阅读说明：本技术 一种基于5g通讯及图像识别处理的水稻种子计数方法 (Rice seed counting method based on 5G communication and image recognition processing ) 是由 黄关青 周飞 于 2021-08-11 设计创作，主要内容包括：本发明提供一种基于5G通讯及图像识别处理的水稻种子计数方法,包括以下步骤：S1:安装种子计数装置,种子计数装置包括振动摊平机构、图像采集模块、图像分析计数模块、5G通讯模块及显示器；S2：取样,并将待测样品放入振动摊平机构的托盘内,使待测样品摊铺均匀,确保没有重叠、粘连；S3：使用图像采集模块对托盘内的待测样品进行拍照,并获得图片；S4：将图片通过5G通讯模块传输至图像分析计数模块进行图像分析处理生成计数结果；S5：通过5G通讯模块将计数结果发送至显示器显示计数结果。本发明具有准确度高、检测效率高、结构简单、成本低、易于操作等优点,方便实际应用,适宜广泛地推广。(The invention provides a rice seed counting method based on 5G communication and image recognition processing, which comprises the following steps: s1, installing a seed counting device, wherein the seed counting device comprises a vibration flattening mechanism, an image acquisition module, an image analysis counting module, a 5G communication module and a display; s2: sampling, and putting a sample to be tested into a tray of a vibration flattening mechanism to uniformly spread the sample to be tested and ensure that the sample to be tested is not overlapped and adhered; s3: photographing a sample to be detected in the tray by using an image acquisition module, and obtaining a picture; s4: the pictures are transmitted to an image analysis counting module through a 5G communication module to be subjected to image analysis processing to generate counting results; s5: and sending the counting result to a display through the 5G communication module to display the counting result. The invention has the advantages of high accuracy, high detection efficiency, simple structure, low cost, easy operation and the like, is convenient for practical application and is suitable for wide popularization.)

1. A rice seed counting method based on 5G communication and image recognition processing is characterized by comprising the following steps:

s1, installing a seed counting device: the seed counting device comprises a vibration flattening mechanism, an image acquisition module, an image analysis counting module and a control box with a display; fixedly connecting the vibration flattening mechanism to the top end of the control box; the image acquisition module comprises an adjustable bracket and a camera, the image acquisition module is arranged on the control box through the adjustable bracket, and the camera of the image acquisition module is positioned above the vibration flattening mechanism;

the vibration flattening mechanism comprises a tray, a sliding support, a rotating shaft, an eccentric wheel, a handle and a guide rod, the guide rod is vertically arranged at the top end of the control box, the tray is of a box-packed structure with an open top, the bottom of the tray is fixedly connected with the sliding support, the sliding support is sleeved outside the guide rod and slides along the axis direction of the guide rod, and springs are sleeved on a rod section of the guide rod between the tray and the sliding support and outside a rod section of the guide rod between the sliding support and the control box; the handle is rotatably connected with the sliding support through the rotating shaft, the rotating shaft is horizontally arranged and is rotatably connected with the sliding support, and the eccentric wheel is fixedly sleeved on the outer side of the rotating shaft;

the image acquisition module is used for acquiring pictures of rice seed samples, and is in communication connection with the image analysis counting module through the 5G communication module;

the image analysis counting module is used for carrying out image analysis and calculation on the pictures acquired by the image acquisition module and obtaining a counting result, and the image analysis counting module is respectively in communication connection with the image acquisition module and a display of the control box through the 5G communication module;

the display is used for receiving and displaying the counting result analyzed by the image analysis counting module;

s2: sampling, putting a sample to be tested into a tray of the vibration flattening mechanism, and uniformly spreading the sample to be tested through the vibration flattening mechanism to ensure that the sample to be tested is not overlapped and adhered;

s3: adjusting the position of the image acquisition module through the adjustable support until a lens of a camera in the image acquisition module is positioned right above a tray of the vibration flattening mechanism, adjusting the optimal height of the camera to ensure that a shot picture is clear and contains all samples to be detected in the tray, and shooting the samples to be detected which are paved smoothly in the tray by using the image acquisition module to obtain the picture;

s4: the pictures obtained in the step S3 are transmitted to the image analysis and counting module through the 5G communication module, and the image analysis and counting module is configured to receive the pictures and perform image analysis processing on the input pictures to generate counting results;

s5: and the image analysis counting module sends the counting result of the step S4 to a display through the 5G communication module, and the display receives and displays the counting result.

2. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the step S2 of spreading the sample to be tested uniformly by the vibration flattening mechanism comprises the following steps: the handle is rotated to drive the rotating shaft and the eccentric wheel to synchronously rotate, so that the sliding support is driven to slide up and down along the axial direction of the guide rod under the action of the eccentric wheel and the spring, and the sample to be detected in the flat tray is vibrated and paved.

3. The method of claim 2, wherein the bottom end of the adjustable bracket is fixedly connected to the top end of the control box, the top end of the adjustable bracket is fixedly connected to the camera, the camera is arranged right above the tray, and the lens of the camera faces downward.

4. The method for counting rice seeds according to claim 1, wherein the method comprises the steps of performing a 5G communication and image recognition process, it is characterized in that the adjustable bracket comprises a support, a first bracket, a second bracket and a third bracket, a plurality of connecting holes are arranged along the length direction of the first bracket, the second bracket and the third bracket, the connecting holes are arranged at equal intervals, the support is fixedly connected with the bottom end of the first bracket through a fastening bolt, the other end of the first bracket is fixedly connected with the second bracket through the fastening bolt, the second bracket is fixedly connected with one end of the third bracket through the fastening bolt, the other end of the third bracket is fixedly connected with the camera through the fastening bolt, the second support adjusts the relative position with the first support and the third support by changing the connecting holes between the second support and the first support and between the second support and the third support.

5. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the number of the eccentric wheels is 2, two eccentric wheels are arranged along the axial direction of the rotating shaft, and two eccentric wheels are respectively located at two sides of the sliding support.

6. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the number of the guide bars is 2, and two guide bars are arranged along the length direction of the sliding support.

7. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the seed counting device further comprises a memory for storing pictures of external devices.

8. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the display further comprises an indicator light unit, the indicator light unit comprises: the power indicator light is used for indicating whether the power is connected or not; the operation indicator light is used for indicating whether the equipment is operated or not; and the 5G communication indicator lamp is used for indicating whether the 5G communication module runs or not.

9. The rice seed counting method based on 5G communication and image recognition processing as claimed in claim 1, wherein the display further comprises a plurality of operation buttons for controlling the seed counting device, the operation buttons comprise: the starting button is used for starting the seed counting device; a stop button for stopping the seed counting device; the reset button is used for resetting the seed counting device; and the emergency stop button is used for emergency stop of the seed counting device.

Technical Field

The invention relates to the technical field of seed counting, in particular to a rice seed counting method based on 5G communication and image recognition processing.

Background

In the breeding of fine breed and field test, the seed count is needed by agricultural scientific research institute and related units. The traditional seed counting method mainly adopts manual counting, has the advantages of high real-time performance, low tool requirement and the like, has the defects of time and labor waste, easy error in the counting process, low counting precision and low accuracy; in addition, counting is carried out by adopting a counting plate, and when counting is carried out by adopting the counting plate, the seeds and the holes are extruded, the seeds are damaged, the germination rate of the seeds is influenced, and the major defect exists; and a few electromechanical integrated particle counting devices can replace manual counting, but the problems of large error, complex manufacturing, high price and the like exist, and the wide popularization and application are difficult.

Disclosure of Invention

Aiming at the problems, the invention aims to provide a rice seed counting method based on 5G communication and image recognition processing, which can overcome the problems of low efficiency and low accuracy of traditional manual counting, seed damage caused by counting by a counting plate, large error, complex manufacture, high price and the like of electromechanical integrated counting equipment, and better applies the 5G communication and image recognition processing technology to the field of seed counting, and has the advantages of quick and accurate counting, simple structure, simple and convenient operation and suitability for various crop seeds.

In order to achieve the purpose, the technical means adopted by the invention are as follows:

a rice seed counting method based on 5G communication and image recognition processing comprises the following steps:

s1, installing a seed counting device, wherein the seed counting device comprises a vibration flattening mechanism, an image acquisition module, an image analysis counting module and a control box with a display; fixedly connecting the vibration flattening mechanism to the top end of the control box; the image acquisition module comprises an adjustable bracket and a camera, the image acquisition module is arranged on the control box through the adjustable bracket, and the camera of the image acquisition module is positioned above the vibration flattening mechanism;

the vibration flattening mechanism comprises a tray, a sliding support, a rotating shaft, an eccentric wheel, a handle and a guide rod, the guide rod is vertically arranged at the top end of the control box, the tray is of a box-packed structure with an open top, the bottom of the tray is fixedly connected with the sliding support, the sliding support is sleeved outside the guide rod and slides along the axis direction of the guide rod, and springs are sleeved on a rod section of the guide rod between the tray and the sliding support and outside a rod section of the guide rod between the sliding support and the control box; the handle is rotatably connected with the sliding support through a rotating shaft, the rotating shaft is horizontally arranged and is rotatably connected with the sliding support, and the eccentric wheel is fixedly sleeved on the outer side of the rotating shaft; the image acquisition module is used for acquiring pictures of rice seed samples and is in communication connection with the image analysis counting module through the 5G communication module;

the image analysis counting module is used for carrying out image analysis and calculation on the pictures acquired by the image acquisition module and obtaining a counting result, and the image analysis counting module is respectively in communication connection with the image acquisition module and a display of the control box through a 5G communication module;

the display is used for receiving and displaying the counting result analyzed by the image analysis counting module;

s2: sampling, putting a sample to be tested into a tray of a vibration flattening mechanism, and uniformly spreading the sample to be tested through the vibration flattening mechanism to ensure that the sample to be tested is not overlapped and adhered;

s3: the position of the image acquisition module is adjusted through the adjustable support until a lens of a camera in the image acquisition module is positioned right above a tray of the vibration flattening mechanism, the optimal height of the camera is adjusted to ensure that a shot picture is clear and contains all samples to be detected in the tray, the image acquisition module is used for shooting the samples to be detected which are paved flatly in the tray, and the pictures are obtained;

s4: transmitting the pictures obtained in the step S2 to an image analysis counting module through a 5G communication module, wherein the image analysis counting module is used for receiving the pictures and carrying out image analysis processing on the input pictures to generate counting results;

s5: the image analysis counting module sends the counting result of the step S3 to a display through a 5G communication module, and the display receives and displays the counting result;

further, the step S2 of uniformly spreading the sample to be measured by the vibration flattening mechanism includes: the rotating handle drives the rotating shaft and the eccentric wheel to rotate synchronously, so that the sliding support is driven to slide up and down along the axial direction of the guide rod under the action of the eccentric wheel and the spring, and the sample to be measured in the tray is vibrated and spread smoothly.

Furthermore, the bottom end of the adjustable support is fixedly connected to the top end of the control box, the top end of the adjustable support is fixedly connected with the camera, the camera is arranged right above the tray, and a lens of the camera faces downwards.

Further, adjustable support includes the support, the first support, second support and third support, along the first support, a plurality of connecting holes are seted up to second support and third support length direction, a plurality of connecting holes are equidistant to be arranged, fastening bolt fixed connection is passed through with the bottom of first support to the support, fastening bolt and second support fixed connection are passed through to the other end of first support, the one end of fastening bolt fixed connection third support is passed through to the second support, fastening bolt fixed connection camera is passed through to the other end of third support, the relative position of second support through change and first support and third support between connecting hole adjustment and the third support.

Furthermore, the number of the eccentric wheels is 2, the two eccentric wheels are arranged along the axis direction of the rotating shaft, and the two eccentric wheels are respectively positioned on two sides of the sliding support.

Furthermore, the number of the guide rods is 2, and the two guide rods are arranged along the length direction of the sliding support.

Further, the seed counting device further comprises a memory, and the memory is used for storing pictures of the external device.

Further, still include the pilot lamp unit on the display, the pilot lamp unit includes: the power indicator light is used for indicating whether the power is connected or not; the operation indicator light is used for indicating whether the equipment is operated or not; and the 5G communication indicator lamp is used for indicating whether the 5G communication module runs or not.

Further, the display also comprises a plurality of operation buttons for controlling the seed counting device, and the operation buttons comprise: the starting button is used for starting the seed counting device; a stop button for stopping the seed counting device; the reset button is used for resetting the seed counting device; and the emergency stop button is used for emergency stop of the seed counting device.

The invention has the beneficial effects that:

the rice seed counting method based on 5G communication and image recognition processing realizes rapid counting of seed crops, a vibration flattening mechanism in a seed counting device uniformly flattens the seed crops to be detected in a vibration mode without overlapping and adhesion phenomena, meanwhile, a 5G communication technology and an image recognition processing technology are introduced into the seed counting method, a 5G communication module is used for real-time and remote data transmission, and an image analysis counting module analyzes and processes picture information and calculates to obtain a counting result.

Drawings

FIG. 1 is a schematic flow chart of a rice seed counting method based on 5G communication and image recognition processing according to the present invention;

FIG. 2 is a block diagram of the image acquisition and processing of the present invention;

FIG. 3 is a schematic perspective view of a seed counting device according to the present invention;

FIG. 4 is a left side view of the seed counting apparatus of the present invention;

FIG. 5 is a front view of the seed counting apparatus of the present invention;

fig. 6 is a perspective view of the shoe of the present invention.

Description of reference numerals:

1: a vibration flattening mechanism; 11: a tray; 12: a support bar; 13: a sliding support; 131: perforating; 132: through holes are formed; 14: a rotating shaft; 15: an eccentric wheel; 16: a handle; 17: a base; 18: a spring; 19 a guide rod; 2: an image acquisition module; 21: a support; 22: a first bracket; 23: a second bracket; 24: a third support; 25: a camera; 26: fastening a bolt; 3: a control box; 30: a display; 31: a display screen; 32: an operation button; 33: a power indicator light; 34: an operation indicator light; 35: 5G communication indicator light; 4: an image analysis counting module; 5: 5G communication module; 6: a memory.

Detailed Description

In order to more clearly explain the technical contents of the present invention, the following detailed description is given with reference to the accompanying drawings and specific embodiments. As shown in fig. 1 to 6, a rice seed counting method based on 5G communication and image recognition processing includes the following steps:

s1, installing a seed counting device, wherein the seed counting device comprises a vibration flattening mechanism 1, an image acquisition module 2, an image analysis counting module 4, a 5G communication module 5 and a control box 3 with a display 30, and fixedly connecting the vibration flattening mechanism 1 to the top end of the control box 3; the image acquisition module 2 comprises an adjustable bracket and a camera 25, the camera 25 in the invention can use a camera sold on the market, and a special camera can also be installed, and the embodiment of the invention does not specifically limit the brand, model and parameter of the camera. The image acquisition module 2 is arranged on the control box 3 through an adjustable bracket, and the camera 25 of the image acquisition module 2 is positioned above the vibration flattening mechanism 1. Control box 3 is used for control operation seed counting assembly, and image analysis count module 4 and 5G communication module 5 set up inside control box 3, and 3 top fixed connection vibration shakeouts mechanism 1 and image acquisition module 2 of control box, vibration shakeouts mechanism 1 and image acquisition module 2 and arranges along 3 length direction of control box, and the front side of control box 3 is equipped with display 30.

The vibration flattening mechanism 1 comprises a tray 11, a sliding support 13, a rotating shaft 14, an eccentric wheel 15, a handle 16 and a guide rod 19, wherein the guide rod 19 is vertically arranged at the top end of the control box 3, the tray 11 is of a box-packed structure with an open top, the bottom of the tray 11 is fixedly connected with the sliding support 13, the sliding support 13 is sleeved outside the guide rod 19, the tray is arranged on the tray, the sliding support 13 is arranged on the tray, the guide rod 19 is arranged on the tray, the sliding support 13 is arranged on the tray, the spring 18 is sleeved on the guide rod 19, the spring 18 is sleeved on the outer side of the guide rod 19, the sliding support 13 is arranged on the control box 3, the spring 18 is coaxially sleeved on one end of a rotating shaft 14 on the outer side of the guide rod 19, the handle 16 is fixedly connected with the sliding support 13 through the rotating shaft 14, the rotating shaft 14 penetrates through the rotating shaft 14 in the width direction, the rotating shaft 14 is horizontally arranged, the rotating shaft 14 is rotatably connected with the sliding support 13, and the eccentric wheel 15 is fixedly sleeved on the outer side of the rotating shaft 14; the image acquisition module 2 is used for acquiring pictures of rice seed samples, and the image acquisition module 2 is in communication connection with the image analysis counting module 4 through a 5G communication module 5; the image analysis counting module 4 is used for carrying out image analysis and calculation on the pictures acquired by the image acquisition module 2 and obtaining a counting result, and the image analysis counting module 4 is respectively in communication connection with the image acquisition module 2 and the display 30 of the control box 3 through the 5G communication module 5; the display 30 is used for receiving and displaying the counting result analyzed by the image analysis counting module 4, and the display 30 is in communication connection with the image analysis counting module 4 through the 5G communication module 5; the 5G communication module 5 is used for connecting the image acquisition module 2, the image analysis counting module 4 and the display 30 and performing 5G communication. The 5G communication module adopts NSA and SA dual-mode 5G networking and can provide low-delay communication service.

S2: sampling, putting a sample to be tested into a tray 11 of a vibration flattening mechanism 1, uniformly spreading the sample to be tested through the vibration flattening mechanism 1, wherein the vibration flattening mechanism 1 comprises the tray 11, a sliding support 13, a rotating shaft 14, an eccentric wheel 15, a handle 16 and a guide rod 19. The rotating handle 16 drives the rotating shaft 14 and the eccentric wheel 15 to rotate synchronously, so that the sliding support 13 is driven to slide up and down along the axial direction of the guide rod 19 under the action of the eccentric wheel 15 and the spring 18, the sliding support 13 drives the tray 11 to slide up and down along the axial line of the guide rod 19, the eccentric wheel 15 rotates to generate vibration, a sample to be tested in the tray 11 is vibrated up and down, the sample to be tested is spread uniformly through the vibration flattening mechanism 1, and no overlapping and adhesion are ensured;

s3: the position of the image acquisition module 2 is adjusted through an adjustable bracket until a lens of a camera 25 in the image acquisition module 2 is positioned right above a tray 11 of the vibration flattening mechanism 1, the optimal height of the camera 25 is adjusted to ensure that a shot picture is clear and all samples to be detected in the tray 11 are contained, the positions of a second bracket 23 and a third bracket 24 are adjusted through adjusting the adjusting bracket in the image acquisition module 2, the camera 25 is adjusted to a proper position to ensure that the shot picture is clear, all samples to be detected in the tray 11 are shown in the picture, the boundary of the samples to be detected in the picture is clearly divided and visible, preparation is made for subsequent picture analysis, the samples to be detected are fixedly connected through a fastening bolt 26, and the camera 25 is used for shooting the samples to be detected which are paved and flattened in the tray 11 to obtain the picture;

s4: the image obtained in the step S3 is transmitted to the image analysis counting module 4 through the 5G communication module 5, the image analysis counting module 4 is configured to receive the image, and perform image analysis processing on the input image to generate a counting result, and the algorithm used by the image analysis counting module 4 in the present invention may include any one of a gradient method, a Roberts gradient method, a Sobel algorithm, a Laplace algorithm, a Canny algorithm, and the like;

s5: the image analyzing and counting module 4 sends the counting result of step S3 to the display 30 through the 5G communication module 5, and the display 30 receives the counting result and displays the counting result through the display screen 31.

The vibration flattening mechanism 1 is used for vibrating and flattening a sample to be tested placed in the tray 11, so that the sample to be tested is flattened and uniform without overlapping and adhesion, and convenience is brought to subsequent picture analysis and counting. The tray 11 is a box structure with an open top, and the shape of the tray 11 can be, but is not limited to, circular. The bottom of the tray 11 is fixedly connected with a sliding support 13, a support rod 12 is connected between the tray 11 and the sliding support 13, and the two support rods 12 are arranged on the central line of the width direction of the sliding support 13, arranged along the length direction of the sliding support 13 and symmetrically arranged about the central line of the sliding support 13.

The sliding support 13 is a rectangular parallelepiped structure, the sliding support 13 is provided with two through holes 131 penetrating through the guide rod 19 along the height direction, the through holes 131 penetrate through the sliding support 13, and the through holes 131 are located on the center line of the sliding support 13 in the width direction and are arranged along the length direction of the sliding support 13 and are symmetrical about the center line of the sliding support 13. The center of the sliding support 13 in the length direction is provided with a through hole 132 for passing through the rotating shaft 14, and the through hole 132 extends along the width direction of the sliding support 13 and passes through the sliding support 13. The middle part of the upper surface of the sliding support 13 is provided with a convex part for enhancing the strength of the opening part of the through hole 132. The inner diameter of the through hole 131 is equal to or larger than the outer diameter of the guide rod 19, and the inner diameter of the through hole 132 is equal to or larger than the outer diameter of the rotating shaft 14.

The guide rod 19 is vertically arranged below the tray 11, and the sliding support 13 is sleeved outside the guide rod 19 and slides up and down along the axial direction of the guide rod 19. The number of the guide rods 19 is 2, two guide rods 19 are arranged along the length direction of the sliding support 13, and the positions of the guide rods 19 are matched with the positions of the through holes 131 of the sliding support 13. The top end of the guide rod 19 is provided with a stopping part for limiting and stopping the spring 18, and the diameter of the stopping part is larger than the outer diameter of the spring 18. The bottom end of the guide rod 19 is fixedly connected with the base 17, and the bottom end of the base 17 is fixedly connected with the top end of the control box 3.

The spring 18 is coaxially sleeved outside the guide rod 19, and the spring 18 is respectively arranged on the upper side and the lower side of the sliding support 13, namely, the spring 18 is sleeved on the rod section of the guide rod 19 between the tray 11 and the sliding support 13 and on the rod section of the guide rod 19 between the sliding support 13 and the control box 3. The number of the springs 18 is 4, and the 4 springs 18 are coaxially sleeved outside the guide rod 19, wherein two springs 18 are arranged above the sliding support 13, the other two springs 18 are arranged below the sliding support 13, and the springs 18 are respectively abutted against the upper surface and the lower surface of the sliding support 13.

The sliding support 13 penetrates the rotating shaft 14 in the width direction, the rotating shaft 14 penetrates the through hole 132 of the sliding support 13, and the rotating shaft 14 is horizontally arranged and rotatably connected with the sliding support 13. The outer side of the rotating shaft 14 is fixedly connected with eccentric wheels 15, the number of the eccentric wheels 15 is 2, two eccentric wheels 15 are arranged along the axial direction of the rotating shaft 14, and the two eccentric wheels 15 are respectively positioned at two sides of the sliding support 13. One end of the rotating shaft 14 is fixedly connected with a handle 16, the rotating handle 16 is used for driving the rotating shaft 14 and the eccentric wheel 15 to rotate, and driving the sliding support 13 to slide up and down along the axis of the guide rod 19, and the sliding support 13 drives the seeds in the tray 11 to vibrate up and down, so that the seeds in the tray 11 are flattened evenly.

The bottom end of the adjustable support is fixedly connected to the top end of the control box 3, the top end of the adjustable support is fixedly connected with the camera 25, the camera 25 is arranged right above the tray 11, the lens of the camera 25 faces downwards, and the visual field range of the camera 25 covers the area, on the tray 11, of the object to be measured. The adjustable support comprises a support 21, a first support 22, a second support 23 and a third support 24, a plurality of connecting holes are formed in the length directions of the first support 22, the second support 22 and the third support 24 and are arranged at equal intervals, the support 21 is fixedly connected with the bottom end of the first support 22 through a fastening bolt 26, the other end of the first support 22 is fixedly connected with the second support 23 through the fastening bolt 26, the second support 23 is fixedly connected with one end of the third support 24 through the fastening bolt 26, the other end of the third support 24 is fixedly connected with a camera 25 through the fastening bolt 26, and the second support 23 is adjusted relative to the first support 22 and the third support 24 through changing the connecting holes between the second support and the first support 22 and the third support 24. The same fastening bolt 26 is adopted for connecting the support 21, the first support 22, the second support 23 and the third support 24, so that the universality and convenience of use are improved. The first support 22, the second support 23 and the third support 24 are all provided with connecting holes at equal intervals along the axis direction, and the relative position relation of the first support 22 and the second support 23 is adjusted by changing the positions of the corresponding connecting holes between the first support 22 and the second support 23 and using the fastening bolts 26 to penetrate through the corresponding connecting holes, so that the position of the second support 23 is adjustable. Similarly, the position of the third bracket 24 can be adjusted by changing the position of the corresponding connecting hole between the second bracket 23 and the third bracket 24 and using the fastening bolt 26 to pass through the corresponding connecting hole, so as to adjust the relative position relationship between the second bracket 23 and the third bracket 24. By adjusting the positions of the second and third supports 23, 24, the position of the camera 25 can be adjusted to an optimal position for taking a picture of higher quality.

The seed counting device further comprises a memory 6, the memory 6 is used for storing pictures of external equipment, and the memory 6 is arranged inside the control box 3. The memory of the invention can be an EMMC, which can provide a standard interface and manage a flash memory and is provided with a flash memory device, thereby having the advantages of high speed, upgradable performance, small size and low cost. The memory 6 sends the pictures input by the external device to the input end of the image analysis counting module 4 through the 5G communication module 5, and after the image analysis counting module 4 analyzes and processes the input pictures, the counting results are transmitted to the display 30 through the 5G communication module 5 and are displayed. In addition, the counting result is also transmitted to external equipment through the 5G communication module 5, so that the counting result can be monitored in real time conveniently.

The 5G communication module 5 is used for transmitting pictures and data among the image acquisition module 2, the image analysis counting module 4 and the display 30, meanwhile, the 5G communication module 5 is also capable of receiving pictures of external equipment, and counting results can be sent to other external equipment, so that real-time monitoring of counting results is achieved.

The display 30 is provided with a display screen 31, an indicator light unit and an operation button 32, and the display screen 31 is used for displaying a counting result; the indicator light unit includes: a power indicator lamp 33 for indicating whether the power is connected or not; an operation indicator lamp 34 for indicating whether the apparatus is operating or not; and the 5G communication indicator lamp 35 is used for indicating whether the 5G communication module 5 runs or not. There are a plurality of operation buttons 32, the operation buttons 32 are used for operating the seed counting device, and the operation buttons 32 include start, stop, reset and emergency stop. The starting button is used for starting the seed counting device; a stop button for stopping the seed counting device; the reset button is used for resetting the seed counting device; and the emergency stop button is used for emergency stop of the seed counting device.

The rice seed counting method based on 5G communication and image recognition processing of the invention uses a seed counting device, when counting rice seeds, firstly, the seeds to be measured are placed in the tray 11 of the vibration flattening mechanism 1, the operator rotates the handle 16, the handle 16 rotates the rotating shaft 14 and the eccentric wheel 15, the eccentric wheel 15 rotates to generate unbalanced centrifugal force and drive the sliding support 13 to move up and down along the guide rod 19, when the end of the eccentric 15, which is far from the rotating shaft 14, is turned upwards, the centrifugal force drives the sliding support 13 to slide upwards, when the end of the eccentric 15, which is far away from the rotating shaft 14, is turned downwards, gravity and centrifugal force together drive the sliding support 13 to slide downwards, thus, the sliding support 13 drives the sample to be tested in the tray 11 to vibrate up and down, so that the sample to be tested in the tray 11 is spread evenly and smoothly until no overlapping or adhesion phenomenon exists; secondly, a camera 25 in the picture acquisition module photographs a sample to be detected in the tray 11 to obtain a picture, and the picture is sent to the image analysis counting module 4 through the 5G communication module 5; the image analysis counting module 4 analyzes and processes the pictures, calculates a counting result and sends the counting result to the display 30 through the 5G communication module 5; the display 30 receives the counting result and displays it through the display screen 31.

The rice seed counting method based on 5G communication and image recognition processing realizes rapid counting of seed crops, a vibration flattening mechanism in a seed counting device uniformly flattens the seed crops to be detected in a vibration mode without overlapping and adhesion phenomena, meanwhile, a 5G communication technology and an image recognition processing technology are introduced into the seed counting method, a 5G communication module is used for real-time and remote data transmission, and an image analysis counting module analyzes and processes picture information and calculates to obtain a counting result.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention; various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.