Design and Implementation of Service Platform for Wheat Nutrition

Diagnosis

Ning Li

, Jinyuan Zhang

and Zhongliang

Deng

School of Electronic Engineering, Beijing University Of Posts And Telecommunications, 10 Xitucheng Road, Haidian

District, Beijing, China

{ Ning Li, Jinyuan Zhang } lnmmdsy@sina.com, zjy2223137@163.com

Keywords: Service platform, Data Warehouse models, image processing, nutrition diagnosis model Introduction.

Abstract: For the shortage about research and analysis of wheat farmers for current nutritional status and disease of

wheat, diagnosing the disease of wheat reasonably, nutrition diagnosis system was designed and established

a wheat nutrition diagnosis platform based on image processing. Combined with the needs analysis,

researched the framework design and business processes of wheat nutrition diagnosis system, and designed

a massive data warehouse model with complex data structures based on data management and nutritional

model based on image processing. Furthermore, in connection with the application of the system in

changge, Henan province, the core applications and key technologies of platform during the process of

realization were explored and shared.

1 INTRODUCTION

The traditional wheat crop nutrition analysis and

disease diagnosis mainly rely on manual visual way

and agricultural experts attending the seminar, but

because of the variability of the environment and the

diversity of growth in different stages of crop,

leading to the deviations between diagnosis results

and the actual growth of wheat. On the other hand,

due to technical or expert personnel cannot arrive to

the farmland timely and missed the best time of

diagnosis, expert consultation revealed timeliness

defects. And with the development and innovation

of information industry and the technology, we can

solve these problems by means of image processing

and pattern recognition techniques. Therefore, we

hope to build image recognition and image

processing systems for real-time diagnosis of the

nutritional status of wheat crop, which makes wheat

nutritional management more scientific and

standardized.

In recent years, various agricultural expert system

based on nutrition diagnosis sprang up and has

reached a mature stage. The international

community has the majority of agricultural expert

systems are widely used for aspects of crop

production management, pest and disease diagnosis

and so on ( Wali, Emal; Datta, Avishek; Shrestha,

Rajendra P, 2016, Reckling, Moritz; Hecker, Jens-

Martin; Goeran, 2016). Development of Chinese

agricultural expert system is also in a period of rapid

development, has established a plant protection

expert systems, pest control expert systems, and has

been widely used (Yin Xiaogang; Wang Meng,

2016, Takashi Ohnishi; Yuka Nakamura, 2016).

Although the agricultural expert system has been a

maturing stage, the situation on the monitoring of

crop nutrition expert systems is mostly for

forecasting and diagnosis of pest crop, which is

useless for this crop nutrients with normal growth.

Therefore, for a large field wheat crop growing

normally, we use database model and image

processing technology, developing a nutrition

diagnostic service platform for farmers timely access

to the daily wheat growth status information.

2 PLATFORM GENERAL

DESIGN

According to the different developmental stages of

wheat growth characteristics, combined with lessons

learned and wheat nutrition diagnosis disease cases,

and the impact of field weather environmental

factors, the wheat nutrition diagnosis service system

is established, the process design shown in Figure 1.

283

Deng Z., Li N. and Zhang J.

Design and Implementation of Service Platform for Wheat Nutrition Diagnosis.

DOI: 10.5220/0006449102830288

In ISME 2016 - Information Science and Management Engineering IV (ISME 2016), pages 283-288

ISBN: 978-989-758-208-0

283

The system can obtain the image of wheat in each

period by means of mobile collection device, and

the collected moisture and image data is transmitted

over the network to a remote database server for

centralized storage and management of data

classification. Administrators issued request through

the Web server to the database to obtain the

collected wheat image data, with image processing

technology nested to the wheat nutrition model,

access to information on the nutritional status of

wheat leaves taken, in accordance with relevant

knowledge and expertise nutrition diagnostic

techniques, diagnostic recommendations are given

symptomatic uploaded to the system home page for

reference and learning.

farmland

Bluetooth

Taking

Pictures

data

transmission

Web service

Image

proceing

Wheat nutrition

model

Display results

feedback

Upload

and

download

Figure 1: Process of design platform..

3 PLATFORM ARCHITECTURE

DESIGN

According to the platform position and social

function, considering the current status of wheat

nutrition analysis and diagnosis, the overall logical

architecture is divided into data service layer, the

system support layer and the business application

layer (Paradiso, Sean P; Delaney; Kris T, 2016).

i. data service layer

Data services layer achieves the main data

collection, classification, storage and centralized

provisioning. The system data services layer mainly

consists of collection data, storage services data and

application service data, which will feedback to the

system user by the form of a form, line chart or mail

to the system user.

ii. system support layer

System support layer polymerizes the

dispersed, heterogeneous application and

information resources through a unified access entry,

to achieve various types of data resources and a

variety of applications across databases and systems

with seamless access and integration (Donatas;

Aviža;Zenonas; Turskis, 2015). The system support

layer mainly refers to safeguard and share common

components of data and provide standardized

management, including data storage and

transmission, user information and administrator

rights management, refresh and deploy storage data .

iii. business application layer

Business application layer mainly refers to help

user registering wheat nutrition diagnostic services

platform to perform operations and implement the

corresponding function. Farmers and grain dealers

can check the growth of wheat and nutrition analysis

results within a certain time, what they acquire as a

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reference to adopt measures correlatively.

Administrators need to go through the certification

authority into the system management interface,

giving a feedback to the user based on the current

wheat nutrition diagnosis information, to improve

the efficiency of the system.

4 PLATFORM FUNCTIONAL

MODELING

4.1 Data Warehouse Modeling

Currently data warehouse modeling methods used

commonly are paradigm modeling and dimensional

modeling method. The paradigm modeling is mainly

used in the data storage for relational database, and

the modeling process is relatively simple. Compared

with paradigm modeling, the data can be processed

more efficiently in dimensional modeling, which

method mainly used to solve the performance issues

of modeling process. However, these modeling

methods are mostly used for traditional structured

data and unstructured data with simple construction,

but there is a complex multi-dimensional

relationship between the data and image information

of system, which contribute to the results of using a

conventional methods to establish regular contact

will become bloated and inefficient, and data

processing result will be too dependent on data

structure relationships (L. Jiang; J. Xu; B. Xu,

2011).

Based on the analysis of different types of

unstructured data, combined with user needs and

experience, propose a complex unstructured data for

mass data model structure. The system platform data

modeling process is divided into four steps: business

modeling phase, the concept of domain modeling

phase, the logical modeling phase and the physical

modeling phase, concrete steps are as follows:

• business modeling phase

Combined with business needs the business

modeling phase can divides into four main blocks,

including: user information, image acquisition,

images processing and nutrition business model.

According to the nature of the business, every

division within each business module must

determine the business topics and establish the

appropriate contact, as a basis for analysis of the

entire business processes and functions.

• concept of domain modeling phase

In the establishment of business processes,

substantializing the abstract business sub-module

with complex structure and sub-structure

relationships to concrete elements of the system and

its internal relations, adopt relational model to

express the attribute information of unstructured

data. Furthermore, two-dimensional table structure

of relational model by adding the extended relational

model to express complex structure of unstructured

data, use object-oriented model to express the

unstructured data (G. Bavota, 2016). Combined with

the business needs, the system abstract the specific

business template to basic elements, handle events,

process results and descriptions. The basic elements

include user information, weather, address, soil and

other basic information; event processing refers to

the various elements collected for processing and

integration; process result incorporate nutrition

diagnosis results and recommendations; descriptions

contain the various indicators and wheat growth

period introduction.

• logical modeling phase

Having established the relevance of each abstract

entities, adhering the attachment into system during

establishing process for data identification is needed

(Tsou; Ming Cheng, 2016). Such as handling events

for wheat image, also need to get their image

numbers, acquisition time, collecting location,

upload time and other basic information. After

improving the basic attributes of the entities, should

find out the relationship between the contact and

abstract event abstract entities, and make

explanation for which will complete the whole

concept model series into an organic entity, and fully

express service between associations.

• physical modeling phase

Physical modeling stage aim to incarnate the content

of the logical model within implementation of

concrete on physical media. Wheat nutrition

diagnosis services platform adopts B/S structure,

using MYSQL database to store the collected data.

For business needs, the collected information and

related properties of wheat image stored in the

database with categorized, and generated the

appropriate fact tables, dimension tables, and line

charts on the Web side. In addition, the maintenance

chart is established for database metadata and real-

time feedback needs, and refresh the uploaded data

timely to ensure smooth and safe operation of the

system.

The database modeling design shown in Figure 2.

Design and Implementation of Service Platform for Wheat Nutrition Diagnosis

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285

Figure 2: Data warehouse model design

4.2 Wheat nutrition model

Wheat leaf color and leaf shape not only visually

reflecting its chlorophyll content, but also can show

nitrogen metabolism in the body, therefore, the

image of Plant canopy is closely related to the

growth characteristics, the Contracts of light

function and nitrogen nutrition status (Y. q. Qi,

2013). This system is through image analysis of

chlorophyll content and leaf nitrogen content of

wheat, in order to determine the nutritional status of

wheat crops.

Full coverage sampling for wheat crop during

jointing stage, take photos for wheat and get image

the same day, moreover, measured the amount of

dry matter of leaf stem, the leaf nitrogen content

LNC and the values of chlorophyll content. In this

study, choose white paper as the background, in

order to achieve image segmentation of leaf and

background using RGB image setting Thresholds.

After the completion of image segmentation using

RGB and HSV color model to describe nitrogen

status of wheat, calculated hue (H, Hue), lightness

(V, Value), saturation (S, saturation) and dark green

index (DGCI, dark green Color index) using the

average gray hue of all the pixels on the blade RGB

channel (P. Wuttisarnwattana, 2016).

The main processing steps are as follows:

1) To overcome the impact of changes in light and

shadow on the part of the image, take

normalization process for wheat canopy image.

In this paper, an improved normalization

method is proposed, and the results are more

scientific and reasonable, formula is shown as

follows:

222

r =

g =

b =

RGB

⎧

⎪

⎨

⎪

⎩

(4-1)

2) Binarization, denoising and morphological

opening operation processing were adopted for

the object images. Denoising method used

adaptive wavelet threshold model, which

combines the traditional advantages of wavelet

thresholding, while adopting adaptive processing

for high-frequency wavelet decomposition

coefficients of different amplitude on the basis of

wavelet decomposition level (Sushanth, 2011,

Xiao Qian; Ge Gang, 2016). Denoising model

formula is:



()

2ln 1 2

ign t

ωω

ωωω ω

−

⎧

⋅≥

⎪

⎧⎫

⎪

⋅+

⎪⎪ ⎪

⋅− <<

⎨⎨ ⎬

⎪⎪ ⎪

⎩⎭

⎪

⎩

(4-2)

Where

denotes the amplitude wavelet

coefficients, i, j denotes the image size,

t and

denotes the thresholds, n denotes wavelet decom-

position level.

3) Use the Fuzzy C-means algorithm for image

segmentation, the objective function is:

FCM

ij ij

Eud

∑∑

(4-3)

Where C denotes the number of clusters, N denotes

the number of pixels in the image,

d denotes the

gray distance,

u denotes the fuzzy membership for

v , where

v denotes the cluster center of

number I, the Formula is shown as follows:

⎛⎞

⎜⎟

⎝⎠

∑

(4-4)

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After extracting the wheat based color

characteristic, fitted with the same period of leaf

nitrogen content in linear, tuning and determine the

best-fit coefficients of three primary components,

and determine the normalized color mix index under

the RGB space (C. W. Lin, 2014). Through corre-

lation analysis with NCMI, wheat leaf nitrogen

concentration and chlorophyll content, demonstrate

the nutrition diagnosis results based on wheat image

processing.

5 PLATFORM REALIZATION

Wheat nutrition diagnostic services platform utilize

the incremental development approach, set up the

database and nutritional analysis platform based on

collected wheat moisture and image data, and enrich

the data of database with demand. Firstly, we must

continue to improve the existing forms of

distribution data in the data warehouse according to

user needs. Moreover, it is necessary to continue to

add moisture and image information of the

respective growth stages of wheat late to the

platform, formatting the new data marts and

statistics.

The system adopts web Services as the core

technology of application platform and information

services resources integration, using MVC and

Struts + Hibernate + Spring as the standard

architecture. Interface performance uses html + css +

JS as design framework, mainly utilizing PHP as a

carrier to reflect the design concept, meanwhile

reduce the interdependence of technology in internal

internet system as far as possible ( R. Sethuraman,

2016). The database platform store personalized

management (authentication and rights of manage-

ment, navigation, and retrieval), user behaviour log

and system administration files. Server database is

used to store wheat moisture data and image

information, achieve data uploading and

management implemented in the MYSQL database

management system. In addition, the system

management module is designed to provide a

platform for the service module, management and

maintenance of the database data platform to ensure

the smooth and efficient operation of the system.

The primary interface of wheat nutrition

diagnostic services platform shown in Figures 3 and

4. Figures 3 shows the wheat image information,

users select the time and location information from

drop-down box to view the corresponding conditions

of wheat growing image. Figure 4 displays the

nutritional diagnosis result after the image

processing for selecting the wheat images, which

analyzes the nutritional status judged by the content

of chlorophyll and leaf nitrogen content of wheat.

Figure 3: Wheat picture selection screen

Figure 4: Wheat nutrition diagnosis interface

6 CONCLUSIONS

In this paper, the service platform for the wheat crop

nutrition diagnosis and analysis at different

developmental stages is established, with the method

of rigorous architecture design and modeling

analysis, and the platform design and image

processing technology as the support. Through

rigorous scientific methods and experience in

agriculture proposed ways of Wheat Nutrition

Diagnosis and put service platform into effect for the

majority of farmers to use and reference. The system

can meet the application requirements for farmers’

judgment of growth of wheat in Plains, providing

guidance for agricultural production, which is

important for modern agricultural information

management.

ACKNOWLEDGMENT

This work was supported by the Integration and

Application of Information Service in the Main

Stages of Grain Production (National “12th Five-

Design and Implementation of Service Platform for Wheat Nutrition Diagnosis

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Design and Implementation of Service Platform for Wheat Nutrition Diagnosis

287

Year” science and technology support plan) of China

under Grant No.2014BAD10B06.We thank Li Ning,

Deng Zhongliang, Zhang Qi and Gu Yunxia

comments and suggestions, which helped improve

the overall quality of this work.

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