CN209387532U - Soil image acquisition equipment and soil water-containing amount detection systems - Google Patents
Soil image acquisition equipment and soil water-containing amount detection systems Download PDFInfo
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- CN209387532U CN209387532U CN201821656800.9U CN201821656800U CN209387532U CN 209387532 U CN209387532 U CN 209387532U CN 201821656800 U CN201821656800 U CN 201821656800U CN 209387532 U CN209387532 U CN 209387532U
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Abstract
The utility model discloses a kind of soil image acquisition equipments and soil water-containing amount detection systems of measurement testing field, obtaining equipment includes magazine, built-in light source, transparent sleeve, industrial camera, prism and power supply, industrial camera is installed on transparent sleeve inner upper, built-in light source is set to transparent sleeve lower inside, prism is installed on above built-in light source, power supply is that built-in light source and industrial camera are powered, and magazine is set at the top of transparent sleeve.Computer connects and composes soil water-containing amount detection systems by cable network or wireless network and soil image acquisition equipment.The utility model can analyze in time the moisture content of soil by the gray value of soil image, have compared with high-timeliness and accuracy.
Description
Technical field
The utility model relates to measure testing field, a kind of soil image acquisition equipment and soil water-containing are specifically disclosed
Amount detection systems.
Background technique
With increasingly sharpening for the contradiction of supply and demand for the water resource, Water Saving Agriculture Development is all attached great importance in countries in the world.Agricultural is used
Water accounts for about the 70% of China's water total amount, and therein 90% or more is used for irrigation water.In agricultural production, soil moisture is to make
The most important factor of object growth, soil water content height will affect crop to moisture and Nutrient Absorption, different crops
Different to soil moisture demand during the growth process, crop growing way under suitable Soil Moisture is preferable.It can be seen that
Soil water content plays very important effect to the growth of crop
Using there are mainly two types of commonplace in the mode being measured at present to soil moisture, one is acquisition soil
After carry out drying mensuration, another kind is using electric resistance sensor soil moisture instrument mensuration.Oven drying method measures soil moisture essence
The high error of exactness is small, but measures heavy workload and cannot obtain data result in time, while can also destroy original-state soil structure.Electricity
It is easy to hinder the measurement of sensor soil moisture instrument, can obtain soil moisture data in time, but measurement result vulnerable to soil dissolved salt and
The influence of temperature measures precision decline when soil moisture content is lower.Main method has NEUTRON METHOD, Ground Penetrating Radar method
(GPR), frequency domain reflectometer method (TDR), time-domain reflectomer method (FDR) and Remote-sensing method, these technologies have detection efficient
Height, the advantages such as anti-interference factor is strong, but these determination techniques are still in continuous development in determining soil moisture and improve the stage,
And since the expensive and complicated for operation feature of instrument and equipment is less in practical applications.Numerous determining soil moisture sides
Its principle majority is to reflect moisture content value using measurement soil moisture medium in method, rarely has and determines soil according to soil color
The research of earth moisture is reported.
Utility model content
The utility model aim is providing a kind of soil image acquisition equipment and soil water-containing amount detection systems, to solve
Soil moisture content detection accuracy existing in the prior art is low, detects the technological deficiency of timeliness difference.
To achieve the above object, the utility model provides a kind of soil image acquisition equipment, including magazine, built in light
Source, transparent sleeve, industrial camera, prism and power supply, industrial camera are installed on transparent sleeve inner upper to shoot soil
Image, built-in light source are set to transparent sleeve lower inside and provide light source for industrial camera shooting, and prism is installed on built in light
The reflectivity of built-in light source is adjusted above source, power supply is that built-in light source and industrial camera are powered, and magazine is set to transparent sleeve
Top is to store and transmit the image that industrial camera obtains.
Preferably, magazine includes box body and GPRS image capture module, and GPRS image capture module is set to tray interior
And data exchange is carried out to obtain the soil image of industrial camera acquisition and pass through GPRS network for soil image with industrial camera
It is transmitted wirelessly.
Preferably, transparent sleeve is organic glass sleeve.
Preferably, power supply is battery.
Preferably, soil image acquisition equipment further includes solar panels, and solar panels are set to outside magazine and and electric power storage
Pond connection provides electric energy to charge the battery.
Above-mentioned soil image acquisition equipment is relied on, the utility model additionally provides a kind of soil water-containing amount detection systems,
Soil image acquisition equipment including computer and as described in any of the above-described, computer pass through cable network or wireless network
It is connect with soil image acquisition equipment to receive the image of soil image acquisition equipment acquisition and according to image analysis soil water-containing
Rate.
The utility model has the following beneficial effects:
1, the soil image acquisition equipment of the utility model can fast and accurately acquire soil image and pass through wireless network
Network sends soil image, so that image processing software is handled and analyzed in time, obtains acquired soil image pair
Answer the moisture content of soil.
2, the soil water-containing amount detection systems of the utility model obtain soil image by soil image acquisition equipment in real time,
And handled by computer real-time reception, the moisture content of soil is analyzed in time, is had compared with high-timeliness and accuracy.
3, the soil water-containing quantity measuring method system of the utility model gray value-moisture content standard curve, when obtaining
When soil gray value of image, soil moisture content can be fast and accurately obtained, is had compared with high-timeliness and accuracy.
Below with reference to accompanying drawings, the utility model is described in further detail.
Detailed description of the invention
The attached drawing constituted part of this application is used to provide a further understanding of the present invention, the utility model
Illustrative embodiments and their description are not constituteed improper limits to the present invention for explaining the utility model.In attached drawing
In:
Fig. 1 is that the soil image of the preferred embodiment in the utility model obtains equipment structure chart;
Fig. 2 is the functional relation fitted figure of the preferred embodiment in the utility model water paddy soil moisture content and gray value;
Fig. 3 is the functional relation fitted figure of the preferred embodiment in the utility model water paddy soil moisture content and gray value.
Wherein, 1, magazine;2, built-in light source;3, transparent sleeve;4, industrial camera;5, prism;6, power supply;7, solar energy
Plate.
Specific embodiment
The embodiments of the present invention are described in detail below in conjunction with attached drawing, but the utility model can be by right
It is required that the multitude of different ways for limiting and covering is implemented.
Embodiment 1:
The utility model provides a kind of soil image acquisition equipment, referring to Fig. 1, including it is magazine 1, built-in light source 2, transparent
Sleeve 3, industrial camera 4, prism 5 and power supply 6, industrial camera 4 are installed on 3 inner upper of transparent sleeve to shoot pedological map
Picture, built-in light source 2 are set to 3 lower inside of transparent sleeve and provide light source for the shooting of industrial camera 4, and prism 5 is installed on built-in
The reflectivity of built-in light source 2 is adjusted above light source 2, power supply 6 is that built-in light source 2 and industrial camera 4 are powered, and magazine 1 is set to
3 top of transparent sleeve is stored and transmitted with the image obtained to industrial camera 4.
When measurement, first transparent sleeve 3 is placed into the soil, the built-in light source 2 of 3 lower inside of transparent sleeve is in whole system
Under conditions of interfering in no external light source, soil image is reacted to industrial camera 4.Select industrial camera 4 can be effective
Avoid the influence of white balance.Prism 5 is arranged such that 2 reflectivity of built-in light source reaches maximum, most really reflects soil
Color.Magazine 1 is set to 3 top of transparent sleeve, and when transparent sleeve 3 places into the soil middle, magazine 1 is still above soil.
Magazine 1 is saved and is transmitted after receiving the soil image that industrial camera 4 is shot, and makes computer terminal according to soil image to soil
Earth moisture content is analyzed.
Preferably, magazine 1 includes box body and GPRS image capture module, and GPRS image capture module is set to tray interior
And data exchange is carried out to obtain the soil image of the acquisition of industrial camera 4 and pass through GPRS network for pedological map with industrial camera 4
As being transmitted wirelessly.
GPRS image capture module is provided in magazine 1, GPRS image capture module collects the soil of the shooting of industrial camera 4
The transmitting for carrying out image, signal after earth image by GPRS network, is received eventually by computer, is then known by image
Other processing software carries out analysis and finally obtains the moisture content that acquired soil image corresponds to soil.Be additionally provided in magazine 1 for
The power supply 6 of GPRS image capture module power supply, photo resistance control switch etc..1 surrounding of magazine and upper end need to seal, magazine 1
Light filling technology acquires crop root layer soil image, avoids the influence of solar irradiation under natural conditions
Preferably, transparent sleeve 3 is organic glass sleeve.
Organic glass sleeve can guarantee the normal photographing of industrial camera 4, measure to shooting effect not by test of many times
There are influences.
Preferably, power supply 6 is battery.
Battery can power when shooting for industrial camera 4 and built-in light source 2, supporting industry camera 4 and built-in light source 2
Normal operation.
Preferably, soil image acquisition equipment further includes solar panels 7, solar panels 7 be set to 1 outside of magazine and with storage
Battery connection provides electric energy to charge the battery.
Solar panels 7 are set to outside magazine 1, can be that battery charges using solar energy.
Above-mentioned soil image acquisition equipment is relied on, the utility model additionally provides a kind of soil water-containing amount detection systems,
Soil image acquisition equipment including computer and as described in any of the above-described, computer pass through cable network or wireless network
It is connect with soil image acquisition equipment to receive the image of soil image acquisition equipment acquisition and according to image analysis soil water-containing
Rate.
Computer carries out processing calculating to image by Matlab software, obtains soil moisture content.Whole operation whole process is certainly
Dynamic intelligence, and soil environment will not be destroyed.Computer end, which opens software, can obtain soil moisture information, have good reliable
Property, interactivity, real-time and flexibility.
Embodiment 2:
Test soil is derived from the red soil and plantation peanut that the rice cultivation all the year round of garden Experimental Base weeds in Agricultural University Of Hunan
Reddish yellow soil.Rice soil is numbered as RS, peanut soil number is PS, RS content of organic matter 18.49mg/kg, the PS content of organic matter
21.36mg/kg。
It is air-dried in its natural state after the completion of soil collection, the sieve for crossing 2mm removes root system of plant residue, surveys initial
Water content.Sieved soil 100g is weighed in culture dish, soil moisture content is slowly added water to graduated cylinder and reaches saturation state, is recorded
Amount of water.Culture dish is put into 105 DEG C of baking oven, takes out culture dish weighing record moisture from baking oven every certain time length and subtract
On a small quantity and light filling is carried out to it in magazine to take pictures.The image grayscale value calculating method of acquisition: image is by pixel one by one
It constitutes, the color of each pixel is made up of 3 primary colours of RGB, and the value of each primary colours is 0-255, converts thereof into gray scale
The method of value is that every kind of primary colours on pixel are multiplied by with 1/3 phase is cumulative, value 0-255,0 be it is completely black, 255 be Quan Bai.Number
Word image is substantially a math matrix, and each of matrix element is exactly a pixel of image, being averaged in image
Gray value is that the three primary colours of each pixel of image are converted into gray value add up then divided by pixel number.
G (x) indicates the gray value of image in formula (1), and r (x) is red primary angle value, and g (x) is green primary angle value, b (x)
It is blue primary angle value.X indicates pixel point variable.
In formula (2)Indicate the average gray value of image, G (xi) indicate image each point grey scale pixel value.
The statistics of gray value of image is calculated by matlab software programming program.
It tests and the corresponding image averaging gray value measurement of water content is carried out to two types soil, for rice soil point
Not Xuan Yong 10 culture dishes be packed into the soil of saturation moisture contents and carry out drying and make water content decline acquisition image, data result such as table
Shown in 1.The difference of the soil and initial water content that are packed into due to each culture dish makes soil moisture content decline also each not phase
Together, therefore each group of data are all by its exclusive changing rule feature.Test is in order to carry out correlation analysis to each group of data, respectively
Extract in every group of data soil moisture content be 0%-5%, 5%-10%, 10%-15%, 15%-20%, 20%-25%,
The gray scale of 25%-30%, 30%-35%, 35%-40%, 40%-45%, 45%-50%, 50%-55%, 55%-60%
Value.The segmentation moisture content for extracting every group of data is subjected to discrete analysis, sum of squares of deviations is calculated most by equation of linear regression
Gray value of the small gray value as segmentation moisture content median.Tables 1 and 2 is respectively that water paddy soil water content is right with it
The image averaging sum of the grayscale values peanut the answered ground corresponding image averaging gray value of soil moisture content.It is calculated in table 3 and table 4
Rice soil soil is segmented the gray value and peanut ground soil point out of minimum deviation quadratic sum corresponding to the median of moisture content
The gray value of minimum deviation quadratic sum corresponding to the median of section moisture content.
The corresponding image averaging gray value of 1 water paddy soil water content of table
Infusing N indicates group number, and test has carried out 10 groups altogether and repeated to test, and θ indicates soil moisture content, and gray indicates soil gray scale
Value.
2 peanut of the table ground corresponding image averaging gray value of soil moisture content
Infusing N indicates group number, and test has carried out 10 groups altogether and repeated to test, and θ indicates soil moisture content, and gray indicates soil gray scale
Value.
3 water paddy soil of table segmentation moisture content corresponds to the discrete analysis of average gray value
4 water paddy soil of table segmentation moisture content corresponds to the discrete analysis of average gray value
Test by multiple groups repeat test to paddy field and peanut two kinds of soil moisture contents change and gray-value variation into
Row discrete analysis finds out image averaging gray value corresponding to different segmentation moisture content medians respectively.Using least square method
Soil moisture content and gray-value variation trend are fitted, as a result as shown in Figure 2 and Figure 3.Water paddy soil in Fig. 2 (a) with
The linear fit of gray value, the variation tendency of the gray value gradually increased by moisture content is it is found that gray value and soil moisture content
In non-linear change tendencies.Fig. 2 (b) and Fig. 2 (c) is nonlinear fitting, and water paddy soil moisture content is a kind of non-with gray value
Linear changing relation, when soil moisture content is lower, gray value is higher, under the raising soil gray value of image of moisture content
Drop, when soil moisture content is more than 30%, moisture content continues to increase the rising of soil gray value of image.The first order of Fig. 2 (a) is fitted
Function y=-0.1629x+183.4713, goodness of fit R2=0.2357;The quadratic term fitting function y=of Fig. 2 (b)
0.0231x2- 1.5517x+197.4078, goodness of fit R2=0.9058;The cubic term fit equation y=- of Fig. 2 (c)
0.0003x3+0.0544x2- 2.3044x+201.2471, goodness of fit R2=0.9733.Water paddy soil moisture content and gray value
Function Fitting, the goodness of fit of cubic term is best.Be in Fig. 3 (a) peanut soil moisture content and gray value variation tendency
Linear fit gradually increases the variation tendency of gray value by moisture content it is found that gray value and soil moisture content are in non-linear change
Change relationship.Fig. 3 (b) and Fig. 3 (c) are nonlinear fittings, peanut soil moisture content it is similar with gray-value variation with paddy field, it is native
Gray value is larger when earth moisture content is lower, as the raising soil gray value of image of soil moisture content declines, works as soil moisture content
When more than 30%, moisture content continues to increase the rising of soil gray value of image, when soil moisture content is more than 50%, soil image ash
Angle value decline.First order the fitting function y=-0.21x+180.0472, goodness of fit R of Fig. 3 (a)2=0.3129;Fig. 3's (b)
Quadratic term fitting function y=0.036x2- 2.5708x+212.3572, goodness of fit R2=0.8847;The cubic term of Fig. 3 (c) is quasi-
Close equation y=-0.0017x3+0.2042x2- 7.4668x+254.5079, goodness of fit R2=0.9815.Peanut ground soil water-containing
The goodness of fit of the Function Fitting of rate and gray value, cubic term is best.
The optimal cubic term mathematical model of the experimental evidence goodness of fit carries out verifying analysis to soil moisture content, tests to water
Two methods of rice field 10 groups of soil application that with peanut soil has selected moisture content different respectively are measured, as a result such as table 5
It is shown.Compared with the water paddy soil water content measured using the function model of gray level image with oven drying method measures soil moisture content
For deviation range -5.94% to 2.42%, average deviation absolute value is 2.09%.The function model of gray level image measures peanut
Ground soil moisture content with oven drying method measure soil moisture content compared with deviation range -3.82% to 2.36%, average deviation is exhausted
It is 1.78% to value.When two types soil is that moisture content is larger, gray value of image measured value and oven drying method measured value result
Deviation increases.This may be when soil moisture content is smaller soil color variation it is obvious, the soil color when soil moisture content is larger
Variation is smaller, and using gray level image Model fitting result there are certain deviation, two kinds of soil deviations of testing inspection are equal
6% hereinafter, illustrating that the mathematical model of fitting can relatively accurately measure soil moisture content.
The soil moisture content of 5 gray value of table measurement and the water content error analysis of oven drying method measurement
The above descriptions are merely preferred embodiments of the present invention, is not intended to limit the utility model, for this
For the technical staff in field, various modifications and changes may be made to the present invention.It is all in the spirit and principles of the utility model
Within, any modification, equivalent replacement, improvement and so on should be included within the scope of protection of this utility model.
Claims (5)
1. a kind of soil image acquisition equipment, which is characterized in that including magazine (1), built-in light source (2), transparent sleeve (3), work
Industry camera (4), prism (5) and power supply (6), the industrial camera (4) be installed on the transparent sleeve (3) inner upper with
Soil image is shot, the built-in light source (2) is set to the transparent sleeve (3) lower inside as the industrial camera (4) bat
Offer light source is taken the photograph, the prism (5) is installed on the reflection that the built-in light source (2) are adjusted above the built-in light source (2)
Rate, the power supply (6) is the built-in light source (2) and the industrial camera (4) is powered, and the magazine (1) is set to described
It is stored and transmitted at the top of bright sleeve (3) with the image obtained to the industrial camera (4).
2. a kind of soil image acquisition equipment according to claim 1, which is characterized in that the magazine (1) includes box body
With GPRS image capture module, the GPRS image capture module is set to the tray interior and carries out with industrial camera (4)
Data exchange is to obtain the soil image of industrial camera (4) acquisition and be transmitted wirelessly soil image by GPRS network.
3. a kind of soil image acquisition equipment according to claim 1, which is characterized in that the transparent sleeve (3) is to have
Machine glass sleeve.
4. a kind of soil image acquisition equipment according to claim 1, which is characterized in that the power supply (6) is battery.
5. a kind of soil image acquisition equipment according to claim 4, which is characterized in that the soil image acquisition equipment
It further include solar panels (7), the solar panels (7) are set to the magazine (1) outside and are connected as institute with the battery
It states battery charging and electric energy is provided.
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109297963A (en) * | 2018-10-12 | 2019-02-01 | 湖南农业大学 | Soil image acquisition equipment, soil water-containing amount detection systems and detection method |
| CN110887761A (en) * | 2019-12-07 | 2020-03-17 | 宁夏大学 | Method and system for measuring surface soil water content |
-
2018
- 2018-10-12 CN CN201821656800.9U patent/CN209387532U/en active Active
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109297963A (en) * | 2018-10-12 | 2019-02-01 | 湖南农业大学 | Soil image acquisition equipment, soil water-containing amount detection systems and detection method |
| CN110887761A (en) * | 2019-12-07 | 2020-03-17 | 宁夏大学 | Method and system for measuring surface soil water content |
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