CN213305574U - Control-deployment camera system and control-deployment camera - Google Patents

Abstract

The application relates to a cloth accuse camera system and cloth accuse camera, this cloth accuse camera system includes: an image acquisition unit; the data analysis unit is in communication connection with the image acquisition unit; the 5G module image transmission unit is in communication connection with the data analysis unit; the image acquisition unit acquires image data; the data analysis unit receives the image data and analyzes the image data; the 5G module image transmission unit carries out data processing on the analyzed image data according to a 5G3GPP standard and sends the processed data according to the 5G3GPP standard; the problem of video jamming or transmission delay caused by insufficient bandwidth when the fourth generation mobile communication technology is used for data transmission can be solved; the data transmission requirement of large data volume and high bandwidth can be met by transmitting data through the 5G antenna in the 5G module image transmission unit, and therefore the problem of video blocking or transmission delay caused by insufficient bandwidth in the data transmission process can be solved.

Description

Control-deployment camera system and control-deployment camera

Technical Field

The application relates to a deployment control camera system and a deployment control camera, and belongs to the technical field of video monitoring.

Background

In the security industry, deployment and control cameras are more and more widely used, and with the continuous popularization of 4K high-definition resolution cameras and Artificial Intelligence (AI) cameras and the maturity of multi-path high-definition video splicing technology, the data volume of video code streams in the data transmission process is also continuously increased.

Currently, the deployment camera usually employs the 4th Generation mobile communication technology (4G) for data transmission.

However, the fourth generation mobile communication technology often cannot meet the requirement of large data volume and high bandwidth data transmission, and when the fourth generation mobile communication technology is used for video transmission, the problem of video jamming or transmission delay is caused due to insufficient bandwidth.

SUMMERY OF THE UTILITY MODEL

The application provides a control camera system and a control camera, which can solve the problem that video jamming or transmission delay is caused due to insufficient bandwidth when a fourth generation mobile communication technology is used for data transmission. The application provides the following technical scheme:

in a first aspect, a deployment control camera system is provided, including:

an image acquisition unit;

the data analysis unit is in communication connection with the image acquisition unit;

the 5G module pattern transmission unit is in communication connection with the data analysis unit;

wherein the image acquisition unit acquires image data; the data analysis unit receives the image data and analyzes the image data; and the 5G module image transmission unit carries out data processing on the analyzed image data according to a 5G3GPP standard and sends the processed data according to the 5G3GPP standard.

Optionally, the 5G module graph transmission unit includes a 5G graph transmission module communicatively connected to the data analysis unit; and the 5G image transmission module receives the analyzed image data and performs data processing according to the 5G3GPP standard.

Optionally, the deployment control camera system further includes a data interface expansion unit communicatively connected to the 5G module image transmission unit and the data analysis unit, and the data interface expansion unit sends the analyzed image data to the 5G module image transmission unit.

Optionally, the deployment control camera system further comprises a wifi-6 wireless transmission unit in communication connection with the data analysis unit.

Optionally, the deployment control camera system further includes a bluetooth module communicatively connected to the data analysis unit, where the bluetooth module includes a data communication interface module; and the data communication interface module transmits the voice data collected by the Bluetooth module to the data analysis unit.

In a second aspect, there is provided a deployment camera comprising: the system comprises a shell, the deployment control camera system which is arranged in the shell and is provided with any one of the first aspect, and an antenna bracket which is arranged on the shell, wherein the 5G module image transmission unit comprises a 5G antenna which is arranged on the antenna bracket; the 5G antenna sends data processed by the 5G module image transmission unit; the image acquisition unit is a camera.

Optionally, the 5G antenna is laser engraved on the antenna support.

Optionally, the 5G antenna module has an antenna interface, and the 5G antenna includes a feeder line, and the feeder line is connected to the antenna interface of the 5G antenna module and the antenna bracket.

Optionally, the deployment control camera further includes a module heat dissipation module for dissipating heat of the 5G image transmission module, where the module heat dissipation module includes a bottom plate disposed on one side of the 5G image transmission module, a first heat dissipation member disposed between the bottom plate and the 5G image transmission module, and a second heat dissipation member; a gap is formed between the 5G image transmission module and the shell, and the second heat dissipation piece fills the gap.

Optionally, the deployment and control camera system further comprises a wifi-6 wireless transmission unit and a bluetooth module, the wifi-6 wireless transmission unit is in communication connection with the data analysis unit, the bluetooth module is in communication connection with the data analysis unit, the wifi-6 wireless transmission unit is arranged on the antenna support so as to enable the analyzed image data to be transmitted out through a wifi local area network, and the bluetooth module is arranged on the antenna support so as to enable the deployment and control camera to be in communication connection with other devices.

The beneficial effect of this application lies in: the utility model provides a control camera system, it passes through the 5G antenna transmission data in the 5G module picture passes the unit, can satisfy the data transmission demand of big data gauge height bandwidth, can not cause the problem that video card is pause or transmission delay because of the bandwidth is not enough, consequently, can solve the problem that video card is pause or transmission delay that causes because of the bandwidth is not enough in the data transmission process.

The foregoing description is only an overview of the technical solutions of the present application, and in order to make the technical solutions of the present application more clear and clear, and to implement the technical solutions according to the content of the description, the following detailed description is made with reference to the preferred embodiments of the present application and the accompanying drawings.

Drawings

Fig. 1 is a schematic structural diagram of a deployment control camera system according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a 5G graphics transmission module according to an embodiment of the present disclosure;

FIG. 3 is a schematic structural diagram of a deployment camera provided in an embodiment of the present application;

fig. 4A and 4B are schematic structural diagrams of an antenna support a41 and a support B41 according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of a module heat dissipation module according to an embodiment of the present application.

Detailed Description

The following detailed description of embodiments of the present application will be described in conjunction with the accompanying drawings and examples. The following examples are intended to illustrate the present application but are not intended to limit the scope of the present application.

Fig. 1 is a schematic structural diagram of an orchestration camera system according to an embodiment of the present application, where the orchestration camera system at least includes:

an image acquisition unit 101 for acquiring image data;

the data analysis unit 102 is in communication connection with the image acquisition unit;

the 5G module image transmission unit 104 is in communication connection with the data analysis unit 102;

wherein, the image acquisition unit 101 acquires image data; the data analysis unit 102 receives and analyzes the image data; the 5G module mapping unit 104 performs data processing on the analyzed image data according to the 5G3GPP standard, and sends the processed data according to the 5G3GPP standard.

The image acquisition unit 101 can acquire 4k high definition video data, can improve the definition of video data, and this image acquisition unit 101 can be the camera of camera, or be connected with the camera of camera to after the camera has caught image data, with the rearmounted module of the image acquisition of camera seizure.

The data analysis unit 102 has 4Tops operation performance, can be applied to the aspects of face recognition or license plate recognition and the like, and can improve the intelligent degree of the control camera.

In one embodiment, the 5G module mapping unit 104 may be directly connected to the data analysis unit in communication (not shown). In another embodiment, the 5G module mapping unit 104 is communicatively connected to the data analysis unit 102 through the data interface extension unit 103.

Further, referring to fig. 2, in an embodiment, the 5G module mapping unit 104 is communicatively connected to the data analysis unit 102 through the data interface expansion unit 103, the 5G module mapping unit 104 includes a 5G module 31 communicatively connected to the data analysis unit 102, and the 5G module 31 is configured to receive the analyzed image data and perform data processing according to the 5G3GPP standard. The 5G baseband module 31 includes a 5G baseband chip 311 and a power amplifier 312, where the 5G baseband chip 311 is configured to encode the data analyzed by the data analysis unit 102 into a baseband signal that can be transmitted through a 5G antenna; the power amplifier 312 is configured to amplify the audio/video signal in the baseband signal, so that the background command center 100 can obtain a clear and stable audio/video signal.

In this embodiment, the deployment control camera system may further include a wifi-6 wireless transmission unit 105, a data interface expansion unit 103, and a bluetooth module 107. Wherein:

the wifi-6 wireless transmission unit 105 is in communication connection with the data analysis unit 102 through the data interface expansion unit 103, and is used for sending the analyzed image data out through a wifi local area network. The wifi-6 wireless transmission unit 105 uses wifi-6 wireless local area network standard, and can be compatible with wifi technical standards such as 802.11.ac, 802.11.n and the like downwards, so that the wifi antenna has higher speed and larger bandwidth. The data interface expanding unit 103 is communicatively connected to the 5G module image transmission unit 104 and the data analysis unit 102, and is configured to send the image data analyzed by the data analysis unit 102 to the 5G module image transmission unit 104.

The bluetooth module 107 is communicatively connected to the data analysis unit 102, and the bluetooth module 107 includes a data communication interface module (not shown) for transmitting the voice data collected by the bluetooth module 107 to the data analysis unit 102.

The deployment control camera system provided by the embodiment can be built in the deployment control camera or installed in a rear shell of the deployment control camera. The working principle of the control camera system is as follows: the image acquisition unit 101 acquires image data and then sends the acquired image data to the data analysis unit 102; the data analysis unit 102 receives the image data sent by the image acquisition unit 101, and analyzes the image data to obtain analyzed image data; then, the analyzed image data is transmitted to a 5G module image transmission unit 104 and a wifi-6 wireless transmission unit 105 through a data interface expansion module 103; and finally, the 5G module image transmission unit 104 performs data processing on the analyzed image data according to the 5G3GPP standard, transmits the processed data to a background command center according to the 5G3GPP standard, and the wifi-6 wireless transmission unit 105 transmits the analyzed image data to other equipment through a wifi local area network. In addition, the bluetooth module 107 sends the collected voice data to the data analysis unit 102 through the data communication interface module, and sends the voice data and the image data collected by the image collection unit 101 to a background command center or other devices after being analyzed by the data analysis unit 102.

From the above, the 5G module image transmission unit 104 sends out the analyzed image data, so that the deployment control camera meets the data transmission requirement of large data volume and high bandwidth, and the problem of video jam or transmission delay caused by insufficient bandwidth when the fourth generation mobile communication technology is used for transmitting data can be solved.

Fig. 3 is a schematic structural diagram of a deployment control camera according to an embodiment of the present application, where the deployment control camera includes the deployment control camera system shown in fig. 1. Referring to fig. 1 to 4B, the deployment control camera includes a housing (not shown) and a support frame, and the support frame is disposed in the housing (not shown). The support frame comprises a U-shaped frame body 21, a support bottom 22 and an antenna bracket 41. The U-shaped frame body 21 comprises a first accommodating cavity 23 and a U-shaped groove 24, and the first accommodating cavity 23 is located on two sides of the U-shaped frame body 21 and used for mounting the antenna bracket 41; the U-shaped groove 24 is positioned in the middle of the U-shaped frame body 21 and used for supporting the image acquisition unit 101; the support base 22 includes a second receiving cavity 25 for receiving the 5G graphics module 31. The 5G module mapping unit 104 includes a 5G antenna disposed on the antenna bracket 41, and the 5G antenna transmits data processed by the 5G module mapping unit 104, specifically, the 5G antenna transmits data processed by the 5G mapping module 31.

The image pickup unit 101 is fixed inside the U-shaped groove 24 of the U-shaped frame body 21 using a rotatable shaft so that the image pickup unit 101 can make a vertical rotational movement with respect to the U-shaped frame body 21. In the present embodiment, the image capturing unit 101 is a camera.

The antenna bracket 41 is located in the first accommodating cavity 23 of the U-shaped frame body 21 and has a function of supporting the 5G antenna 42. The antenna bracket 41 is made of a polycarbonate composite material, and the polycarbonate composite material is a colorless and transparent amorphous thermoplastic material and has good dimensional stability and flame retardance, so that the antenna bracket 41 has the characteristics of high temperature resistance, difficulty in deformation and good electroplating property. In this embodiment, the number of the antenna holders 41 is set to 2, which are the antenna holder a41 and the antenna holder B41, respectively, and the antenna holder a41 and the antenna holder B41 are relatively distributed in the first accommodating cavity 23, specifically, referring to fig. 4A and 4B, the antenna holder a41 is installed with the 5G antenna 42 and the wifi antenna 44, and the antenna holder B41 is installed with the 5G antenna 42, the wifi antenna 44 and the bluetooth antenna 45.

Referring to fig. 4B, in the present embodiment, since the wifi-6 wireless transmission unit 105 and the bluetooth module 107 are provided, correspondingly, the wifi-6 wireless transmission unit 105 has the wifi antenna 44, the bluetooth module 107 has the bluetooth antenna 45, and both the wifi antenna 44 and the bluetooth antenna 45 are disposed on the antenna support 41. Specifically, 2 wifi antennas 44 in the wifi-6 wireless transmission unit 105 and 1 bluetooth antenna 45 in the bluetooth module 107 are installed on the antenna support 41, 2 wifi antennas 44 pass through the 2T2R technology, so that the wireless network transmission rate is faster, 1 bluetooth antenna 45 is used for connecting the deployment and control camera with other equipment in a communication manner, and all antennas are designed to be built-in antennas, so that the deployment and control camera is simple and attractive in appearance.

One end of the 5G antenna 42 disposed on the antenna bracket 41 is connected to the 5G mapping module 31 for transmitting the processed data. The 5G antenna 42 is laser engraved on the antenna support 41. In this embodiment, the 5G antenna 42 adopts a Laser Direct Structuring (LDS) direct laser etching on the antenna support 41, so that the structure of the antenna support 41 including the 5G antenna 42 is integrally formed, and the structure is overall simple and convenient to install. The number of the 5G antennas 42 is 4, the uplink and downlink speed is faster and the bandwidth is higher through a 4T4R technology, 2 5G antennas 42 are installed on each antenna support 41, and the 5G antennas 42 support all working frequency bands and European partial frequency bands of three operators in China, so that the application range of the deployment and control camera can be enlarged, and the full-network communication is realized.

The other end of the 5G antenna 42 is connected with the metal shell of the cloth control camera through the conductive foam, so that the anti-interference capability of the 5G antenna 42 in a low frequency band is stronger.

Referring to fig. 4A and 4B, the 5G antenna 42 further includes a feeder 43 for connecting the antenna interface of the 5G transmission module 31 to the antenna support 41. The feeder line 43 is made of a low-loss material, so that the loss of the baseband signal processed by the 5G diagram transmission module 31 in the feeder line 43 is smaller.

The 5G image transmission module 31 generates heat with large power consumption, and if the heat is not processed or is not processed well, the data transmission rate of the 5G image transmission unit 104 may be reduced, and even the operation of the 5G image transmission module 31 is unstable, and the problem of restart may occur. In order to perform heat dissipation processing on the 5G image transmission module 31, the deployment control camera further includes a module heat dissipation module 106, and the module heat dissipation module 106 performs heat conduction and heat dissipation processing on the upper surface and the lower surface of the 5G image transmission module 31, so that stable operation of the 5G image transmission module 31 in a high-temperature environment can be ensured.

As shown in fig. 5, the module heat dissipation module 106 includes a bottom plate 32 disposed at one side of the 5G graphics transmission module 31, a first heat dissipation member 33 disposed between the bottom plate 32 and the 5G graphics transmission module 31, and a second heat dissipation member. The 5G image transmission module 31 is inserted on the bottom plate 32 through an M.2 interface; the 5G fig. transmission module 31 has a first gap with the bottom plate 32, and the first heat dissipation member 33 is used for filling the first gap to transmit the heat of the 5G fig. transmission module 31 to the bottom plate; the bottom plate 32 is filled with the first heat dissipation element region and is treated with bright copper, so that the heat of the 5G heat conduction module 31 is easily conducted to the bottom plate 32. In the present embodiment, the first heat dissipation member 33 is a pad thermal pad. Of course, the first heat dissipation element 33 may also be other fillers with heat conduction function, and the embodiment does not limit the type of the first heat dissipation element 33. A second gap is formed between the 5G image transmission module 31 and the housing of the deployment and control camera, and the second heat dissipation member is used for filling the second gap so as to transmit the heat of the 5G image transmission module 31 to the housing. In the present embodiment, the second heat sink includes an aluminum plate 34, a heat pipe 35, and a heat conductive gasket 36, and specifically, the aluminum plate 34 and the heat conductive gasket 36 are stacked. Aluminum plate 34 and heat conduction pad 36 are stacked to be two sets, which are a first heat dissipation set and a second heat dissipation set respectively, wherein the first heat dissipation set is disposed on one side of 5G image transmission module 31, heat conduction pad 36 in the first heat dissipation set is disposed between aluminum plate 34 in the first heat dissipation set and 5G image transmission module 31, the first heat dissipation set and the second heat dissipation set are connected through heat pipe 35, and aluminum plate 34 in the first heat dissipation set and aluminum plate 34 in the second heat dissipation set are connected to two sides of heat pipe 35 respectively. Of course, in other embodiments, the second heat dissipation element may also include one or more of the aluminum plate 34, the heat pipe 35 and the heat conductive gasket 36, or other objects with heat conductive function, and the embodiment is not limited to the type of the second heat dissipation element.

It should be added that, the deployment control camera may further include: power supply, control components, etc., which are not listed in this embodiment.

According to the structure, the 5G antenna in the 5G module image transmission unit is used for transmitting data, so that the deployment and control camera meets the data transmission requirement of large data volume and high bandwidth, and the problem of video blockage or transmission delay caused by insufficient bandwidth when the fourth generation mobile communication technology is used for transmitting data can be solved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An cloth control camera system, comprising:

an image acquisition unit;

the data analysis unit is in communication connection with the image acquisition unit;

the 5G module pattern transmission unit is in communication connection with the data analysis unit;

wherein the image acquisition unit acquires image data; the data analysis unit receives the image data and analyzes the image data; and the 5G module image transmission unit carries out data processing on the analyzed image data according to a 5G3GPP standard and sends the processed data according to the 5G3GPP standard.

2. The cloth control camera system of claim 1, wherein the 5G module image transmission unit comprises a 5G image transmission module communicatively connected to the data analysis unit; and the 5G image transmission module receives the analyzed image data and performs data processing according to the 5G3GPP standard.

3. The cloth control camera system according to claim 1, further comprising a data interface expansion unit that communicatively connects the 5G module image transmission unit and the data analysis unit, wherein the data interface expansion unit sends the analyzed image data to the 5G module image transmission unit.

4. The deployment camera system of claim 1, further comprising a wifi-6 wireless transmission unit communicatively coupled to the data analysis unit.

5. The cloth control camera system of claim 1, further comprising a bluetooth module communicatively coupled to the data analysis unit, the bluetooth module including a data communication interface module; and the data communication interface module transmits the voice data collected by the Bluetooth module to the data analysis unit.

6. An cloth control camera, comprising: the control camera system as claimed in any one of claims 1 to 3 and an antenna support arranged on the shell, wherein the control camera system is arranged in the shell, and the 5G module mapping unit comprises a 5G antenna arranged on the antenna support; the 5G antenna sends data processed by the 5G module image transmission unit; the image acquisition unit is a camera.

7. The deployment controlled camera of claim 6, wherein the 5G antenna is radium engraved on the antenna mount.

8. The deployment camera of claim 7, wherein the 5G module mapping unit comprises a 5G mapping module, the 5G mapping module has an antenna interface, and the 5G antenna comprises a feeder line, and the feeder line connects the antenna interface of the 5G mapping module and the antenna mount.

9. The deployment camera of claim 8, further comprising a module heat dissipation module that dissipates heat from the 5G map transmission module, the module heat dissipation module comprising a base plate disposed on one side of the 5G map transmission module, a first heat dissipation member disposed between the base plate and the 5G map transmission module, and a second heat dissipation member; a gap is formed between the 5G image transmission module and the shell, and the second heat dissipation piece fills the gap.

10. The cloth control camera system of claim 6, further comprising a wifi-6 wireless transmission unit and a bluetooth module, wherein the wifi-6 wireless transmission unit is in communication connection with the data analysis unit, the bluetooth module is in communication connection with the data analysis unit, the wifi-6 wireless transmission unit comprises a wifi antenna arranged on the antenna bracket to send the analyzed image data out through a wifi local area network, and the bluetooth module comprises a bluetooth antenna arranged on the antenna bracket.

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