CN106562798B - Flat panel detector system and method for rapid configuration and image derivation thereof - Google Patents

Abstract

The present invention provides a flat panel detector system, the system comprising: a wired network; a wireless access device connected to the wired network; the upper computer is connected with the network, configures network parameters and writes the network parameters into the charger or the battery; the charger is connected with the upper computer and is used for charging the battery and comparing the configuration file in the battery with networking parameters, and if the configuration file in the battery is different from the networking parameters, the networking parameters are written into the battery; a battery matched with the charger for storing networking parameters, images and supplying power for the detector; the flat panel detector matched with the battery reads the parameters of the battery intranet and completes the setting of the IP address of the flat panel detector, and after the flat panel detector is connected with the wireless access equipment, the flat panel detector passes through the security authentication, performs X-ray imaging and uploads the image to the workstation. The flat panel detector system and the rapid configuration and image deriving method thereof solve the problems that the wireless network pairing of the existing detector is complicated, and when the flat panel detector is disconnected with the network and the image cannot be uploaded, the image deriving method is inconvenient and effective.

Description

Flat panel detector system and method for rapid configuration and image derivation thereof

Technical Field

The invention mainly relates to the field of wireless X-ray flat panel detectors and computer intelligent communication, in particular to a flat panel detector system and a rapid configuration and image derivation method thereof.

Background

X-ray detectors have evolved over the century from traditional film-like to digital-like, which in turn has undergone CR detectors, CCD X-ray detectors, CCD tiled X-ray detectors, and the most popular X-ray flat panel detectors today. The X-ray flat panel detector can capture X-rays, convert X-ray images of a detected object into digital images for convenient viewing, analysis, storage and transmission, and is widely applied to the fields of medical treatment, biology, materials, industrial detection and the like.

The X-ray flat panel detector can be divided into a direct imaging type and an indirect imaging type, wherein the direct imaging type detector directly converts X-rays into electric signals, and the indirect imaging type detector structure is composed of a scintillation material or fluorescent material layer, an amorphous silicon layer with photodiode function and a TFT array, wherein a layer of scintillator or fluorescent material is adopted to convert the X-rays into visible light, and then the visible light detector converts the visible light into the electric signals. After the electric signal is obtained, the detector transmits the data to a computer for display and storage according to a certain format after filtering, amplifying and analog-to-digital conversion.

X-ray photography systems, commonly known as X-ray machines (here for digital X-ray machines only, i.e. digital flat panel detectors: DR), include X-ray flat panel detectors, frames, bulbs, high voltage, imaging software; the X-ray flat panel detector is the key component at the most core, and is used as an image component for receiving the X-ray imaging uploading of the attenuated measured object, so that the most important link of the system image chain is realized.

At present, a wireless communication mode is realized by the digital flat panel detector, and the digital flat panel detector is connected with a DR host system through wireless signals. Pairing a digital flat panel detector with the wireless network where the DR host system resides can be a cumbersome task. Currently, a more common way is to manually configure the cable connection through a UI interface, or to quickly pair the cable connection through infrared or other ways requiring additional accessories for support. Therefore, configuring the digital flat panel detector to connect to the wireless network in a fast, simple and automatic manner is an urgent problem to be solved.

Meanwhile, portable tablet application is realized based on the electronic cassette, and the user can get the picture after exposure in the use environment without a wireless network, so that the function of the cassette is truly realized. At this time, the photographed image is stored in the digital flat panel detector, and an effective medium is required to derive the image data.

In view of this, there is a need to design a new flat panel detector system and a method for rapid configuration and image derivation thereof to solve this problem.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present invention is to provide a flat panel detector system and a method for rapidly configuring and image deriving thereof, which are used for solving the problems that in the prior art, the pairing of wireless networks of flat panel detectors is complicated, and when the flat panel detectors are disconnected from the networks and cannot upload images, there is no convenient and effective method for deriving image data.

To achieve the above and other related objects, the present invention provides a flat panel detector system, comprising:

a wired network for providing a network to the flat panel detector system;

the wireless access device is connected with the wired network and is used for converting the wired network into a wireless network and providing the wireless network for the flat panel detector;

the upper computer is connected with the wired network or the wireless network and is used for configuring networking parameters and writing the networking parameters into the charger or the battery;

the charger is connected with the upper computer and is used for charging the battery and comparing whether the configuration file in the battery is consistent with the networking parameters or not, and if not, the networking parameters are written into the battery;

the battery is used in cooperation with the charger and is used for storing networking parameters, images shot by the flat panel detector and supplying power to the flat panel detector; and

the flat panel detector is used for reading networking parameters in the battery, finishing setting of an IP address of the flat panel detector, establishing connection with the wireless access equipment, passing security authentication, performing X-ray imaging and uploading images to a workstation.

Preferably, the charger comprises:

a charging circuit for charging the battery;

the control unit is connected with the charging circuit and used for controlling the read-write unit, the first storage unit and the comparison unit;

the read-write unit is connected with the control unit and is used for reading and writing networking parameters in the upper computer and configuration files in the battery;

the first storage unit is connected with the control unit and is used for storing networking parameters read from the upper computer and configuration files read from the battery;

and the comparison unit is connected with the control unit and is used for comparing networking parameters with the configuration file.

Preferably, the battery includes:

the battery pack is used for storing electric energy and supplying power for the flat panel detector;

the charge and discharge management unit is connected with the battery pack and used for controlling charge and discharge of the battery;

the second storage unit is connected with the charge and discharge management unit and is used for storing networking parameters and images shot by the flat panel detector;

the golden finger is positioned on the battery and is used for realizing the electric connection between the battery and the flat panel detector; and

and the USB interface is positioned on the battery and used for realizing the connection between the battery and the upper computer.

Preferably, when the battery is directly connected with the upper computer through the USB interface, the upper computer charges the battery and compares whether the configuration file in the battery is consistent with the networking parameters, and if not, the networking parameters are written into the battery.

Preferably, the charger is connected with the upper computer through a USB interface.

Preferably, the wireless access device is a wireless router.

Preferably, the control unit comprises one of an MCU, FPGA, or DSP.

Preferably, the flat panel detector comprises one of an amorphous selenium flat panel detector, a CCD flat panel detector and an amorphous silicon flat panel detector.

The invention also provides a method for rapidly configuring and deriving images of a flat panel detector system according to any one of the above, the method comprising:

1) When a peripheral is connected to the upper computer, the upper computer judges whether the connected peripheral is a charger or a battery; when the peripheral is a charger, jumping to 2); when the peripheral is a battery, jumping to 4);

2) Configuring networking parameters for the charger through the upper computer, and storing the networking parameters in the charger;

3) When the charger charges the battery, reading out a configuration file in the battery, and comparing whether networking parameters are consistent with the configuration file or not; if the charging conditions are matched, jumping to the step 5) after the charging is finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

4) The upper computer charges the battery and compares whether the configuration file in the battery is consistent with the networking parameters, if so, the upper computer jumps to 5) after waiting for the charging to be finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

5) Inserting a battery into a flat panel detector, reading in networking parameters when the flat panel detector is started and initialized, finishing the setting of an IP address of the flat panel detector, and connecting with the wireless access equipment according to the networking parameters and passing security authentication;

6) When X-ray shooting and imaging are carried out through the flat panel detector, the shot images are uploaded to the workstation and stored in the battery, and the battery is connected with the upper computer to read out the images stored in the battery.

Preferably, the battery also stores an image information retrieval table for inquiring whether the image is uploaded to the workstation.

Preferably, when the wireless access device adopts a client mode, the networking parameters include SSID and key of the wireless access device, IP address of the flat panel probe and subnet mask thereof.

Preferably, when the wireless access device adopts a virtual wireless access point mode, the networking parameters include SSID of the wireless access device and its key, encryption mode, frequency, band, country code and channel.

Preferably, when the upper computer is a specific upper computer, the networking parameter further includes an IP address of the upper computer and a port number thereof.

Preferably, the wireless access device is a wireless router.

Preferably, the IP addresses of the upper computer, the wireless router, and the flat panel detector are in the same network segment.

As described above, the flat panel detector system and the method for rapid configuration and image derivation thereof of the present invention have the following advantages:

1. the flat panel detector system supports a plug and play use mode, and can realize quick switching and shared use of the flat panel detector in different workstation environments by configuring networking parameters once through an upper computer without using an additional configuration module.

2. The invention realizes image storage and export through the battery, and conveniently and effectively realizes image storage and export.

3. The invention can also directly use the USB interface to charge and configure the battery, thereby increasing the flexibility of the system.

Drawings

FIG. 1 shows a system block diagram of a flat panel detector system according to the present invention.

Fig. 2 shows a system block diagram of a charger in the flat panel detector system according to the present invention.

Fig. 3 shows a block diagram of a battery in the flat panel detector system according to the present invention.

FIG. 4 is a flowchart showing steps of a method for rapid configuration and image derivation of a flat panel detector system according to the present invention.

Description of element reference numerals

1. Flat panel detector system

11. Wired network

12. Wireless access device

13. Upper computer

14. Charger (charger)

141. Charging circuit

142. Control unit

143. Read-write unit

144. First memory cell

145. Comparison unit

15. Battery cell

151. Battery pack

152. Charging and discharging management unit

153. Second memory cell

154. Golden finger

155 USB interface

16. Flat panel detector

1) Step 6)

Detailed Description

Other advantages and effects of the present invention will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present invention with reference to specific examples. The invention may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present invention.

Please refer to fig. 1 to 4. It should be noted that, the illustrations provided in the present embodiment merely illustrate the basic concept of the present invention by way of illustration, and only the components related to the present invention are shown in the drawings and are not drawn according to the number, shape and size of the components in actual implementation, and the form, number and proportion of the components in actual implementation may be arbitrarily changed, and the layout of the components may be more complex.

Example 1

As shown in fig. 1, the present invention provides a flat panel detector system 1, comprising:

a wired network 11 for providing a network to the flat panel detector system 1;

a wireless access device 12 connected to the wired network 11 for converting the wired network 11 into a wireless network to provide a wireless network for the flat panel detector 16;

the upper computer 13 connected with the wired network 11 or the wireless network is used for configuring networking parameters and writing the networking parameters into the charger 14 or the battery 15;

the charger 14 is connected with the upper computer 13 and is used for charging the battery 15 and comparing whether the configuration file in the battery 15 accords with the networking parameters or not, and if not, the networking parameters are written into the battery 15;

a battery 15 used in cooperation with the charger 14 for storing networking parameters, images taken by the flat panel detector 16, and supplying power to the flat panel detector 16; and

the flat panel detector 16, which is used in cooperation with the battery 15, is configured to read networking parameters in the battery 15, complete setting of an IP address of the flat panel detector, establish connection with the wireless access device 12 by itself, pass security authentication, perform X-ray imaging, and upload images to a workstation.

Specifically, the wired network 11 is an ethernet, and is connected to the wireless access device 12 and the host computer 13 through ethernet lines, respectively.

Preferably, in this embodiment, the wireless access device 12 is a wireless router. Of course, in other embodiments, the wireless access device 12 may be other devices capable of implementing wireless access functions.

Preferably, in the present embodiment, the upper computer 13 is a computer, and the computer is connected to the ethernet through the wired network 11.

As shown in fig. 2, the charger 14 includes:

a charging circuit 141 for charging the battery 15;

a control unit 142 connected to the charging circuit 141 for controlling the read/write unit 143, the first storage unit 144, and the comparison unit 145;

the read-write unit 143 connected with the control unit 142 is used for reading and writing networking parameters in the upper computer 13 and configuration files in the battery 15;

a first storage unit 144 connected to the control unit 142, for storing the networking parameters read from the upper computer 13 and the configuration files read from the battery 15;

a comparison unit 145, connected to the control unit 142, is used for comparing networking parameters with the configuration file.

The charger 14 is connected with the upper computer 13 through a USB interface.

The charging circuit 141 is any conventional circuit capable of charging a battery.

Preferably, the control unit 142 includes, but is not limited to, one of an MCU, an FPGA, or a DSP. Further preferably, in the present embodiment, the control unit 142 is an FPGA (field programmable gate array); of course, in other embodiments, the control unit 142 may also be an MCU, a DSP, or other unit capable of performing control functions.

As shown in fig. 3, the battery 15 includes:

a battery pack 151 for storing electric energy to supply power to the flat panel detector 16;

a charge and discharge management unit 152 connected to the battery pack 151 for controlling charge and discharge of the battery 15;

a second storage unit 153 connected to the charge/discharge management unit 152, for storing networking parameters and images captured by the flat panel detector 16;

a gold finger 154 on the battery 15 for electrically connecting the battery 15 with the flat panel detector 16; and

the USB interface 155 is located on the battery 15, and is used for implementing connection between the battery 15 and the host computer 13.

When the battery 15 is directly connected with the upper computer 13 through the USB interface 155, the upper computer 13 charges the battery 15 and compares whether the configuration file in the battery 15 matches with the networking parameters, if not, the networking parameters are written into the battery 15.

Preferably, in the present embodiment, the second storage unit 153 is a mass memory.

Preferably, the flat panel detector 16 comprises one of an amorphous selenium flat panel detector, a CCD flat panel detector, and an amorphous silicon flat panel detector.

Example two

The present invention also provides a method for rapid configuration and image derivation of a flat panel detector system as described in embodiment one, the method comprising:

1) When a peripheral is connected to the upper computer, the upper computer judges whether the connected peripheral is a charger or a battery; when the peripheral is a charger, jumping to 2); when the peripheral is a battery, jumping to 4);

2) Configuring networking parameters for the charger through the upper computer, and storing the networking parameters in the charger;

3) When the charger charges the battery, reading out a configuration file in the battery, and comparing whether networking parameters are consistent with the configuration file or not; if the charging conditions are matched, jumping to the step 5) after the charging is finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

4) The upper computer charges the battery and compares whether the configuration file in the battery is consistent with the networking parameters, if so, the upper computer jumps to 5) after waiting for the charging to be finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

5) Inserting a battery into a flat panel detector, reading in networking parameters when the flat panel detector is started and initialized, finishing the setting of an IP address of the flat panel detector, and connecting with the wireless access equipment according to the networking parameters and passing security authentication;

6) When X-ray shooting and imaging are carried out through the flat panel detector, the shot images are uploaded to the workstation and stored in the battery, and the battery is connected with the upper computer to read out the images stored in the battery.

When the wireless access device adopts the Client mode, the networking parameters include SSID and key of the wireless access device, IP address of the flat panel detector and subnet mask thereof.

It should be noted that, when the wireless access device adopts an AP (wireless access point) mode, the WiFi module of the flat panel detector needs to be turned on in a hotspot mode, where the networking parameters include the SSID of the wireless access device, its secret key, encryption mode, frequency, band, country code and channel, the IP address of the flat panel detector and its subnet mask.

It should be further noted that, when the upper computer is a specific upper computer, the networking parameter further includes an IP address of the upper computer and a port number thereof.

It should be further noted that the subnet mask of the flat panel detector is generally 255.255.255.0 by default.

It should be noted that, the IP address of the upper computer and the IP address of the flat panel detector must be set in the same network segment, and the IP address of the wireless access device may not be set.

Preferably, the wireless access device is a wireless router, and the IP addresses of the upper computer, the wireless router, and the flat panel detector are set in the same network segment.

Specifically, the battery is also stored with an image information retrieval table for inquiring whether the image is uploaded to the workstation.

When the battery is connected with the workstation, the images stored in the battery can be checked through the image information retrieval table stored in the battery, which images are uploaded to the workstation and which images are not uploaded to the workstation, so that the staff can derive and archive the images which are not uploaded to the workstation according to the information of the image information retrieval table.

In summary, the flat panel detector system and the method for rapidly configuring and deriving images of the invention have the following advantages:

1. the flat panel detector system supports a plug and play use mode, and can realize quick switching and shared use of the flat panel detector in different workstation environments by configuring networking parameters once through an upper computer without using an additional configuration module.

2. The invention realizes image storage and export through the battery, and conveniently and effectively realizes image storage and export.

3. The invention can also directly use the USB interface to charge and configure the battery, thereby increasing the flexibility of the system.

Therefore, the invention effectively overcomes various defects in the prior art and has high industrial utilization value.

The above embodiments are merely illustrative of the principles of the present invention and its effectiveness, and are not intended to limit the invention. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, it is intended that all equivalent modifications and variations of the invention be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (13)

1. A flat panel detector system, the system comprising:

a wired network for providing a network to the flat panel detector system;

the wireless access device is connected with the wired network and is used for converting the wired network into a wireless network and providing the wireless network for the flat panel detector;

the upper computer is connected with the wired network or the wireless network and is used for configuring networking parameters and writing the networking parameters into the charger or the battery;

the charger is connected with the upper computer and is used for charging the battery and comparing whether the configuration file in the battery is consistent with the networking parameters or not, and if not, the networking parameters are written into the battery;

the battery is used in cooperation with the charger and is used for storing networking parameters, images shot by the flat panel detector and supplying power to the flat panel detector; and

the flat panel detector is used with the battery, is used for reading networking parameters in the battery, finishing the setting of an IP address of the flat panel detector, automatically establishing connection with the wireless access equipment, passing security authentication, performing X-ray imaging and uploading images to a workstation;

wherein, the charger includes:

a charging circuit for charging the battery;

the control unit is connected with the charging circuit and used for controlling the read-write unit, the first storage unit and the comparison unit;

the read-write unit is connected with the control unit and is used for reading and writing networking parameters in the upper computer and configuration files in the battery;

the first storage unit is connected with the control unit and is used for storing networking parameters read from the upper computer and configuration files read from the battery;

the comparison unit is connected with the control unit and used for comparing networking parameters with the configuration file;

the battery includes:

the battery pack is used for storing electric energy and supplying power for the flat panel detector;

the charge and discharge management unit is connected with the battery pack and used for controlling charge and discharge of the battery;

the second storage unit is connected with the charge and discharge management unit and is used for storing networking parameters and images shot by the flat panel detector;

the golden finger is positioned on the battery and is used for realizing the electric connection between the battery and the flat panel detector; and

and the USB interface is positioned on the battery and used for realizing the connection between the battery and the upper computer.

2. The flat panel detector system according to claim 1, wherein when the battery is directly connected to the upper computer via the USB interface, the upper computer compares whether the configuration file in the battery matches the networking parameters while charging the battery, and if not, writes the networking parameters into the battery.

3. The flat panel detector system according to claim 1, wherein the charger is connected to the host computer through a USB interface.

4. The flat panel detector system according to claim 1, wherein the wireless access device is a wireless router.

5. The flat panel detector system according to claim 1, wherein the control unit comprises one of an MCU, FPGA, or DSP.

6. The flat panel detector system of claim 1, wherein the flat panel detector comprises one of an amorphous selenium flat panel detector, a CCD flat panel detector, an amorphous silicon flat panel detector.

7. A method of rapid configuration and image derivation of a flat panel detector system as claimed in any one of claims 1 to 6, wherein the method comprises:

1) When a peripheral is connected to the upper computer, the upper computer judges whether the connected peripheral is a charger or a battery; when the peripheral is a charger, jumping to 2); when the peripheral is a battery, jumping to 4);

2) Configuring networking parameters for the charger through the upper computer, and storing the networking parameters in the charger;

3) When the charger charges the battery, reading out a configuration file in the battery, and comparing whether networking parameters are consistent with the configuration file or not; if the charging conditions are matched, jumping to the step 5) after the charging is finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

4) The upper computer charges the battery and compares whether the configuration file in the battery is consistent with the networking parameters, if so, the upper computer jumps to 5) after waiting for the charging to be finished; if not, writing the networking parameters into the battery, and jumping to 5) after the charging is finished;

5) Inserting a battery into a flat panel detector, reading in networking parameters when the flat panel detector is started and initialized, finishing the setting of an IP address of the flat panel detector, and connecting with the wireless access equipment according to the networking parameters and passing security authentication;

6) When X-ray shooting and imaging are carried out through the flat panel detector, the shot images are uploaded to the workstation and stored in the battery, and the battery is connected with the upper computer to read out the images stored in the battery.

8. The method for quickly configuring and retrieving images of flat panel detectors according to claim 7, wherein said battery further stores an image information search table for inquiring whether an image is uploaded to a workstation.

9. The method for rapid configuration and image derivation of a flat panel detector of claim 7, wherein the networking parameters comprise SSID and key of the wireless access device, IP address of the flat panel detector, and subnet mask thereof, when the wireless access device is in Client mode.

10. The method for rapid configuration and image derivation of flat panel detector according to claim 7, wherein when the wireless access device adopts AP mode, the networking parameters include SSID of the wireless access device and its key, encryption mode, frequency, band, country code and channel, IP address of flat panel detector and its subnet mask.

11. The method for rapid configuration and image derivation of flat panel detector according to claim 9 or 10, wherein when the host computer is a specific host computer, the networking parameters further include an IP address of the host computer and a port number thereof.

12. The method for rapid configuration and image derivation of flat panel detectors of claim 7, wherein the wireless access device is a wireless router.

13. The method for rapid configuration and image derivation of a flat panel detector according to claim 12, wherein the host computer, wireless router, and IP address of the flat panel detector are within the same network segment.