JPH10137192A - Medical system architecture with script or virtual code - Google Patents

Abstract

(57) [Summary] [PROBLEMS] To configure a software module (object) having characteristics of being held as much as possible. In a medical system architecture provided with an aspect for image detection, an apparatus for image processing, and the apparatus for image transmission, the apparatus for image processing has a digital image system with a computer. The computer operates according to the scheme for data exchange between the various application programs with the respective graphic control elements, during which the industry standards for image transmission and other medical information are transferred between the respective computers. And provided to enable digital communication between aspects of various manufacturers,
A script and / or virtual code is assigned to each object of the industry standard, and the code is executed on a computer.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a medical system architecture provided with component navigation, and the medical system architecture has an image detection mode, an image processing apparatus, and an image transmission apparatus. At that time, the device for image processing,
It has a digital imaging system with a calculator, which operates according to the data exchange scheme between the various application programs with the respective graphic control elements.

[0002]

2. Description of the Related Art Each medical system (for example, the publication "Bi
ldgebende Systeme fuer die medizinische Diagnosti
k ”, Heinz Morneburg [Compiler], Erlangen, Publicis M
CD-Verlag, 3. Auflage 1995, pp. 680-697) is becoming increasingly complex and the extent of expansion of the medical system is increasing at a similar rate. But,
This requires a very flexible architecture.

[0003] Each of the previously known architectures is constructed substantially without decentralized software and software modules.

[0004]

SUMMARY OF THE INVENTION An object of the present invention is to configure a software module (object) having characteristics of being held as much as possible. Furthermore,
Each connection between each module to the location of this module (object) must be transparent, so that each connection can be all integrated into one process or distributed over a network .

[0005]

According to the present invention, there is provided, in accordance with the present invention, a medical system architecture having a mode for image detection, a device for image processing and a device for image transmission. , A digital imaging system with a computer, which operates according to a scheme for data exchange between various application programs with each graphic control element, in which the image transmission Industry standards and other medical information are provided between each computer to enable digital communication between aspects of various manufacturers, wherein scripts and / or virtual codes are The problem can be solved by being assigned to each object and executing the code on a computer.

[0006]

DETAILED DESCRIPTION OF THE INVENTION On the one hand, each component is obtained which is self-maintained by the DICOM object model, and on the other hand, the processing of the virtual code technology on the DICOM object in each component on each network node. become able to. An advantageous variant is to use each processing algorithm in an HTML document.

Advantageously, the medical industry standard is based on the DICOM standard.

According to the present invention, for example, SUN, JAVA apricot of active X, JAVA script,
Opendoc scripts or Visual Basic scripts can be used as code in DICOM objects. At that time, the DICOM object is provided with a script or virtual code extension.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

Referring to the drawings, there is shown a system architecture of a medical computer network. For detection of medical images, embodiments 1 to 4 (for example, a CT unit 1 for computer tomography, an MR unit 2 for nuclear magnetic resonance, a DSA unit 3 for digital subtraction angiography, and a digital It has an X-ray unit 4 for radiography 4. Each of the embodiments 1 to 4 has a workstation 5 to 5
8 can be connected and this workstation can be used to control each aspect 1 to 4 to process and store the detected medical images. Such a workstation is, for example, a very fast small computer based on one or more high-speed processors.

Each of the workstations 5 to 8 is connected to an image communication network 9 for distribution of formed images and communication. Thus, for example, images formed in aspects 1-4 can be stored in central image memory 10 or transferred to other workstations 5-8.

Another workstation can be connected to the image communication network 9 as inspection consoles 11 and 12, which can be connected to local image memories 13 and 14, for example a jukebox. In the inspection consoles 11 and 12,
Each image detected and stored in the image memory 10 can later be recalled for examination and stored in the local image memories 13 and 14, from which each image can be directly transferred to the examination console. Available to the inspector working at 11 or 12.

A network interface 15 can be connected to the image communication network 9, and the internal image communication network 9 can be connected via this interface.
Is connected to a global data network, so that standardized data can be exchanged on a worldwide basis using various networks.

In this case, this image and data exchange via the image communication network 9 is based on the DICOM standard, images and other medical information of various manufacturers, which are widely used in medical systems. This is done according to the industry standard for digital communication transmission between the device and each treatment device.

According to the present invention, using a storing script or virtual code (as a basis for such an object) within a DICOM object;
Or by script or virtual code extension
With the help of extending the ICOM object, such code can be executed later on the target computer (DICOM reference extension with reference or shadow group). In this way, it is possible to make a machine-independent selection, and the DICO within the network can be selected.
M objects can be processed later. Each algorithm is stored with a corresponding DICOM image data object.

[0016]

The advantages of the proposal of the present invention are its flexibility and also its simple operability for data exchange with other aspects.

[Brief description of the drawings]

FIG. 1 is a system architecture of a medical computer network.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 CT unit 2 MR unit 3 DSA unit 4 X-ray unit 5-8 Workstation 9 Image communication network 10 Central image memory 11,12 Inspection console 13,14 Local image memory 15 Network interface

Claims (9)

[Claims] 1. A medical system architecture comprising an aspect for image detection (1 to 4), an apparatus for image processing (5 to 8, 11, 12) and an apparatus for image transmission (9), The apparatus for image processing (5 to 8, 11, 1)
2) has a digital imaging system with a computer, said computer operating according to the scheme for data exchange between the various application programs with each graphic control element, Industry standards and other medical information for said image transmission are provided between each computer to enable digital communication between aspects of various manufacturers, wherein scripts and / or virtual codes are provided. Medical system architecture, wherein the code is assigned to each object of the industry standard and the code is executed by a computer. 2. The medical system architecture according to claim 1, wherein the industry standard is a DICOM standard. 3. The medical system architecture according to claim 1, wherein a JAVA applet is used as a code inside the DICOM object. 4. The medical system architecture according to claim 1, wherein a JAVA script is used as a code inside the DICOM object. 5. A medical system architecture as claimed in claim 1 or 2, wherein Active X is used as code inside the DICOM object. 6. The medical system architecture according to claim 1, wherein an Opendoc script is used as a code inside the DICOM object. 7. The medical system architecture according to claim 1, wherein a visual basic script is used as a code inside the DICOM object. 8. The medical system architecture according to claim 1, wherein a script code extension is provided for each DICOM object. 9. The medical system architecture according to claim 1, wherein a virtual code extension is provided for each DICOM object.