KR20200112572A - System transmitting uncompressed video signal for treatment device - Google Patents

Abstract

According to an embodiment of the present invention, provided is an uncompressed video transmission system for a treatment device which can transmit a high-capacity camera video at high speed through ultra-high speed proximity communication. The uncompressed video transmission system for a treatment device comprises: a controller connected to a treatment device equipped with a camera to receive a camera video; a first wireless communication device connected to the controller and having a communication protocol for wirelessly transmitting the camera video; and a second wireless communication device located in a short distance from the first wireless communication device to wirelessly receive the camera video, and connected to a manager terminal to provide the camera video to be displayed through a screen of the manager terminal.

Description

Wireless communication device for treatment device and uncompressed image transmission system equipped with it {SYSTEM TRANSMITTING UNCOMPRESSED VIDEO SIGNAL FOR TREATMENT DEVICE}

The present invention relates to an uncompressed image transmission system for a treatment device, and more particularly, to an uncompressed image transmission system for a treatment device implemented to transmit a camera image through short-range wireless communication in a treatment device equipped with an oral camera. will be.

In general, ultra-high-speed proximity communication technology is a large-capacity short-range wireless communication technology using the 60 GHz band, which enables wireless communication at 3.5 Gbps at a distance of 0.01m to 3m, and enables ultra-high-speed, low-power transmission, and is established as an international standard. It is possible to establish a leading position.

In addition, ultra-high-speed proximity communication technology is a next-generation ultra-high-speed short-range wireless communication technology that easily transmits and receives giga-class large-capacity content at a short distance without complicated access procedures. Ultra-high-speed proximity communication technology can transmit at a maximum of 3.5 Gbps, and uses the 60 GHz frequency band, which is an unlicensed frequency band, and for network construction of IoT, industrial production, medical care, self-driving cars, home infotainment, etc. It is applicable to various industrial fields.

In particular, ultra-high-speed proximity communication technology can be applied not only to network construction, but also to wireless unit devices to enhance the convenience of general devices, and future wireless contents such as VR/AR devices, wireless medical devices, wireless SSDs, wireless security devices, and wireless HDMI. It is expected to be greatly utilized for innovative expansion in the field of services and services.

On the other hand, oral endoscopy for dental treatment devices can expand the market for medical devices that require high-volume real-time information transmission such as 3D ultrasound and X-Ray/CT based on wireless image transmission solutions.

However, a system capable of transmitting a high-capacity wireless image of an oral endoscope quickly and easily without loss has not been implemented, so a study on a non-compressed image transmission system for a treatment device is required.

Republic of Korea Patent Publication No. 10-2003-0033247 (published on May 1, 2003)

An object of the present invention is for a treatment device implemented to receive a camera image by connecting it to a controller in a treatment device equipped with a camera, and to transmit an ultra-high-speed, high-capacity wireless transmission from a first wireless communication device connected to the controller to a second wireless communication device through short-range wireless communication. It provides an uncompressed image transmission system.

In addition, it provides an uncompressed image transmission system for a treatment device that implements a USB bridge function and can receive a camera image from a second wireless communication device connected to the manager terminal and USB and display it on the screen of the manager terminal.

The wireless communication device according to an embodiment of the present invention is connected to a controller connected to a treatment device equipped with a camera to wirelessly transmit a camera image at a short distance or wirelessly receive the camera image transmitted wirelessly, and is connected to a manager terminal to receive It characterized in that it provides to display the camera image through the screen of the manager terminal.

In the above, the wireless communication unit configuration management unit for controlling to receive the camera image; And a wireless communication unit that wirelessly transmits or receives a DP signal received from the DP port or a USB signal received from the USB port to another wireless communication device wirelessly connected by short-range wireless communication.

In the above, the wireless communication unit further comprises a signal control unit for selecting and controlling a signal of the DP port or the USB port under the control of the configuration management unit.

An uncompressed image transmission system for a treatment device according to an embodiment of the present invention includes a controller connected to a treatment device equipped with a camera to receive a camera image; A first wireless communication device connected to the controller and having a communication protocol for wirelessly transmitting the camera image; And a second wireless communication unit that is located in a short distance from the first wireless communication unit to receive the camera image wirelessly, and is connected to a manager terminal to provide the camera image to be displayed through a screen of the manager terminal.

In the above, the first and second wireless communication unit for controlling to receive the camera image; A wireless communication unit wirelessly transmitting or receiving a DP signal received from a DP port or a USB signal received from a USB port to another wireless communication device wirelessly connected by short-range wireless communication; It includes; a signal control unit for selecting and controlling a signal of the DP port or the USB port under the control of the configuration management unit.

In the above, the first wireless communication unit is characterized in that wirelessly transmitting the camera image to the second wireless communication unit using ultra-high-speed proximity communication.

In addition, the wireless communication device of the present invention can be manufactured as a micro-miniature communication chip having a size of 6x6 mm that includes a wireless communication unit, a serial-to-parallel converter, and a baseband modem, and a low-power micro-module capable of transmitting ultra-high speed wireless image data of 3 Gbps or higher in a short distance.

In addition, the uncompressed image transmission system for a treatment device of the present invention is connected to medical equipment in the form of USB and has versatility, receives image data at high speed, is connected to a wireless communication device in a USB type, and is paired with other wireless communication devices to provide high-speed proximity communication. As a result, high-capacity camera images can be transmitted at high speed.

Furthermore, the uncompressed image transmission system for a treatment device of the present invention can contribute to the medical field by transmitting high-definition, high-capacity camera images wirelessly to a dental oral endoscope at high speed, and in addition, high-capacity real-time such as 3D ultrasound and X-Ray/CT. There is an advantage of expanding the market for medical devices that need information transmission.

1 is a hardware configuration diagram of an uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention.
2 is a block diagram showing a schematic configuration of an uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention.
3 is a block diagram showing a detailed configuration of the first wireless communication device of FIG. 2.
4 is a view showing an example of measuring an image frame rate when wireless communication performance is deteriorated in an uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention.
5 is a screen showing a result of a test result of a 1080p, 30fps uncompressed image transmission without video loss in a wireless section of an uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention can add, change, or delete other elements within the scope of the same idea. Other embodiments included within the scope of the inventive concept may be easily proposed, but it will be said that this is also included within the scope of the inventive concept. In addition, components having the same function within the scope of the same idea shown in the drawings of each embodiment will be described with the same reference numerals.

1 is a hardware configuration diagram of an uncompressed image transmission system for a treatment device according to an embodiment of the present invention, and FIG. 2 is a schematic configuration diagram of an uncompressed image transmission system for a treatment device according to an embodiment of the present invention. It is a block diagram, and FIG. 3 is a block diagram showing a detailed configuration of the first wireless communication unit of FIG. 2.

The uncompressed image transmission system for a treatment device according to an embodiment of the present invention is implemented to wirelessly transmit a camera image through wireless communication in a treatment device 100 equipped with an oral camera.

Here, the treatment device 100 is a device in which an oral camera used in dentistry is mounted as an example, but may be another treatment device or a medical diagnosis device in which the camera is mounted. In addition, the camera included in the treatment apparatus 100 may be a wireless camera, and the camera quality requires high definition for the purpose of treatment and diagnosis. For example, the number of Full HD (High Definition) pixels is 1,920 x 1,080 = 2,073,600 pixels, The minimum required rate for Full HD data transmission may be 2,073,600 x 24 bits x 24 frames.

As shown in FIG. 1, the uncompressed image transmission system for a treatment device includes a controller 200, a first wireless communication device 300, and a second wireless communication device 400.

The controller 200 is a device connected to or mounted on the treatment device 100 and serves to transmit a high-definition camera image embedded in the treatment device 100 to the first wireless communication device 300.

To this end, the controller 200 is designed based on ODROID-XU4 manufactured by Hardkernel, for example, to implement a USB 3.0 bridge function, and can be provided with a camera image that is an uncompressed Full HD level or higher image at high speed through a wired USB connection.

To this end, the controller 200 is composed of a device driver for the Linux kernel, an oral camera initialization and plug-in monitoring module, and reads the camera image from the oral camera in real time and transmits it to the first wireless communication device 300 through another USB port. .

Further, the controller 200 may be implemented to transmit a camera image by connecting in a USB-C type, or may be implemented to be wired in the form of a display port (DP) or a high definition multimedia interface (HDMI) for high-speed transmission.

As shown in FIG. 1, the first wireless communication unit 300 is connected to the controller 200 to wirelessly transmit the camera image at a short distance, and the second wireless communication unit 400 is transmitted from the first wireless communication unit 300. The camera image can be wirelessly received, and the camera image can be provided so that the camera image is displayed through the screen of the manager terminal by being connected to the manager terminal.

Here, the manager terminal is a device that is connected to the second wireless communication unit 400 through a DP port or a USB port, and can receive and display a camera image on the screen. For example, a laptop computer, a desktop computer, a tablet PC, a smartphone, a phablet It could be a phone, etc.

In addition, the first wireless communication unit 300 and the second wireless communication unit 400 are equipped with a communication protocol for wireless communication, and are preferably WPAN ( Wireless Personal Arean Network) method can be used.

In one embodiment, the wireless communication module complies with IEEE 802.15.3e High-Rate Close Proximity Point to Point Communication (HRCP). The wireless communication module uses millimeter wave bands of 60GHz, 70GHz, and 80GHz bands. The wireless communication module has a maximum transmission speed of 7Gbps and 14Gbps.

In addition, Zigbee, UWB (Ultra Wide Band), Lora (Long Range) communication can be used by changing the communication chipset as necessary.

The first wireless communication device 300 is a communication module connected to a USB 3.0 bridge and has an oral endoscopic image transmission function.

Further, the second wireless communication unit 400 is a communication module connected to the manager terminal, and is equipped with a USB Video Class (UVC) communication protocol.

That is, the second wireless communication device 400 is connected to the manager terminal to transmit the camera image received through the communication module to the manager terminal and transmits the image data according to the UVC communication protocol.

Furthermore, the first and second wireless communication units (300, 400) are designed as LTCC (Low Temperature Co-fired Ceramic) boards applied with a 60GHz chipset to have a high dielectric constant in the 60GHz band for ultra-high-speed proximity communication, and a 60GHz chipset is mounted and USB 3.0 In order to provide an interface, it can be configured with, for example, CYPRESS's EZ-USB FX3 chip.

That is, the first and second wireless communication devices 300 and 400 may implement a 60GHz chipset control and data transmission/reception function through F/W mounted on the FX3 chip.

The first wireless communication unit 300 is a configuration management unit 310, a signal control unit 320, a wireless communication unit 330, a register unit 340, a baseband modem 350, a serial-to-parallel converter, as shown in FIG. (360) (SerDes, 360) is further included.

The configuration management unit 310 is connected to the controller 200 by wire through a DP port or a USB port to control the camera image to be transmitted.

In addition, the configuration management unit 310 controls the first and second wireless communication units 300 and 400 to enable mutual pairing when the first wireless communication unit 300 approaches the second wireless communication unit 400 at a recognizable short distance. .

The signal control unit 320 may recognize whether the camera image signal input by the control of the configuration management unit 310 is a DP port or a USB port and control to transmit the corresponding signal, and the signal control unit 320 is, for example, a multiplexer (MUX ) Can be.

The signal control unit 320 is connected to the DP signal processing unit 321 and the USB signal processing unit 323 so that when the corresponding signal is a DP signal, it can be transmitted through the DP signal processing unit 321, and when the corresponding signal is a USB signal. , It can be controlled to be transmitted through the USB signal processing unit 323.

The DP signal processing unit 321 transmits the DP signal to the wireless communication unit 330 through the DP signal control unit 322.

In addition, the USB signal processing unit 323 transmits the USB signal to the serial/parallel converter 360 through the USB signal control unit 324 and the baseband modem 350.

The serial-to-parallel converter 360 serializes and transmits parallel bits (16, 32 bits, etc.) of the USB signal to the second wireless communication device 400 as a bit string.

The wireless communication unit 330 transmits a DP signal or a USB signal selectively controlled by the signal control unit 320 through short-range wireless communication.

The register unit 340 is connected to the configuration management unit 310 to control the configuration management unit 310 to receive a camera image or temporarily store control information necessary for pairing the first and second wireless communication units 300 and 400 Functions as a device.

The baseband modem 350 is connected to the USB signal control unit 324 to enable camera image transmission in a short distance without modulation.

In addition, the second wireless communication unit 400 also includes the same configuration (410 to 460) as each of the above-described units (310 to 360) to perform the same function as the first wireless communication unit 300, the overlapping description is Omit it.

The serial-to-parallel converter 460 included in the second wireless communication unit 400 may perform a role of restoring the bit sequence of the camera image transmitted from the first wireless communication unit 300 back to the original parallel bit. A transmission code encoding and decoding function may be embedded in the serial/parallel converter 460.

The wireless communication unit 430 included in the second wireless communication unit 400 serves to receive a DP signal or a USB signal selected and controlled by the signal control unit 420 through short-range wireless communication.

4 is a diagram showing an example of measuring an image frame rate when wireless communication performance is deteriorated in an uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention, according to wireless communication states such as radio wave interference and distortion. It indicates that the frame loss for the received video and the reception frame rate are lowered.

In particular, it is preferable that the uncompressed image transmission system for a treatment apparatus of the present invention is controlled to lower the frame rate and lower the image quality when the wireless communication condition is not good as described above to enable seamless reproduction of the received image.

In addition, FIG. 5 is a screen showing a result of a test result of an uncompressed image transmission of 1080p and 30fps without image loss in a wireless section of the uncompressed image transmission system for a treatment apparatus according to an embodiment of the present invention. It shows the result screen of the uncompressed image transmission test.

100: treatment device 200: controller
300: first wireless communication unit 310, 410: configuration management unit
320, 420: signal control unit 321, 421: DP signal processing unit
322, 422: DP signal control unit 323, 423: USB signal processing unit
324, 424: USB signal control unit 330, 430: wireless communication unit
340, 440: register unit 350, 450: baseband modem
360, 460: serial-to-parallel converter 400: second wireless communication device
500: administrator terminal

Claims (6)

It is connected to a controller connected to a treatment device equipped with a camera to wirelessly transmit the camera image at a short distance, or
A wireless communication device for a treatment apparatus, characterized in that for receiving the wirelessly transmitted camera image wirelessly, and providing to display the received camera image through a screen of the manager terminal. The method of claim 1,
The wireless communication unit
A configuration management unit that controls to receive the camera image; And
A wireless communication unit for a treatment apparatus further comprising a wireless communication unit for wirelessly transmitting or receiving the DP signal received from the DP port or the USB signal received from the USB port to another wireless communication unit wirelessly connected by short-range wireless communication. The method of claim 2,
The wireless communication unit
A wireless communication device for a treatment apparatus further comprising a signal control unit for selectively controlling a signal of a DP port or a USB port under the control of the configuration management unit. A controller connected to a treatment device equipped with a camera to receive a camera image;
A first wireless communication device connected to the controller and having a communication protocol for wirelessly transmitting the camera image; And
No compression for a treatment device comprising a second wireless communication device located in a short distance from the first wireless communication device to receive the camera image wirelessly, and connected to a manager terminal to display the camera image through the screen of the manager terminal Video transmission system. The method of claim 4,
The first and second wireless communication devices
A configuration management unit that controls to receive the camera image;
A wireless communication unit wirelessly transmitting or receiving a DP signal received from a DP port or a USB signal received from a USB port to another wireless communication device wirelessly connected by short-range wireless communication; And
Uncompressed image transmission system for a treatment apparatus comprising a signal control unit for selectively controlling a signal of a DP port or a USB port under the control of the configuration management unit. The method of claim 4,
The first wireless communication device
An uncompressed image transmission system for a treatment apparatus, characterized in that wirelessly transmitting the camera image to the second wireless communication device using ultra-high-speed proximity communication.

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