DE19625833A1 - Medical imaging system architecture using standard object model - Google Patents

Abstract

The system associates a variety of devices performing e.g. computerised tomography (1), magnetic resonance imaging (2), digital subtraction angiography (3) and digital radiography (4) with fast microcomputer workstations (5-8) linked to a video communication network (9). Diagnostic workstations (11,12) in the same network are connected to a local image store (13,14). Images from a separate store (10) can be called up for local display and diagnosis. The system can be interfaced (15) to a global network for worldwide exchange of standardised data.

Description

The invention relates to a medical system architecture with a modality for capturing images, a device device for processing the images and a device for Transfer of the images, in which the device for processing processing has a digital image system with a computer, which according to a procedure for data exchange between ver various application programs with graphic control elements ment works.

Medical systems are becoming increasingly complex during the Degree of expansion of medical systems in the same ratio grows. However, this creates a very flexible architecture needed.

The previously known architectures are essentially without decentralized software and software modules the.

The invention is based on the task of software modules To construct (objects) that exhibit behavior that carries itself if possible. Furthermore, the verbin between the building blocks in relation to their location Blocks (objects) must be invisible, so that they are all combined in one process or distributed over a network could be.

The object is achieved in that the Computer works according to a process in which an industry standard for the transmission of images and other medical devices information between computers to enable the digital communication between the modalities manufacturer as a software component in combination with the JAVA technology is implemented.  

On the one hand, the DICOM Object Model gives you self-traces components and on the other hand, SUN-JAVA-Tech helps technology when building these components.

It has proven beneficial if the medical Industry standard is the DICOM standard.

According to the medical image standard DICOM Object model with the SUN-JAVA applet or SUN-JAVA script Technology can be combined.

It has proven to be beneficial if each in the sense a database technology normalized DICOM Object (DICOM model) as a JAVA applet software component Using the SUN JAVA language or as a JAVA script software Component is implemented using the SUN-JAVA language.

According to the invention, the JAVA network can distribute the JAVA applet components for different address spaces cause.

According to the software components in the medical imaging, patient monitoring, Use investigation listing or reporting.

The invention is based on one in the drawing illustrated embodiment explained in more detail.

The figure shows the system architecture of a medical computer network. For the acquisition of medical images, the modalities 1 to 4 serve as image-generating systems, for example a CT unit 1 for computer tomography, an MR unit 2 for magnetic resonance, a DSA unit 3 for digital subtraction angiography and an X-ray unit 4 for digital radiography 4 can have. Workstations 5 to 8 can be connected to these modalities 1 to 4 , with which the modalities 1 to 4 can be controlled and the acquired medical images can be processed and stored. Such a workstation is, for example, a very fast small computer based on one or more fast processors.

The workstations 5 to 8 are connected to an image communication network 9 for distributing the generated images and communication. For example, the images generated in modalities 1 to 4 can be stored in a central image memory 10 or forwarded to other workstations 5 to 8 .

Further workstations can be connected to the image communication network 9 as diagnosis consoles 11 and 12 , which can be connected to a local image memory 13 and 14 , for example a jukebox. In the diagnosis consoles 11 and 12 , the captured and stored in the image memory 10 images can be called up later for diagnosis and stored in the local image memory 13 and 14 , from which they can be available to the diagnosis console 11 or 12 working person.

A network interface 15 can be connected to the video communications network 9 by the network tion the internal Bildkommunika 9 is connected to a global data network, can be exchanged so that the worldwide standardized data with different Netzwer ken.

This image and data exchange via the image communication network 9 takes place according to the widely used in medical systems DICOM standard, an industry standard for the transmission of images and other medical information between computers to enable digital communication between diagnostic and therapy devices from different manufacturers.

According to the medical image standard DICOM-Ob ject model in combination with the JAVA applet and / or the JAVA script technology used in such a way that each in the sense a database technology normalized DICOM-Object as a JAVA applet software component using the JAVA language che and / or as a JAVA script software component Help of the JAVA language is implemented. Any such DICOM-Object is a JAVA applet and / or as a JAVA script Object in connection with medical imaging and / or patient monitoring, examination Listing or reporting. The JAVA language can be at for example from SUN.

The advantage of this proposal according to the invention lies in its flexibility and even more ease of use for data exchange with other modalities.

Claims (11)

1. Medical system architecture with a modality ( 1 to 4 ) for capturing images, a device ( 5 to 8 , 11 , 12 ) for processing the images and a device ( 9 ) for transmitting the images, in which the device ( 5 to 8 , 11 , 12 ) for processing has a digital image system with a computer that works according to a method for data exchange between different application programs with graphic control elements, an industry standard for the transmission of images and other medical information between computers to enable digital communication between the modalities of different manufacturers is implemented as a software component in combination with JAVA technology. 2. Medical system architecture according to claim 1, because characterized in that the Indu line standard is the DICOM standard. 3. Medical system architecture according to claim 1 or 2, characterized by the combination of the medical image standard DICOM Object Model with the SUN JAVA applet technology. 4. Medical system architecture according to claim 1 or 2, characterized by the combination of the medical image standard DICOM Object Model with the SUN JAVA script technology. 5. Medical system architecture according to claim 3 or 4, characterized in that each in the sense of a database technology normalized DICOM Ob ject (DICOM model) as a JAVA applet software component implemented using the SUN-JAVA language.   6. Medical system architecture according to one of the claims 3 to 5, characterized in that everyone normalized in terms of database technology DICOM Object as a JAVA script software component Help of the SUN-JAVA language is implemented. 7. Medical system architecture according to one of the claims 3 to 6, characterized in that everyone normalized in terms of database technology DICOM Object as a JAVA applet software component Help of the SUN-JAVA language is implemented, whereby JAVA-Net work to distribute the JAVA applet components different address spaces. 8. Medical system architecture according to one of the claims 1 to 7, characterized by the use of software components in medical Imaging. 9. Medical system architecture according to one of the claims 1 to 8, characterized by the Use of software components in patient Monitoring. 10. Medical system architecture according to one of the claims 1 to 8, characterized by the Use of the software components in the examination Listing. 11. Medical system architecture according to one of the claims 1 to 8, characterized by the Use of the software components for reporting.