JP7428081B2 - Sorting device, image processing system and program - Google Patents

Description

The present invention relates to a sorting device, an image processing system, and a program.

Medical image data is stored for long periods of time from the viewpoint of follow-up observation during medical examinations, comparison with past images, and to prevent medical errors. These image data are stored in a compressed format such as JPEG (Joint Photographic Experts Group) or JPEG2000 because a large amount of data is stored. At this time, in order to reduce the time required to decompress compressed images, measures have been taken to store the most recent image data in an uncompressed state. Particularly in recent years, high-speed SSD (Solid State Drive) disks have become common, and an information processing system that stores the most recent uncompressed image data on an SSD is known (see Patent Document 1).

On the other hand, in recent years, large-scale image storage servers such as VNA (Vendor Neutral Archive) have been proposed for the purpose of sharing image data among multiple departments and multiple facilities. Zero client terminals are known that do not require the installation of special software and can display images on browsers in various environments (see Patent Document 2). Zero client terminals do not have an OS (Operating System) or local storage.

Japanese Patent Application Publication No. 2015-228140 Japanese Patent Application Publication No. 2018-120279

Regarding storage of medical image data, there is a long-term storage (permanent storage) of image data such as radiation images that is required to be stored for 5 years by law, and a short-term storage (for example, a number of cases) of image data to be cached. 10 days) storage (temporary storage). Conventionally, servers have two types: a relatively inexpensive drive (HDD; Hard Disk Drive) that stores permanently saved image data as compressed image data, and a high-speed drive (SSD) that stores temporarily saved image data as uncompressed image data. ) and were equipped. In a system that provides saved image data to a client terminal, when one server (as an image storage device) with an HDD and an SSD is provided instead of multiple servers, access from the client terminal to the SSD is quick. .

On top of that, when the client terminal of the above system is made into a zero client terminal, a large number of zero client terminals are connected to the image storage device in order to generate image data to be displayed on the zero client terminal on the server as a server-side rendering mechanism. Ru.

In the case of the above system configuration, since a load is placed on the image storage device, a plurality of servers (referred to as image processing devices) that perform image rendering are also required. Since these multiple image processing devices need to refer to common image data (image files), the image data is compressed to the drive (HDD) of the image storage device on the network that can be commonly referenced by these image processing devices. Saved as image data. However, this takes time to decompress compressed image data.

Therefore, it is conceivable to store and use uncompressed image data in a high-speed SSD of an image storage device on a network. However, image data reference on the image storage device's network drive (including both HDD and SSD) is affected by network access, so even if uncompressed image data is stored on a high-speed SSD on the network, the SSD There was a risk that it would not be possible to perform a display that takes advantage of the performance that takes advantage of the advantages (the advantage of not taking time to decompress).

An object of the present invention is to provide high-speed image data reference even when a plurality of image processing devices that perform server side rendering (image data conversion for display) are provided.

In order to solve the above problem, the invention according to claim 1,
A sorting device communicatively connected to a plurality of image processing devices including a first storage unit that stores uncompressed image data and a client terminal that displays image data, the distribution device comprising:
Image processing in which image data requested by the client terminal is stored based on a storage table in which image data and the image processing device in which the image data is stored in a first storage unit are associated with each other. a selection section for selecting a device;
and a first control unit that requests the selected image processing apparatus to convert the reference-requested image data into image data for display on the client terminal.

The invention according to claim 2 is the sorting device according to claim 1, which comprises:
The first control unit transmits information about the selected image processing apparatus to the client terminal that has made the reference request .

The image processing system of the invention according to claim 3 includes:
The sorting device according to claim 1 or 2;
the plurality of image processing devices;
The client terminal;
The image processing device includes:
When processing of image data is requested, a second device reads the image data from the first storage section of the own device and converts the read image data into image data for display on the client terminal that is the source of the reference request . A control unit is provided.

The invention according to claim 4 is the image processing system according to claim 3,
The client terminal is a zero footprint terminal.

The invention according to claim 5 is the image processing system according to claim 3 or 4,
The selection unit selects one image processing device from the plurality of image processing devices when no image processing device is selected based on the storage table.

The invention according to claim 6 is the image processing system according to claim 5,
The selection unit selects an image processing apparatus to which the least number of client terminals are connected from among the plurality of image processing apparatuses when no image processing apparatus is selected based on the storage table.

The invention according to claim 7 is the image processing system according to claim 5 or 6,
The plurality of image processing devices are communicatively connected to a second storage unit that stores compressed image data,
When the image data for which the processing is requested is not stored in the first storage section of the own device, the second control section stores compressed image data corresponding to the image data from the second storage section. The acquired compressed image data is expanded and converted into image data for display on the client terminal that is the source of the reference request.

The invention according to claim 8 is the image processing system according to claim 7,
the second control unit stores the expanded image data in the first storage unit of its own device;
The selection unit holds information on the stored expanded image data, and selects whether the image data requested for reference from the client terminal is stored based on the stored image data information and the storage table. Select the image processing device you are using.

The program of the invention according to claim 9 is:
A computer of a sorting device that is communicatively connected to a plurality of image processing devices each having a storage unit that stores uncompressed image data and a client terminal that displays image data;
Selecting an image processing device that stores the image data requested for reference from the client terminal based on a storage table in which image data and the image processing device that stores the image data in a storage unit are associated with each other. A selection section to
a control unit that requests the selected image processing device to convert the reference-requested image data into image data for display on the client terminal;
function as

The invention according to claim 10 is the program according to claim 9,
The control unit transmits information about the selected image processing device to a client terminal that has made a reference request .

According to the present invention, high-speed image data reference can be provided even when a plurality of image processing devices that perform server-side rendering are provided.

1 is a block diagram showing a schematic configuration of an image processing system according to an embodiment of the present invention. FIG. 2 is a block diagram showing the functional configuration of an image storage device. FIG. 2 is a block diagram showing the functional configuration of an image processing device. FIG. 2 is a block diagram showing the functional configuration of a sorting device. FIG. 2 is a block diagram showing the functional configuration of a client terminal. FIG. 3 is a diagram showing the configuration of a storage table. 7 is a flowchart showing image data registration processing. 7 is a flowchart showing image data providing processing.

Embodiments and modifications of the present invention will be described in detail in order with reference to the accompanying drawings. Note that the present invention is not limited to the illustrated example.

(Embodiment)
Embodiments according to the present invention will be described with reference to FIGS. 1 to 8. First, the device configuration of this embodiment will be described with reference to FIGS. 1 to 5. FIG. 1 is a block diagram showing a schematic configuration of an image processing system 1. As shown in FIG. FIG. 2 is a block diagram showing the functional configuration of the image storage device 10. As shown in FIG. FIG. 3 is a block diagram showing the functional configuration of the image processing device 20A. FIG. 4 is a block diagram showing the functional configuration of the sorting device 30. FIG. 5 is a block diagram showing the functional configuration of the client terminal 40A.

The image processing system 1 according to the present embodiment is a server client system placed (installed) within the same medical facility such as a hospital. As shown in FIG. 1, the image processing system 1 includes an image storage device 10, image processing devices 20A, 20B, and 20C, a sorting device 30, and client terminals 40A and 40B. The number of image processing devices is just an example, and may be two, four or more. The number of client terminals is just an example, and may be three or more.

The image archiving device 10 is a server of a medical image archiving and communication system (PACS), and includes an HDD 13 as a second storage unit, and is connected to the image processing devices 20A, 20B, and 20C via a communication network. are connected and can communicate with each other. The image storage device 10 is connected to a modality (not shown) (for example, CR (Computed Radiography), CT (Computed Tomography), MRI (Magnetic Resonance Imaging), etc.), and stores medical images obtained by photographing a patient with the modality. Image data can be received from the modality. Then, the image storage device 10 compresses the received image data that must be stored for a predetermined storage period (5 years) and stores it in the HDD 13 as compressed image data for a predetermined period (5 years or more). It is possible to manage each.

The image processing devices 20B and 20C have the same configuration as the image processing device 20A, and the image processing device 20A will be mainly described below as a representative. The image processing device 20A is a server side rendering server, and includes a first storage unit and an SSD 23 as a storage unit, and is connected to the image storage device 10 and the distribution device 30 via a communication network, so that they can communicate with each other. ing. The image processing device 20A stores image data as uncompressed image data that is not compressed as a cache received from a modality (not shown) via the image storage device 10 in the SSD 23 for a predetermined period (for example, several tens of days). Then, when the image processing device 20A receives an image data reference request from the client terminal 40A or 40B via the distribution device 30, the image processing device 20A reads the image data from the HDD 13 or the SSD 23, and uses the read image data to create a file for browser display. Image data (web page data) is generated and transmitted to the sorting device 30.

The distribution device 30 is a server that selects an image processing device that performs rendering of image data, and is connected to the image processing devices 20A to 20C and client terminals 40A and 40B via a communication network so that they can communicate with each other. . When there is an image data reference request from the client terminal 40A or 40B, the sorting device 30 selects the image processing device 20A, 20B, or 20C, transmits the image data reference request, and sends the returned image data to the reference request. Send to the original client terminal.

The client terminal 40B has the same configuration as the client terminal 40A, and hereinafter, the client terminal 40A will mainly be described as a representative. The client terminal 40A is a zero footprint terminal. This zero-footprint terminal does not require the installation of special software and can display images on browsers in various environments, leaving no data (footprint) on the client terminal in applications distributed from the server. Although the terminal device does not have a local storage (storage unit 43 to be described later), it may be provided with a local storage (storage unit 43 to be described later).

The client terminal 40A is a terminal that displays medical image data, and is used by users such as doctors, nurses, and visiting caregivers in medical facilities. Note that the client terminal 40A may be configured to be provided at a home-visit nursing care office, a patient's home undergoing home treatment, or the like.

The HDD 13 and SSD 23 actually store not only image data but also examination data including examination image data, chart data, and the like.

Next, the functional configuration of the image storage device 10 will be explained with reference to FIG. The image storage device 10 includes a control section 11, an operation section 12, an HDD 13, a display section 14, a communication section 15, and the like. Each part of the image storage device 10 is connected to each other via a bus 16.

The control unit 11 includes a CPU (Central Processing Unit), a RAM (Random Access Memory), a storage unit, and the like. The CPU controls each part of the image storage device 10. Specifically, in the control unit 11, the CPU reads out various processing programs stored in the storage unit, develops them in the RAM, and performs various processes in cooperation with the developed programs. RAM is a volatile semiconductor memory that temporarily stores various data or programs. The storage unit of the control unit 21 is a storage unit that can read and write information from a HDD, an SSD, etc., and may be configured to be used also as the SSD 23. It is assumed that the storage section of the control section 11 stores an image data registration program for executing an image data registration process to be described later.

The operation unit 12 includes a keyboard having various keys and a pointing device such as a mouse, and outputs an operation signal input to the control unit 11 in response to a key operation on the keyboard or a position operation on the mouse.

The HDD 13 is a relatively inexpensive magnetic storage medium that stores various information in a readable and writable manner. The HDD 13 stores test data including compressed image data obtained by compressing test image data.

The display unit 14 includes a monitor such as an LCD (Liquid Crystal Display) or an EL (Electro Luminescence) display, and displays various screens according to instructions from display signals input from the control unit 11.

The communication unit 15 is configured with a network interface, etc., and communicates with external devices (image processing devices 20A, 20B, 20C) connected via a communication network such as a LAN (Local Area Network), WAN (Wide Area Network), or the Internet. Send and receive data between.

Next, with reference to FIG. 3, the functional configuration of the image processing device 20A will be described. The image processing device 20A includes a control section 21 as a second control section, an operation section 22, an SSD 23, a display section 24, a communication section 25, and the like. Each part of the image processing device 20A is connected to each other via a bus 26.

The control unit 21 includes a CPU, a RAM, a storage unit, and the like. The CPU controls each part of the image processing device 20A. Specifically, in the control unit 21, the CPU reads out various processing programs stored in the storage unit, develops them in the RAM, and performs various processes in cooperation with the developed programs. The storage unit of the control unit 21 is a storage unit that can read and write information from a HDD, an SSD, etc., and may be configured to be used also as the SSD 23.

The operation unit 22 includes a keyboard having various keys and a pointing device such as a mouse, and outputs an operation signal input to the control unit 21 in response to a key operation on the keyboard or a position operation on the mouse.

The SSD 23 is a semiconductor storage medium that stores various information in a readable and writable manner and has a faster access speed than the HDD 13. The SSD 23 stores test data including uncompressed image data that is not compressed test image data.

The display unit 24 includes a monitor such as an LCD or an EL display, and displays various screens according to instructions from display signals input from the control unit 21.

The communication unit 25 is configured with a network interface and the like, and sends and receives data to and from external devices (image storage device 10, sorting device 30) connected via a communication network such as a LAN, WAN, or the Internet.

Next, the functional configuration of the sorting device 30 will be explained with reference to FIG. The sorting device 30 includes a selection section, a first control section, a control section 31 as a control section, an operation section 32, a storage section 33, a display section 34, a communication section 35, and the like. Each part of the distribution device 30 is connected to each other via a bus 36.

The control unit 31 includes a CPU, a RAM, a storage unit, and the like. The CPU controls each part of the distribution device 30. Specifically, in the control unit 31, the CPU reads out various processing programs stored in the storage unit, develops them in the RAM, and performs various processes in cooperation with the developed programs. The storage unit of the control unit 31 is a storage unit such as an HDD or SSD from which information can be read and written, and may be configured to be used also as the storage unit 33.

The operation unit 32 includes a keyboard having various keys and a pointing device such as a mouse, and outputs an operation signal input to the control unit 31 in response to a key operation on the keyboard or a position operation on the mouse.

The storage unit 33 is a storage medium that stores various information in a readable and writable manner, and is an HDD, an SSD, or the like.

The display unit 34 includes a monitor such as an LCD or an EL display, and displays various screens according to instructions from display signals input from the control unit 31.

The communication unit 35 is configured with a network interface, etc., and exchanges data with external devices (image processing devices 20A, 20B, 20C, client terminals 40A, 40B) connected via a communication network such as a LAN, WAN, or the Internet. Send and receive.

Next, the functional configuration of the client terminal 40A will be explained with reference to FIG. The client terminal 40A includes a control section 41, an operation section 42, a storage section 43, a display section 44, a communication section 45, and the like. Each part of the client terminal 40A is connected to each other via a bus 46.

The control unit 41 includes a CPU, a RAM, a storage unit, and the like. The CPU controls each part of the client terminal 40A. Specifically, in the control unit 41, the CPU reads out various processing programs stored in the storage unit, develops them in the RAM, and performs various processes in cooperation with the developed programs. The storage unit of the control unit 31 is a storage unit such as an HDD or SSD from which information can be read and written, and may be configured to be used also as the storage unit 43.

The operation unit 42 has a keyboard with various keys and a pointing device such as a mouse, and transmits an operation signal input to the control unit 41 according to a key operation on the keyboard, a position operation on the mouse, or a position of a touch operation on the touch panel. Output to.

The storage unit 43 is a storage medium such as an HDD or an SSD that stores various information in a readable and writable manner.

The display unit 44 includes a monitor such as an LCD or an EL display, and displays various screens according to instructions from display signals input from the control unit 21.

The communication unit 45 is configured with a network interface and the like, and sends and receives data to and from an external device (distribution device 30) connected via a communication network such as a LAN, WAN, or the Internet.

Next, information stored in the distribution device 30 will be explained with reference to FIG. FIG. 6 is a diagram showing the configuration of the storage table 50.

A storage table 50 is stored in the storage unit 33 of the distribution device 30. As shown in FIG. 6, the storage table 50 has items for an examination 51 and an image processing device 52. The test 51 is test identification information of the test data. The image processing device 52 is identification information of the image processing device whose test data of the test 51 is stored in the SSD 23.

Next, the operation of the image processing system 1 will be explained with reference to FIGS. 7 and 8. FIG. 7 is a flowchart showing image data registration processing. FIG. 8 is a flowchart showing the image data providing process.

First, with reference to FIG. 7, the image data registration process executed by the image storage device 10 will be described. The image data registration process is a process in which image data of an examination received for storage is stored in the HDD 13 and the SSD 23 of the selected image processing device, and is registered in the storage table 50.

In the image storage device 10, when the communication unit 15 starts receiving image data for storage from a modality (not shown), the control unit 11 executes the image data registration program stored in the storage unit. Execute the image data registration process according to the following.

First, the control unit 11 receives image data for storage from a modality (not shown) via the communication unit 15 (step S11). The image data to be received is, for example, RAW data, and has patient identification information, examination identification information, etc. in the header part, and main data of the uncompressed image in the data part.

Then, the control unit 11 compresses the image data received in step S11 using a compression method such as JPEG or JPEG2000 to generate compressed image data (step S12). Then, the control unit 11 stores the compressed image data generated in step S12 in the HDD 13 for preservation (permanent preservation) (step S13).

Then, the control unit 11 reads the examination identification information of the image data received in step S11, and registers the record of the same examination as the read examination identification information in the examination 51 of the storage table 50 via the communication unit 15. The distribution device 30 is inquired as to whether or not there is one (step S14). Corresponding to step S14, when the control unit 31 of the sorting device 30 receives the inquiry from the image storage device 10 via the communication unit 35, it reads the storage table 50 from the storage unit 33 and stores the inspection identification information of the inquiry. It is confirmed whether it is registered, and the confirmation result is sent back to the image storage device 10 via the communication unit 35. If the same examination identification information exists, the confirmation result includes the image processing device 52 corresponding to the examination 51 of the same examination.

Then, the control unit 11 determines whether the same test is registered in the storage table 50 in response to receiving the confirmation result from the distribution device 30 in response to the inquiry in step S14 via the communication unit 15 (step S15).

If the same examination is registered (step S15; YES), the control unit 11 transmits the information received in step S11 to the image processing device 52 of the image processing device 52 corresponding to the registered examination 51 via the communication unit 15. The image data is sent and stored in the SSD 23 as uncompressed image data (step S16), and the image data registration process is ended. Corresponding to step S16, the control unit 21 of the destination image processing device receives image data from the image storage device 10 via the communication unit 25, and stores the image data in the SSD 23 of the own device.

If the same examination is not registered (step S15; NO), the control unit 11 randomly selects one image processing device to be saved from all the image processing devices 20A to 20C (step S17). The selection of one image processing device in step S17 is not limited to random selection. The selection of one image processing device in step S17 is the selection of an image processing device by round robin, the selection of the image processing device whose image data of the oldest examination is stored in the SSD 23, and the selection of the image processing device with the smallest load at that time. Selection of an image processing device, selection of an image processing device that is different from the image processing device that stores image data of past examinations of the same patient in the SSD 23, selection of a different image processing device for each series included in the examination, etc. good.

Selection of an image processing apparatus by round robin is a method of selecting a plurality of image processing apparatuses in turn. For example, the image processing devices are selected as follows: 20A→20B→20C→20A→20B... The image data of the examination stored in the SSD 23 of the image processing device is erased from the oldest examination, so by selecting the image processing device that has stored the image data of the oldest examination in the SSD 23, the image data of the subsequent SSD 23 can be deleted. free space can be increased. The image processing device with the least load at that point is, for example, the image processing device to which the least number of client terminals are connected. By selecting the image processing device with the least load, the load on the image processing device can be reduced.

Further, when image data is referred to on a client terminal, image data of the same region of the same modality may be displayed side by side on the same screen for comparison with past image data. For this reason, selecting an image processing device that stores image data from past examinations of the same patient (may be limited to the same modality) in the SSD 23 and a different image processing device is difficult because the image data processing load is This is a good case in terms of performance since it is distributed by processing devices. Similarly, when image data is referenced on a client terminal, image data of a plurality of series of the same examination may be displayed side by side on the same screen in order to compare the image data. Therefore, selecting a different image processing device for each series included in the examination is a case in which the load of image data processing is distributed among the plurality of image processing devices, which is good in terms of performance.

Then, the control unit 11 transmits the image data received in step S11 to the image processing device selected in step S17 via the communication unit 15, and causes the image processing device selected in step S17 to store it in the SSD 23 as uncompressed image data (step S18). . Corresponding to step S18, the control unit 21 of the destination image processing device receives image data from the image storage device 10 via the communication unit 25, and stores the image data in the SSD 23 of the own device.

Then, the control unit 11 transmits the examination identification information read in step S14 and the identification information of the image processing device selected in step S17 to the distribution device 30 via the communication unit 15, and The inspection 51 of 50 and the image processing device 52 are registered as a new record (step S19), and the image data registration process is ended. Corresponding to step S19, the control unit 31 of the sorting device 30 receives the examination identification information and the identification information of the image processing device from the image storage device 10 via the communication unit 35, and stores the information in the storage table 50. It is registered as a new record in the inspection 51 and image processing device 52.

Next, with reference to FIG. 8, the image data providing process executed by the sorting device 30 will be described. After the image data registration process, the image data provision process reads the image data from the SSD 23 of the image processing device in response to a reference request for image data of an arbitrary examination from the client terminal 40A or 40B, and sends the image data to the client that made the reference request. This is the process of providing and displaying the information on the terminal.

When the client terminal 40A or 40B receives an operation input from the user via the operation unit 42 requesting to refer to the image data of an arbitrary examination, the control unit 41 transmits the information of the examination to be displayed via the communication unit 45. An image data reference request is sent to the sorting device 30. In the distribution device 30, when the communication unit 35 starts receiving a reference request for examination image data from the client terminal 40A or 40B (the client terminal that has made the reference request), the control unit 31 controls the storage unit. The image data providing process is executed according to the image data providing program stored in the image data providing program.

Note that there is no problem even if the image data provision processing is performed by a device other than the image storage device 10. For example, the image data provision processing may be performed by the sorting device 30, or the image data may be distributed and transmitted to the image processing devices 20A to 20C, and each image processing The device may store only the image data received by itself in the SSD 23 of the device itself.

Further, as in the above example, a DB such as the storage table 50 is generally used to manage stored image data, but it is sufficient if the storage of image data is managed. For example, there may be another management server that manages stored image data that can be accessed from the client terminal.

As shown in FIG. 8, first, the control unit 31 receives a reference request for inspection image data from a client terminal that is a reference request source via the communication unit 35 (step S21). Then, the control unit 31 determines whether the test identification information of the test corresponding to the image data of the reference request received in step S21 is registered in the test in use list stored in the RAM (step S22). The test in use list is a temporary list that is provided for each client terminal, for example, and stores test identification information of the test corresponding to the displayed image data and the image processing device that read the image data from the HDD 13.

If the image processing apparatus is registered in the test use list (step S22; YES), the control unit 31 selects the image processing apparatus registered in the test use list (step S23). If it is not registered in the test usage list (step S22; NO), the control unit 31 reads the storage table 50 from the storage unit 33, and in the storage table 50, corresponds to the image data of the reference request received in step S21. It is determined whether the image processing device 52 corresponding to the test 51 to be performed is registered (step S24).

If the image processing device 52 is registered (step S24; YES), the control unit 31 stores the image processing device 52 corresponding to the examination 51 of the examination corresponding to the image data received in step S21 in the storage table 50. Select (step S25). If the image processing device 52 is not registered (step S24; NO), the control unit 31 selects the image processing device with the least number of sessions (number of connected client terminals) among all the image processing devices 20A to 20C. Select (step S26).

After step S25 or S26, the control unit 31 transmits the inspection information of the image data of the reference request received in step S21 and the image processing device selected in step S25 or S26 that is currently being used for inspection stored in the RAM. Register it in the list (step S27).

After step S23 or S27, the control unit 31 transmits, via the communication unit 35, an acquisition request for image data of the examination of the reference request received in step S21 to the image processing apparatus selected in step S23 or S27. (Step S28). In response to step S28 via step S23, the control unit 21 of the selected image processing device receives an acquisition request from the distribution device 30 via the communication unit 25, and receives an image of the examination corresponding to the received acquisition request. The data is read from the SSD 23 of the own device, the read image data is converted into image data for browser display, and is sent back to the distribution device 30. Furthermore, once the image data is converted, the control unit 21 of the selected image processing device stores the original image data in the SSD 23 for a certain period of time (for example, the client terminal will be stored until the user closes the display screen (browser).

In response to step S28 via step S25, the control unit 21 of the selected image processing device receives an acquisition request from the distribution device 30 via the communication unit 25, and receives an image of the examination corresponding to the received acquisition request. The data is read from the SSD 23 of the own device, the read image data is converted into image data for browser display, and is sent back to the distribution device 30.

In response to step S28 via step S26, the control unit 21 of the selected image processing device receives an acquisition request from the distribution device 30 via the communication unit 25, and receives an image of the examination corresponding to the received acquisition request. Compressed image data of the data is requested and acquired from the image storage device 10, the acquired compressed image data is expanded (decompressed), converted into image data for browser display, and sent back to the distribution device 30. The control unit 11 of the image storage device 10 receives a request for compressed image data from the selected image processing device via the communication unit 15, and compresses the image data of the examination corresponding to the received request for compressed image data. The image data is read from the HDD 13 and sent back to the selected image processing device.

Then, the control unit 31 receives image data for browser display from the selected image processing device via the communication unit 35, transmits it to the client terminal that made the reference request in step S21 (step S29), and End the data provision process. Corresponding to step S29, the control unit 41 of the client terminal that is the source of the reference request in step S21 receives image data for browser display from the distribution device 30 via the communication unit 45, and displays the image data on the browser of the display unit 44. to be displayed. In addition, the test usage list stored in the RAM of the image processing device and the image data stored in the SSD 23 are deleted when, for example, the display screen (browser) of the corresponding client terminal is closed. be done.

For example, when the client terminal 40A makes a request to refer to the image data of a study (study1), the image processing device 20A is selected from the storage table 50 in FIG. The image data of the inspection (study1) of the reference request is read out from the SSD 23 by the processing device 20A, converted to image data for browser display, and the converted image data for browser display is sent to the client terminal 40A of the reference request source. It is displayed on the display section 44.

As described above, according to the present embodiment, the distribution device 30 is communicatively connected to the image processing devices 20A to 20C including the SSD 23 that stores uncompressed image data, and the client terminals 40A and 40B that display the image data. be done. The sorting device 30 receives a reference request from the client terminal 40A or 40B based on the storage table 50 in which the image data of the examination and the image processing device 52 in which the image data (of the examination 51) is stored in the SSD 23 are associated. a control unit 31 that selects an image processing device that stores the image data requested for reference, and requests the selected image processing device to convert the reference-requested image data into image data for display on a client terminal; Equipped with. The image processing system 1 includes a sorting device 30, image processing devices 20A to 20C, and client terminals 40A and 40B. When the image processing devices 20A to 20C are requested to process image data from the distribution device 30, the image processing devices 20A to 20C read the image data from the SSD 23 of their own devices, and refer to the read image data as an image for display on the requesting client terminal. It includes a control unit 21 that converts into data.

For this reason, the image processing device requested to process reads the image data of the reference request from the SSD 23 serving as local storage of its own device and converts it into image data for browser display, and the distribution device 30 reads the image data of the reference request and converts it into image data for browser display. By transmitting the image data to the reference requesting client terminal and displaying it, high-speed image data reference can be provided even in the case where a plurality of image processing devices 20A to 20C that perform server side rendering are provided.

Further, the client terminals 40A and 40B are zero footprint terminals. Therefore, in addition to the effect of not leaving any personal information behind, with a zero-footprint terminal, when referring to image data, the displayed image data is not saved and the image data in the cache is reused ( The image processing device is accessed every time), so if the image processing device does not have cached image data, it will be slow. However, by storing the cached image data in the image processing device, the image data can be processed more quickly, and faster image data reference can be provided.

Furthermore, when no image processing apparatus is selected based on the storage table 50, the control unit 31 selects one image processing apparatus from among the image processing apparatuses 20A to 20C. Further, when no image processing apparatus is selected based on the storage table 50, the control unit 31 selects the image processing apparatus with the least number of client terminal connections (the least number of sessions) from among the image processing apparatuses 20A to 20C. select. Therefore, the processing load on the image processing devices 20A to 20C can be reduced, and faster image data reference can be provided.

Further, the image processing devices 20A to 20C are communicatively connected to an image storage device 10 including an HDD 13 that stores compressed image data. When the image data for which processing is requested is not stored in the SSD 23 of the own device, the control unit 21 acquires compressed image data corresponding to the image data from the HDD 13 of the image storage device 10, and stores the acquired compressed image data. is expanded and converted into image data for display on the client terminal that is the source of the reference request. Therefore, even if there is no registration in the storage table 50 and no image data is stored in the cache, image data reference can be provided.

Further, when the image data for which processing is requested is not stored in the SSD 23 of the own device, the control unit 21 stores image data expanded from the obtained compressed image data in the SSD 23 of the own device. The control unit 31 holds information on the stored expanded image data in the RAM as a test usage list, and stores the image data requested for reference from the client terminal based on the test usage list and the storage table 50. Select the image processing device you are using. Therefore, even for image data that is not registered in the storage table 50 and is stored in the SSD 23, high-speed image data reference can be provided.

(Modified example)
A plurality of modified examples of the above embodiment will be described.

First, in the above embodiment, when the CPU 31 of the sorting device 30 receives a request to display image data of an examination from a client terminal, the CPU 31 uses the storage table 50 or the like to display an image of the image data stored in the SSD 23. Although the configuration is such that a processing device is selected and processing of image data (reading and conversion of image data) is requested to the selected image processing device, the present invention is not limited to this.

For example, the sorting device 30 may receive data from the client terminal 40A or 40B based on the storage table 50 that associates the image data of the test with the image processing device 52 in which the image data (of the test 51) is stored in the SSD 23. A configuration including a control unit 31 that selects an image processing apparatus in which the image data requested for reference is stored and transmits information on the selected image processing apparatus to the client terminal that has made the reference request via the communication unit 35. do. Upon receiving the information of the selected image processing device from the distribution device 30 via the communication unit 45, the control unit 41 of the client terminal that is the reference request source transmits the reference request for the image data of the reference request to the selected image. The information of the processing device is sent to the corresponding image processing device. The control unit 21 of the image processing device receives a request to process image data from the client terminal via the communication unit 25, reads the image data from the SSD 23 in response to the received request to process the image data, and sends the image data to the browser. The image data is converted into image data for display, and the image data for browser display is directly transmitted to the client terminal that made the reference request via the communication unit 25.

For this reason, the image processing device that is directly requested to process by the client terminal reads the image data of the reference request from the SSD 23 serving as local storage of its own device, converts it into image data for browser display, and converts it into image data for browser display. By transmitting the image data to the reference requesting client terminal and displaying it, high-speed image data reference can be provided even in the case where a plurality of image processing devices 20A to 20C that perform server side rendering are provided.

Further, in the above embodiment, the image processing system 1 is arranged in the same medical facility, but the present invention is not limited to this. For example, a configuration may be adopted in which the image storage device 10 is located on a cloud, and a plurality of image processing devices, a sorting device 30, and a plurality of client terminals are located within the same medical facility.

Further, in the above embodiment, the image storage device 10 includes the HDD 13 and the image processing device includes the SSD 23, but the present invention is not limited to this. A performance difference occurs between the storage means of the image processing device and the storage means of the image storage device 10 (the storage means of the image processing device has a faster access (reading) speed than the storage means of the image storage device 10). That's fine. In particular, in a configuration where the image storage device 10 is located on the cloud, it is sufficiently effective even if the storage means of the image processing device is an HDD.

Further, for example, in a large group of hospitals, an image storage device may be shared, a plurality of image processing devices may be provided in each nearby region, and a client terminal may be provided at each hospital within the group.

Further, in the above embodiment, a plurality of image processing apparatuses are arranged in the same medical facility, but the present invention is not limited to this. For example, a configuration may be adopted in which a plurality of image processing devices are arranged across a plurality of medical facilities. Effects can be obtained if a plurality of image processing devices are arranged in any medical facility.

Further, in the above embodiment, the distribution device 30 has a configuration in which the storage table 50 is stored in the storage unit 33, but the present invention is not limited to this. The distribution device 30 may have a configuration in which the storage table 50 is stored in the HDD 13. The control unit 41 of the client terminal transmits, via the communication unit 45, a request for an image processing device in which image data of the examination is stored to the image storage device 10. When the control unit 11 of the image storage device 10 receives a request from a client terminal for an image processing device in which image data of an examination is stored via the communication unit 15, the storage table 50 etc. stored in the HDD 13 is received from a client terminal via the communication unit 15. is used to select an image processing device whose image data is stored in the SSD 23, and transmit information on the selected image processing device to the requesting client terminal via the communication unit 15. The request for image data processing from the client terminal to the image processing device is similar to the configuration in which the above-described distribution device 30 transmits information on the selected image processing device to the client terminal.

Alternatively, the image storage device 10 may be the backbone of a hospital, and each department within the hospital may have a plurality of image processing devices. It is assumed that the network communication speed within this department is high. Therefore, by arranging an image processing device within each department, it is possible to speed up the display of image data and reduce the load on the backbone network.

Further, for example, the control unit 31 of the sorting device 30 grasps the operating status of a plurality of image processing devices, and if an image processing device that is not started is registered in the storage table 50, it cannot be used by other image processing devices. A configuration may also be provided that has a function of distributing and requesting image data processing (image data reading and conversion).

In addition, if a specific image processing device is under a load (for example, a large number of client terminals are connected), the control unit 31 of the distribution device 30 controls the Alternatively, a configuration may be adopted in which the image data processing is distributed and requested to another image processing apparatus.

Furthermore, the following two configurations are possible assuming that the above-mentioned distribution device 30 manages only the storage table 50 and the client terminal directly makes inquiries to the image processing device. The first configuration is such that when the distribution device 30 cannot access the image processing device, the client terminal randomly selects an image processing device and requests image data processing (reading and converting image data). Good too. As a second configuration, if the client terminal has a record of accessing an image processing device in the past, the client terminal selects the same image processing device that it accessed in the past and processes the image data without inquiring the distribution device 30. It may also be configured to make a request.

Note that the descriptions in the above embodiments and modifications are examples of a suitable sorting device, sorting system, and program according to the present invention, and the present invention is not limited thereto. For example, at least two of the above embodiments and modifications may be combined as appropriate.

Further, the detailed configuration and detailed operation of each part constituting the image processing system 1 in the above embodiments and modified examples can be changed as appropriate without departing from the spirit of the present invention.

1 Image processing system 10 Image storage device 20A, 20B, 20C Image processing device 30 Sorting device 40A, 40B Client terminal 11, 21, 31, 41 Control unit 12, 22, 32, 42 Operation unit 13 HDD
23 SSD
33, 43 Storage section 14, 24, 34, 44 Display section 15, 25, 35, 45 Communication section 16, 26, 36, 46 Bus

Claims (10)

A sorting device communicatively connected to a plurality of image processing devices including a first storage unit that stores uncompressed image data and a client terminal that displays image data, the distribution device comprising:
Image processing in which image data requested by the client terminal is stored based on a storage table in which image data and the image processing device in which the image data is stored in a first storage unit are associated with each other. a selection section for selecting a device;
A distribution device comprising: a first control unit that requests the selected image processing device to convert the reference-requested image data into image data for display on the client terminal. The distribution device according to claim 1, wherein the first control unit transmits information about the selected image processing device to a client terminal that has made a reference request . The sorting device according to claim 1 or 2;
the plurality of image processing devices;
The client terminal;
The image processing device includes:
When processing of image data is requested, a second device reads the image data from the first storage section of the own device and converts the read image data into image data for display on the client terminal that is the source of the reference request . An image processing system including a control unit. The image processing system according to claim 3, wherein the client terminal is a zero footprint terminal. The image processing system according to claim 3 , wherein the selection unit selects one image processing device from the plurality of image processing devices when no image processing device is selected based on the storage table. The image processing device according to claim 5, wherein the selection unit selects an image processing device with the least number of client terminals connected from among the plurality of image processing devices when no image processing device is selected based on the storage table. processing system. The plurality of image processing devices are communicatively connected to a second storage unit that stores compressed image data,
When the image data for which the processing is requested is not stored in the first storage section of the own device, the second control section stores compressed image data corresponding to the image data from the second storage section. The image processing system according to claim 5 or 6, wherein the image processing system acquires the compressed image data, expands the acquired compressed image data, and converts it into image data for display on the client terminal that is the source of the reference request. the second control unit stores the expanded image data in the first storage unit of its own device;
The selection unit holds information on the stored expanded image data, and selects whether the image data requested for reference from the client terminal is stored based on the information on the stored image data and the storage table. 8. The image processing system according to claim 7, wherein the image processing system selects an image processing apparatus that is currently available. A computer of a sorting device that is communicatively connected to a plurality of image processing devices each having a storage unit that stores uncompressed image data and a client terminal that displays image data;
Selecting an image processing device that stores the image data requested for reference from the client terminal based on a storage table in which image data and the image processing device that stores the image data in a storage unit are associated with each other. A selection section to
a control unit that requests the selected image processing device to convert the reference-requested image data into image data for display on the client terminal;
A program to function as The program according to claim 9 , wherein the control unit transmits information about the selected image processing device to a client terminal that has made a reference request.

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