JPH1099282A - Medical system architecture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable to collect connections into one process or to disperse via a network, by enabling digital communication between different composition units according to industrial standards for transmitting images, etc., and building in an industrial standard as an OCX software component. SOLUTION: A network interface 15 can be connected with an image transmission network 9. The data exchange via the image transmission network 9 is performed according to the DICOM standard sufficiently processed by a medical system. That is, it is performed according to an industrial standard for transmitting image and other medical information between computers. Thereby, a medical standard DICOM object model can be combined with the Microsoft OLE-CCX technique, and thereby each unit standardized by data bank technique can be developed and built in by a DICOM model as an OCX software component using the Microsoft OLE technique.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention comprises a component unit for image detection, a device for processing an image, and an image transmission device, wherein the device for processing the digital image system is a computer. The calculator operates in accordance with a method for data exchange between different application programs with graphical control elements and OLE custom controls, and each OCX software unit for each individual process bounded by boundaries Is assigned to a medical system architecture.

[0002]

2. Description of the Related Art For example, Hinz Morneburg [Hrsg:] "Bildgeb
ende Systeme fuer die medizinischeDiagnostik ", Erla
ngen, Publicis MCD-Verlag, 3.Auflage 1995,680-697
Medical systems such as those described on the page are becoming increasingly complex. On the other hand, the scale of expansion of medical systems is increasing as well. However, this requires a very flexible architecture.

Hitherto known architectures are built substantially without decentralized software and software units.

[0004]

It is an object of the present invention to construct a software unit (object) and to make this software unit as self-contained as possible.
nt). Furthermore, the connections between the units are made location transparent in relation to the point of this unit (object), so that all the connections are combined in one process,
Or be able to be distributed over a network.

[0005]

According to the present invention, there is provided an industry standard for the transmission of images and other medical information between computers, which allows a manufacturer to digitally communicate between different component units. The industrial standard is O
The problem is solved by being configured as being incorporated as a CX software component.

[0006]

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail hereinafter with reference to an embodiment shown in the drawing.

FIG. 1 shows a system architecture of a medical computer network. The component units 1 to 4 are used for detecting medical images.
These are, for example, CT units for computer tomography, MR units for magnetic resonance, DS for digital basal angiograms as image forming units.
X for A unit 3, and digital radiograph
It can have a line unit 4. Workstations 5 to 8 can be connected to these component units 1 to 4, which control the component units 1 to 4 and can process and store the detected medical images. . Such workstations are, for example, one or more processor-based small high-speed computers.

The workstations 5 to 8 are connected to an image communication network 9.
And connected to share the formed image and to communicate. Thus, for example, the images formed by the component units 1-4 can be stored in the central image memory 10 or transmitted further to other workstations 5-8.

Another workstation can be connected to the image communication network 9 as finding consoles 11 and 12. This finding console is the local image memory 13,1
4, for example, it can be connected to a jukebox.
In the finding consoles 11 and 12, images detected and filed in the image memory 10 can be called later for finding and filed in the local image memories 13 and 14. The images from this local image memory can be used directly by the finding physician working on the finding console 11 or 12.

A network interface 15 can be connected to the image communication network 9. The internal image communication network 9 is connected to the entire data network via this interface, and can exchange standardized data with various networks all over the world.

The image data exchange via the image communication network 9 is performed in accordance with the DICOM standard which has been sufficiently processed in the medical system. That is, in accordance with industry standards for transmitting images and other medical information between computers. This standard allows digital communication between diagnostic and therapeutic devices from different manufacturers.

According to the present invention, the medical standard DICOM object model is combined with the Microsoft OLE-OCX technology, whereby each unit standardized by the data bank technology is converted into a DICOM model (DICOM object) as an OCX software component by the Microsoft OLE technology. Can be developed and incorporated.

Further, according to the present invention, the medical image standard DIC
OM object model is Microsoft OLE-OC
X technology and Microsoft OLE automation technology, so that each DICOM object standardized in databank technology can be developed and incorporated using Microsoft OLE technology as OCX and automation software components. In doing so, OLE automation distributes the OCX components to different address spaces.

Each such DICOM object is an OC
X unit and / or automation unit, each associated with eg medical imaging, patient monitoring, examination lists and reports.

OCX is a Microsoft standard for OLE custom controls. OLE is a method for including or connecting objects to each other. Custom controls are graphical user-defined control elements in Microsoft Windows.

An advantage of the present invention is that its flexibility and the ability to exchange data with other components are simple.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of an embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 CT unit 2 MR unit 3 DSA unit 4 X-ray unit 5, 6, 7, 8 Workstation 9 Image communication network 10 Central image memory 11, 12 Finding console 13, 14 Local image memory 15 Network interface

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI G06T 1/00 G06F 15/62 390Z (72) Inventor Dietrich Quayer Germany Erlangen Nürnberger Strasse 83 (72) Inventor Christian Schaaf Germany Federal Republic Herzogenaurach Gietrunk 10

Claims (10)

[Claims] 1. A component unit (1 to 1) for image detection.
4) and an apparatus for processing an image (5 to 8, 11, 1)
2) and an image transmission device (9), and a device (5 to 5) for processing the digital image system.
8, 11, 12) have a calculator, which operates according to a method for data exchange between different application programs (OLE) with graphical control elements and OLE custom controls (OCX). OC for each individual process bounded by the boundary
In a medical system architecture of the type to which the X software unit is assigned, the industry standard for the transmission of images and other medical information between computers allows manufacturers to digitally communicate between different component units. Standard is OCX
Embedded as a software component,
A medical system architecture characterized by that: 2. The industrial standard is a DICOM standard.
The medical system architecture of claim 1. 3. The medical system architecture according to claim 1, wherein the medical image standard DICOM object model is combined with Microsoft OLE-OCX technology. 4. A DICOM model (DICOM object) for each unit standardized by the data bank technology
4. The medical system architecture of claim 3, wherein the OCX software component is incorporated using Microsoft OLE technology. 5. The medical system architecture according to claim 1, wherein the medical image standard DICOM object model is combined with Microsoft OLE-OCX technology and Microsoft OLE automation technology. 6. Each DI standardized by data bank technology
6. The medical system architecture of claim 5, wherein the COM objects are embedded as OCX and OLE automation software components using Microsoft OLE technology, and the OLE automation distributes the OCX components to various address spaces. 7. The medical system architecture according to claim 1, wherein the software component is applied to medical imaging. 8. The medical system architecture according to claim 1, wherein a software component is applied to the patient monitor. 9. The medical system architecture according to claim 1, wherein a software component is used for the examination list. 10. The medical system architecture according to claim 1, wherein a software component is used for reporting.