactivated in the operating system or otherwise intercepted. This ensures that multiple simultaneous screen events do not interfere with each other, or that touch events can not interfere with the use of the mouse.

The screen events, in particular the touch events of the individual touch monitors, are thereby received directly at an input interface, usually a USB port, where they are read out. For this purpose, technologies such as e.g. WinUSB drivers, Raw Input Streams or Direct Input.

The screen events obtained in this way are processed thereon in a special software component, for example a touch handler, by being assigned to a specific screen and thus to the user interface running there on the basis of the input interfaces or by assigning a user interface based on the position information of the screen event which runs in a screen area in which the position indication of the screen event falls.

These software called touch handlers can also, after determining which user interface the received gestures have been executed on, generate events simulating standard .NET touch events using a TouchDevice API present in the .NET programming environment be forwarded to the respective user interface. For the software of the user interface, it does not matter whether these events are supplied directly by the operating system or by the touch handler.

In order to additionally support multi-finger gestures, these can be processed separately and separately for each user interface by means of the software modules InertiaProcessor2D or ManipulationProcessor2D available in the .NET programming environment and passed on to the respective user interface. Thus, the use of multi-finger inputs by multiple users is possible simultaneously. This makes it possible to additionally implement this also a variety of multi-finger gestures and to provide the software of each user interface concerned. By way of example, these may be extended gestures for the manipulation of the three-dimensional image representation or gestures for the rapid achievement of frequently required functions.

By means of this additional software according to the invention, it is thus achieved that the simultaneous acceptance and processing of a plurality of screen events, in particular of touch inputs, is made possible by a plurality of users on a single single-user multitasking operating system. Accordingly, the operation of the software by several users can be carried out in parallel and the application software of a medical device can receive and process the inputs of several users in parallel. This allows the use of inexpensive hardware and it can be dispensed with the use of other computer components in addition to the central workplace. In addition, this results in a reduction of the development effort, because on the one hand there are no other software technologies, frameworks or operating systems for the control of the touch monitors used and on the other hand, no special adaptation of the application software is necessary.

• – es wird die direkte Annahme von Bildschirmereignissen, also von Touchscreenereignissen oder Mauszeigerereignissen, über die Eingangsschnittstellen an das Betriebssystem unterdrückt,
• – es werden fortlaufend alle gleichzeitig auftretenden Bildschirmereignisse durch die Zusatzsoftware angenommen, die Bildschirmereignisse werden jeweils einem individuellen Benutzerinterfaces zugeordnet, und entsprechend ihrer Zuordnung an die individuellen Benutzerinterfaces übertragen.

In accordance with the above-described concept of the invention, the inventors propose the improvement of a medical device with a control and processing unit, which has a single-user multitasking operating system, which processes several tasks in each case individual user interfaces or windows with defined screen areas on multiple screens at the same time , wherein for each of these screens is an input device for inputting screen events and this is connected to an input interface of the control and processing unit to transmit the screen events with their respective screen position to the control and processing unit. The improvement is that additional software is loaded and executed during operation, which performs the following functions:

• It suppresses the direct acceptance of screen events, ie touch screen events or mouse cursor events, via the input interfaces to the operating system,
• - All simultaneously occurring screen events are continuously accepted by the additional software, the screen events are each assigned to an individual user interface, and transferred according to their assignment to the individual user interfaces.

This makes it possible to make inputs to several user interfaces on several screens at the same time, without these interfere with each other. This opens up the option of a faster workflow, for example when preparing a CT scan. In this case, for example, the necessary settings for the scanning conditions, such as X-ray energy, feed, etc. can be determined on a screen, the programming for a contrast agent injection can be made on another screen and the settings of a patient bed for storage of a patient to be executed.

In the specific embodiment of the additional software, this can on the one hand assign the screen events to the individual user interfaces on the basis of the transmitted screen positions. On the other hand, the additional software can also be designed such that each screen covers exactly one user interface, so that the screen events are assigned to the individual user interfaces on the basis of the input interfaces via which they are received.

It is particularly advantageous if at least one of the screens is designed as a touch screen and the screen events taking place there are touchscreen events. As a result, a graphic interface with a single input interface for the touch screen events generated on the touch screen and an additional interface for a keyboard can be saved for this workstation.

Furthermore, it is proposed that at least one of the screens has a mouse as a pointing device and that the screen events taking place there are the result of mouse clicks. In this case, a keyboard can additionally be provided at this workstation, but a virtual keyboard which is operated with the mouse can also be shown instead of a keyboard on the screen. In this case, the additional keyboard interface could also be dispensed with.

In principle, however, it may be advantageous to provide a separate keyboard at a workstation that frequently has to deal with text input, so that it is also proposed to associate a keyboard with an input interface on at least two screens, whereby the keystrokes are intercepted by the additional software and corresponding to one predetermined assignment of the input interfaces of the input interfaces keyboard events are assigned to the respective user interface and transmitted to the respective associated user interface. If only a single keyboard is used, special handling of the input signals is not absolutely necessary, but possible.

It is also advantageous if gestures are additionally recognized and interpreted by the additional software over time in addition to the screen events assigned to each user interface. These can then be transmitted to the respectively assigned user interface, so that a gesture control on several touchscreens is also possible.

Particularly advantageous is the above-described embodiment of a medical device for an imaging medical device, in particular a computed tomography system or a magnetic resonance tomography system.

Furthermore, this embodiment is particularly associated with a medical device having as an operating system a MS-Windows operating system, preferably in version 7 or 8 or later. Here, the additional software can be programmed via the .NET framework runtime environment, which already has individual routines, such as InertiaProcessor2D or ManipulationProcessor2D, which can be used here.

In the following the invention will be described in more detail with the aid of the figures, wherein only the features necessary for understanding the invention are shown. The following reference symbols are used: 1 : Medical device / CT system; 2 : Gantry housing, 3 : Patient couch; 4 : Contrast agent applicator; 5 : Patient; 6 : Control and computing unit; 6.1 - 6.3 : Screens / touchscreens; G1-G3: graphic interface; I / O1-I / O3: input interface; OS: operating system; Prg1 to Prg _n : computer programs; S: application software; S (UI1) -S (UI3): user interface software UI1-UI3; TD: Touch Device API; TI: touch input API; TH: touch handler; UI1-UI3: user interfaces / user interfaces; .NET: .NET Framework Runtime Environment, ZS: Additional Software.

They show in detail:

1 : schematic representation of a CT system with a control and processing unit including two additional screens;

2 : schematic representation of a known transmission of screen events from three screens to a computing unit;

3 : schematic representation of the transmission according to the invention of screen events from three screens to a computing unit;

4 : Data flow of a touchscreen using the example of a .NET Framework runtime environment based on a WINDOWS operating system.

The 1 shows an exemplary medical device, here in the form of a CT system 1 , The CT system 1 includes a gantry housing 2 in which there is a spotlight detector system for scanning the patient 5 located, a motor driven patient bed 3 on which the patient 5 is stored, a contrast agent applicator 4 and a control and processing unit 6 with which the CT system 1 is controlled.

According to the invention, the control and computing unit 6 even with a screen 6.1 and two additional touchscreens 6.2 and 6.3 fitted. Here is the first touch screen 6.2 near the contrast agent applicator 4 placed so that there directly the parameters of contrast injection can be programmed. The second touchscreen 6.3 is located next to the patient bed 3 and can be used to the patient bed 3 to properly store the patient for the examination. The screen 6.1 , which is assigned to the main workstation, also has a - not shown in detail - pointer instrument (mouse or trackball) and a keyboard, so that in particular inputs with more complex texts can be made, in particular the patient data recorded and settings of the scan parameters can be made.

In addition to the control and processing unit 6 a memory with computer program code Prg1-Prgn symbolically represented to represent the necessary software. Part of this software is also the additional software according to the invention, by which it is possible to operate in parallel multiple screens with inputs of screen events, without causing conflicts and misinterpretations due to the simultaneous incoming screen events in the operating system.

The 2 and 3 should be the difference between in the 2 illustrated state of the art and the inventive design of the control of multiple screens illustrate.

The 2 shows a schematic representation of a control and processing unit 6 with three connected screens 6.1 to 6.3 , which are designed as touchscreens. Accordingly, the control and processing unit has 6 has a graphic interface G1 to G3 per screen for outputting the graphic information to the screens and in each case via an input interface I / O1 to I / O3, which can be formed in each case by means of a USB port. In a single-user multitasking operating system, such as modern variants of the MS-WINDOWS, especially versions 7 or 8, the screens can 6.1 to 6.3 to display different screen contents concurrently within the operating system, be treated as a large virtual screen made up of the sum of the individual real screens. Accordingly, each screen receives its own specific coordinate range, by the control of different user interfaces can be displayed in the form of windows and the user can make inputs there.

If screen events are registered on such screens at the same time, they are transmitted to the control and computing unit via the I / O interfaces I / O1 to I / O3 6 where the operating system interprets them as simultaneous screen events of the virtual overall screen, which can lead to conflicts with multiple concurrent user interfaces, because on the one hand the assignment to existing user interfaces or windows in which application software is running, is not clearly defined, and on the other Misinterpretations are possible, for example in the evaluation of gestures.

In the example shown, the screen events of the three screens 6.1 to 6.3 via the input interfaces in a known manner passed directly to the single-user multitasking operating system OS and transferred from there to the respective active application software S, without that possible conflicts could be solved.

An inventive solution to this problem is in the 3 also shown a schematic representation of the connection of three screens to the control and processing unit 6 shows. Basically, the same hardware-based structure, each with a graphics interface G1 to G3 and an input interface I / O1 to I / O3 as in 2 in front. However, additional software ZS has been integrated, which in operation intercepts the screen events incoming from the screens at the input interfaces I / O1 to I / O3 before they are passed on to the operating system. These incoming signals are sorted with the additional software ZS either according to their interfaces or according to their local information in relation to the active user interfaces UI1 to UI3 and targeted, bypassing the operating system OS directly to the application software of the respective user interfaces S (UI1) to S (UI3) forwarded.

In this way, each user interface sees only those screen inputs specific to it, without being irritated by other inputs coming from other user interfaces. Accordingly, with the aid of the additional software ZS according to the invention and a single-user multitasking operating system OS, a plurality of user interfaces can be operated simultaneously and inputs can be made at the same time.

To illustrate the invention is in the 4 again schematically the data flow of an additional touchscreen 6.2 using the example of a .NET framework runtime environment based on a WINDOWS operating system. Accordingly, the arithmetic unit has 6 as operating system OS over MS-WINDOWS in the version 7 or 8th , Where also the software of a .NET framework runtime environment - represented by the reference numeral .NET - is loaded. Part of the .NET framework runtime environment is also a touch device API (API = application programming interface) TD. From the additional touch screen 6.2 Via a USB interface I / O2 touch events with indication of position and date are forwarded to the touch input API TI. This transfers these touch events to a touch handler TH, which according to an assignment of the touch event made there to a given user interface of this touch event - correspondingly addressed to the touch device API in the .Net framework runtime environment forwards to them from there Form an input to the software of the associated user interface S (UI2). The software of the user interface S (UI2) in turn controls the screen display of the touch screen 6.2 via a graphic interface G2.

By this compared to the prior art modified data flow, it is now possible to operate on a single-user multitasking operating system simultaneously multiple screens, especially touchscreens, so that they can be used by simultaneous use of the user interfaces shown there for simultaneous input.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (9)

Medical device ( 1 ) with a control and processing unit ( 6 ), which has a single-user multitasking operating system (OS), at the same time several tasks in each individual user interfaces (UI1-UI3) or windows with defined screen areas on multiple screens ( 6.1 - 6.3 ), whereby for each of these screens ( 6.1 - 6.3 ) an input device for inputting screen events is present and this with an input interface (I / O1-I / O3) of the control and processing unit ( 6 ) is connected to the screen events with their respective screen position to the control and processing unit ( 6 ), characterized in that an additional software (ZS) is loaded and executed in operation, which performs the following functions: 1.1. the direct acceptance of screen events (= touch screen event or mouse cursor event) via the input interfaces (I / O1-I / O3) to the operating system (OS) is suppressed, 1.2. All simultaneously occurring screen events are continuously accepted by the additional software (ZS), the screen events are each assigned to an individual user interface (UI1-UI3) and transmitted according to their assignment to the individual user interfaces (UI1-UI3). Medical device ( 1 ) according to the preceding Patent Claim 1, characterized in that the screen-related events are assigned to the individual user interfaces (UI1-UI3) on the basis of the transmitted screen positions by the additional software (ZS). Medical device ( 1 ) according to the preceding claim 1, characterized in that by the additional software (ZS) each screen ( 6.1 - 6.3 ) exactly one user interface (UI1-UI3) is covered and the screen events are assigned to the individual user interfaces (UI1-UI3) by means of the input interfaces (I / O1-I / O3) via which they are received. Medical device ( 1 ) according to one of the preceding claims 1 to 3, characterized in that at least one of the screens ( 6.1 - 6.3 ) is designed as a touch screen and the screen events taking place there are touchscreen events. Medical device ( 1 ) according to one of the preceding claims 1 to 3, characterized in that for at least one of the screens ( 6.1 - 6.3 ) a pointer instrument as a pointing device and the screen events taking place there are the result of key clicks. Medical device ( 1 ) according to one of the preceding claims 1 to 5, characterized in that at least two screens ( 6.1 - 6.3 ) a keyboard with an input interface (I / O1-I / O3) is assigned, intercepted by the additional software (S) and the keyboard input and according to a predetermined assignment of the input interfaces (I / O1-I / O3) the keyboard events the respective user interface ( UI1-UI3) and transmitted to the respectively assigned user interface (UI1-UI3). Medical device ( 1 ) according to one of the preceding claims 1 to 6, characterized in that are recognized and interpreted by the additional software (S) over time from each of a user interface (UI1-UI3) associated screen events gestures, and this to the respective associated user interface (UI1 -UI3). Medical device ( 1 ) according to one of the preceding claims 1 to 7, characterized in that it comprises a medical device, in particular a computed tomography system ( 1 ) or a magnetic resonance imaging system. Medical device ( 1 ) according to one of the preceding claims 1 to 8, characterized in that the operating system (OS) is a Microsoft WINDOWS operating system, preferably in the version 7 or 8 or later.

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