WO2000031673A2

WO2000031673A2 - Medical workstation

Info

Publication number: WO2000031673A2
Application number: PCT/DE1999/003706
Authority: WO
Inventors: Karlheinz Dorn; Dieter Ortlam; Martin Herget; Josef WEINGÄRTNER
Original assignee: Siemens Aktiengesellschaft
Priority date: 1998-11-23
Filing date: 1999-11-22
Publication date: 2000-06-02
Also published as: WO2000031673A3

Abstract

The invention relates to a medical workstation (5-8) comprising an imaging system (13), a control device (18) that controls several tasks that run at the same time, a reproduction device (14) and an overlay device (17). The overlay device (17) is configured in such a way that the user interface of the reproduction device (14) is subdivided into areas, whereby the medical images (21) of a task are reproduced in one image area (20) and overlays (23-31) comprising information and control elements relating to said task appear in a control area (22). Selectable fields are arranged on the edge of the monitor image in the form of card tabs that are respectively allocated to a dynamically configurable task that can run at the same time. The currently called task that can be seen on the card tab (25) is marked for identification purposes.

Description

description

Medical workstation

The invention relates to a medical workstation with an image system, with a control device for controlling a plurality of concurrent user jobs or tasks, with a display device and a display device that displays a mouse pointer that can be controlled by a mouse in the user interface of the display device. Such image systems are used for processing and displaying medical images in a diagnostic device, with the diagnostic images being superimposed.

From computer technology, toolbars with buttons are known as control elements of the user interfaces, in technical jargon called user interface (UI), which enable various functions to be triggered by control, for example using the mouse, keyboard or another input device.

DE 196 29 093 AI describes a medical therapy and / or diagnostic system in which a display of a user interface for a user job is displayed on a display device and divided into an image area and a menu area.

From US 5,668,964, a graphical user interface for a personal computer is known, in which one or more notebooks with several pages of different applications are arranged. The pages can be selected by tabs.

The invention is based on the object of designing an image system of the type mentioned at the outset in such a way that the “workflow in medical technology”, for example a plurality of diagnostic images, can be processed quickly and easily. The object is achieved according to the invention in that the fade-in device is designed in such a way that the user interface of the display device is subdivided into areas, the medical images of a user order or tasks being displayed in an image area and fade-ins with information and control elements relating to this in a control area The user order or task is carried out so that selectable fields are arranged in the manner of tabs on the edge of the monitor screen, each of which is assigned a different concurrent user order or task that is dynamically configurable at runtime, and that the current, visible, visible user order or task is currently open the tab is clearly marked. This enables so-called task cards to be displayed, by means of which tasks which are to be regarded as an activity of the workflow, in particular in the image postprocessing and diagnosis in all imaging methods of medical technology, can be selected in a simple and quick manner, with several Tasks or activities that can be processed in parallel and called up as required. The card tabs on the edge of this task card concept ensure a clear division. This creates a medical workflow that can also be configured dynamically (workflow engine).

According to the invention, the fade-in device can be designed such that the main menu, the control elements or tools, the data reproductions and their visualization are switched context-sensitively by switching to another concurrent user order or task.

The task can advantageously be an activity from a medical workflow and as component software. The order of the tasks can correspond to the course of the medical workflow. It has proven to be advantageous if the insertion ^{device is designed in} such a way that further card-shaped areas with fields in the manner of card tabs are arranged in the control area as inserts of information on the current user order or task.

Processing of medical images can be further simplified if the fade-in device is designed in such a way that buttons are shown on the card-shaped areas that correspond to the commands assigned to the current user job or task.

It has proven to be advantageous if the fade-in device is designed in such a way that the activated buttons are highlighted.

The user order or task can advantageously correspond to a component-oriented macro, macro module (component ware) or macro DOCXE.

The image area can be enlarged for viewing purposes if the display device and the control unit are connected to a switching device in such a way that the display is carried out by actuating input devices or by programming or only when the mouse pointer is in a specific area of the image.

An advantageous method for operating an image system for playback from the user interface of medical workstations results when task cards with card tabs are inserted into the image of the playback device, the content of which corresponds to componentware and which as a whole implement a medical workflow that takes place at runtime can be dynamically configured and / or reconfigured in the program. The invention is explained below with reference to an embodiment shown in the drawing. Show it:

Figure 1 shows a known diagnostic device with a playback device according to the invention and

FIG. 2 shows a display of a monitor image with overlays according to the invention of an exemplary configured medical workflow.

1 shows a medical system with modalities 1 to 4 for acquiring medical images, which as image-generating systems include, for example, a CT unit 1 for computed tomography, an MR unit 2 for magnetic resonance, a DSA unit 3 for digital subtraction angiography. phie and can have an x-ray unit 4 for digital radiography. Workstations 5 to 8 can be connected to these modalities 1 to 4, with which the acquired medical images can be processed and stored locally. Such a workstation is, for example, a very fast small computer based on one or more fast processors. The workstations 5 to 8 can, for example, load the corresponding JAVA software from a JAVA server (not shown) as JAVA workstations.

The workstations 5 to 8 are connected to a data network 9 for the distribution of the generated images and communication. For example, the images generated in modalities 1 to 4 and the images further processed in workstations 5 to 8 can be stored in central image storage and image archiving systems 10 of the hospital or forwarded to other workstations.

Further workstations 11, which have local image memories, are connected to the data network 9 as diagnosis stations. In the workstations 11, the captured and in the image storage system 10 stored images are subsequently retrieved for diagnosis and stored in the local image memory, from which they can be directly available to the diagnosis person working on the workstation 11.

Furthermore, 9 servers, for example patient data servers (PDS), file servers and / or program servers, can be connected to the data network.

The image and data exchange via the data network 9 can take place according to the DICOM standard, an industry standard for the transmission of images and further medical information between computers to enable digital communication between diagnostic and therapy devices from different manufacturers.

With the data network 9, further patient data can also be called up from the hospital information system.

The workstations 5 to 8 and 11 have, as will be explained with reference to the workstation 11, a computer 12 to which an image system 13 is connected, which is connected to a monitor 14 for displaying diagnostic images. The image system 13 can contain, for example, a subtraction device, integration stages, image memory and / or converter.

An operating unit 15 is connected to the image system 13 and can have, for example, a keyboard, a mouse 16 and / or a so-called joystick or another input device. The image system 13 has a fade-in device 17 which fades in diagnostic images (or other medical workflow control elements) reproduced on the monitor 14. A control device 18 connected to the fade-in device 17 effects the implementation of control commands entered via the operating unit 15. for example, by clicking on control elements arranged on the monitor 14.

FIG. 2 shows such inserts for medical diagnostics, which are reproduced on the user surface of the monitor 14 and are generated by the inset device 17. According to the invention, the user interface on the monitor image is divided into several areas that can be configured dynamically at runtime and which implement a medical workflow (workflow engine). Each workflow contains a task (activity) implemented as componentware. For example, one or more medical images, in the illustrated case four X-ray images 21 of a patient's hand, are reproduced in an image area 20. In addition to the image area 20, a control area 22 is shown, on the edge of which fields in the manner of card tabs 23 to 26 are arranged, each of which is assigned another concurrent user order or task in the form of a task card. The current task is marked with an inverted font on the highlighted tab 25.

By switching to another concurrent user order or task, the main menu, the control elements or tools, the data playback (for example pictures) and their visualization are switched context-sensitive.

In the control area 22, further card-shaped areas 27 and 28 with fields in the manner of card tabs 29 are arranged in the task card as overlays with information of the user order or tasks. In the areas 27 and 28, a plurality of buttons 30 are arranged as control elements, to which a wide variety of commands can be assigned. These buttons 30 can be labeled or provided with icons. However, only the buttons 30 that can be used for the current task will be visible. The buttons 31 just selected are highlighted. A selection of the buttons 31 or the tabs 25 or 29 both for the desired task and for the commands to be carried out can be made, for example, by means of a mouse pointer 32 which can be moved by the mouse 16, m in known manner by clicking on the corresponding button of the mouse Mouse 16 the selection is made.

In the control area 22, e.g. a field 33 is also provided, in which the data of the patient of the present task are shown. System data can be specified in a further field 34 within the control area 22. A scroll bar 35 can be shown between the image area 20 and the control area 22.

The concurrent user orders or tasks assigned to the individual task cards with tabs correspond as Macro-DOCXE to a component-oriented macro software module and thus the content of component goods.

In order not to hide any data parts, the image system 9 can also have a switching device that detects the position of the mouse pointer 32 and only displays the task card when the mouse pointer (or, for example, another input device) 32 m in the area of Task card is located.

The design of the image system 13 according to the invention for generating the fade-in allows m selection of tasks (individual activity from a medical workflow), in particular in image post-processing and diagnosis in all imaging methods of medical technology, so that multiple tasks (quickly and easily) Activities) can be processed in parallel and called up as required, but can also be activated programmatically (for example as a pipeline strategy). The card tabs 23 to 26 provide a clear division of the workflow along the lines of the task card concept according to the invention, which also dynamically program ms at runtime can be configured or reconfigured. This visual arrangement of such task cards (as a medical workflow) on the user interface of medical workstations in connection with componentware as content for each task card (an activity of the workflow) makes it easier for the user to operate it within his workflow control or workflow. The sequence of the card tabs 23 to 26 assigned to the tasks corresponds to the course of the medical workflow.

Claims

claims

1. Medical workstation (5 to 8, 11) with an image system (13), with a control device (18) for controlling several concurrent user orders or tasks, with a playback device (14) and a fade-in device (17), which is designed in such a way that the user interface of the playback device (14) is divided into areas, the medical images (21) of a user order or tasks being displayed in an image area (20) and inserts (23 to 31) with information and control elements in a control area (22) this user order or task that selectable fields are arranged on the edge of the monitor image in the manner of tabs (23 to 26), each of which is assigned a different concurrent user order or task that is dynamically configurable at runtime, and that the currently called up current one , visible user order or task is clearly marked on the tab (25).

2. Workstation (11) according to claim 1, so that the fade-in device (17) is designed in such a way that the main menu, the control elements or tools, the data reproductions and their visualization are switched context-sensitive by switching to another concurrent user job or task.

3. Workstation (11) according to claim 1 or 2, so that the task is an activity from a medical workflow and implemented as component software.

4. Workstation (11) according to one of claims 1 to 3, characterized in that the order of the tasks corresponds to the course of the medical workflow.

5. Workstation (11) according to one of claims 1 to 4, characterized in that the insertion device (17) is designed such that in the control area (22) further card-shaped areas (27, 28) with fields in the manner of card tabs (29 ) are arranged as overlays of information on the current user order or task.

6. Workstation (11) according to one of claims 1 to 5, characterized in that the fade-in device (17) is designed such that buttons (30, 31) on the card-shaped areas (27, 28) are faded in, the current user order or Commands assigned to the task.

7. Workstation (11) according to one of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t that the fade-in device (17) is designed such that the activated buttons (31) are highlighted brightly.

8. Workstation (11) according to one of claims 1 to 7, d a d u r c h g e k e n n z e i c h n e t that the user job or task corresponds to a component-oriented macro.

9. Workstation (11) according to one of claims 1 to 8, d a d u r c h g e k e n n z e i c h n e t that the user job or task corresponds to a component-oriented macro module (componentware).

10. Workstation (11) according to one of claims 1 to 9, d a d u r c h g e k e n n z e i c h n e t that the user job or task corresponds to a component-oriented macro DOCXE.

11. Workstation (11) according to one of claims 1 to 10, characterized in that the how- dergabevvorrichtung (14) and the control unit (15) are connected to a switching device in such a way that the display is carried out by pressing input devices or programmed.

12. Workstation (11) according to any one of claims 1 to 11, characterized in that the playback device (14) and the control unit (15) are connected to a switching device such that the fade-in takes place only when the pointer (32) Mouse (16) is located in a certain area of the image.

13. A method of operating a workstation (11) for playback from the user interface of medical workstations according to one of claims 1 to 12, characterized in that task cards (27, 28) with card tabs (23 to 26, 29) in the Image of the playback device (14) are displayed, the contents of which correspond to component goods.

14. A method of operating a workstation (11) according to claim 13, characterized in that task cards (27, 28) with card tabs (23 to 26, 29) are shown in the image of the playback device (14), the content of which corresponds to componentware and which as a whole implement a medical workflow that can be dynamically configured and / or reconfigured in the program at runtime.