Weijie Lin¹, Hailing Xian^1*, Wenwen Wang², Caiyun Huang¹, Zhenkun Jiang¹, Xiaoliang Zhou^1
1School of Mathematics and Statistics, Lingnan Normal University, Zhanjiang, China.
²Zhanjiang Mechanical and Electrical School, Zhanjiang, China.
DOI: 10.4236/ojmsi.2022.103017   PDF    HTML   XML   219 Downloads   885 Views   Citations

Abstract

Tomato is a common food on the human table. Up to now, the research on the growth and development model of tomato has been about 50 years. There are many researches on the main nutrients of tomato, such as carbon and nitrogen, but few on the trace element zinc. In this paper, taking plant nutrient C, N and Z_n as variables, the differential equation model of C, N and Z_n in tomato growth and development was established. According to the research of tomato as a whole and divided into root and leaf, the one-compartment and two-compartment models of tomato growth and development were established. The model was analyzed by Matlab program, and the existing experimental data was used to test the numerical simulation results, which proves that the model conforms to the facts.

Keywords

Carbon, Nitrogen and Zinc, Differential Equation Model, Tomato Growth and Development

Share and Cite:

1. Introduction

The widely cultivated tomato is a common vegetarian dish on people’s tables. However, the long-term excessive use of chemical fertilizer has led to many serious problems in the taste and quality of tomato [1]. Therefore, how to improve the quantity and quality of tomato production by precise fertilization is a topic of great research significance.

In recent decades, there have been many achievements on this subject. In 1986, Spitters et al. calculated the masses of dry matter of the organs of the tomato based on the dry matter classification method and established a dynamic simulation model of tomato [2]. In 1996, Heuvelink analyzed tomato growth in greenhouses and constructed TOMSIM model based on existing crop models [3]. In 1997, Zhou, et al. proposed a growth and development model of tomato by observing the change of dry matter in tomato growth stages when the total solar radiation and temperature were changed in a polyvinyl chloride film covered the test field [4]. In 1998, Zhang put forward a differential equation about the relationship between nitrogen and vegetable yield [5]. In 2012, Wang added the effects of oxygen and phosphorus concentration in the establishment of plant growth model [6]. In 2014, Ji et al. studied and established the root growth of tomato model [7]. In 2019, when studying the growth and development models of plants, Li established single compartment, two-compartment and three-compartment models of tomatoes to optimize plant growth [8]. In 2020, Zhang established differential equation model for the requirements proportion of carbon, nitrogen and potassium under the influence of audio frequency [9]. For more relevant works of literature, we may refer to [10] [11].

2. Some Basic Facts and Assumptions about the Subject

2.1. Basic Facts

(F1) The nutrients needed by tomato are mainly provided by the transformation of carbon and nitrogen.

(F2) Leaf organs fix carbon elements in the chloroplast and root organs fix nitrogen elements, and these elements have a fixed proportion in the body of tomato during its growth.

(F3) Carbon is transported from leaf to root, while nitrogen is in reverse.

(F4) In the whole process of plant growth, the amount of carbon fixed is related to the leaf area, while the amount of nitrogen is related to the root surface area, and the root area has a fixed proportion to the leaf area.

(F5) Chloroplasts in the leaves, with the help of light, convert carbon from carbon dioxide into organic matter through photosynthesis. And this organism provides energy for the plant body. Nitrogen absorbed by root organs can be converted into amino acids, which can be converted into proteins in cells. Protein is an important component of tomato structure, and can also participate in the chemical reaction of tomato cells and the composition of cell membrane.

(F6) The main consumption ways of organic matter formed by photosynthesis are:

1) For active transport and other work energy, transport of the two main nutrients above.

2) Conversion energy used for material transformation, such as photosynthesis, dehydration condensation and other material transformation process. It is used to convert small molecules into large molecules for storage.

3) Maintenance energy used to maintain some easily decomposed protein structures, and binding energy consumed during tissue formation.

2.2. Basic Hypotheses

(H1) Plant nutrients are provided only by carbon and nitrogen.

(H2) The use of carbon requires the involvement of proteins or nitrogen.

(H3) In plants, the energy provided by organic matter for macromolecular conversion increases, while the energy for the maintenance of unstable protein structures decreases.

(H4) The ratio of carbon to nitrogen in a tomato is independent of the aging of the tissue, i.e., it is the same in all tissues.

3. One-Compartment Differential Equation Model

The basic idea of one-compartment model is studying tomato as a whole, providing nutrients and required trace elements of tomato by external sunlight, carbon dioxide, nitrogen fertilizer and zinc fertilizer, ignoring the specific function and morphological differences of root and leaf organs and building a simple one-compartment model of tomato growth and development. The idea is shown in Figure 1.

At time t, the concentration of carbon, nitrogen and zinc elements in tomato were assumed to be $C\left(t\right),N\left(t\right)$ and $Z_n\left(t\right)$ functions. The nutrient consumption during tomato growth should be a function of $C\left(t\right),N\left(t\right)$ and $Z_n\left(t\right)$, denoted as the tomato nutrient consumption rate function $f\left(C,N,Z_n\right)$ which satisfies:

(D1) When any one of the three elements of carbon, nitrogen or zinc fails to meet the requirements of tomato growth, the consumption rate is correspondingly slower.

(D2) When the supply of carbon, nitrogen and zinc exceeds demand, the consumption rate is a definite value that depends only on the variety and heredity of the tomato.

According to hypothesis (H2), the rate of carbon consumption in tomato body is defined as $Vf\left(C,N,Z_n\right)$, where V is the volume. According to the hypothesis of (H4), let the ratio of carbon, nitrogen and zinc in tomato be $1:\mu :\gamma$, that is to say, $\mu Vf\left(C,N,Z_n\right)$ and $\gamma Vf\left(C,N,Z_n\right)$ functions express the rates of nitrogen and zinc consumption respectively in tomato. Based on hypothesis (H3), in order to avoid the infinite growth of tomato, W is expressed as the total mass of tomato, and both a andb are positive numbers. The ratio of binding

energy to total energy in tomato is set as a monotonically decreasing function $R_1=a-bW$. Then $R_{1}V\left(t\right)f\left(C,N,Z_n\right)$ represents the amount of binding energy in tomato at time t. The conversion coefficient of tomato dry tissue from 1kmol carbon to measurable tomato mass (kg) was set as r (the conversion rate of binding energy to mass). Then the differential equation model of tomato growth can be expressed as:

$\frac{\text{d}W}{\text{d}t}=r\left(a-bW\right)V\left(t\right)f\left(C,N,Z_n\right).$ (1)

According to the relation between volume, mass and density, $V\left(t\right)=\frac{W\left(t\right)}{\rho }$, Equation (1) can be arranged as

$\frac{\text{d}W}{\text{d}t}=\frac{r\left(a-bW\right)}{\rho }Wf\left(C,N,Z_n\right)$ (2)

where $\rho$ represents the density of tomato. To meet the conditions (D1) and (D2), $f\left(C,N,Z_n\right)$ can be selected a fractional linear form as follows

$f\left(C,N,Z_n\right)=\frac{\alpha CN{Z}_n}{1+\beta CN{Z}_n}$ (3)

where $\alpha ,\beta$ are positive numbers. According to the law of conservation of mass, the three equation models of $C\left(t\right),N\left(t\right)$ and $Z_n\left(t\right)$ are now explored.

The mass of carbon at time ( $t+\Delta t$ ) in the tomato should be equal to the amount of carbon at time t in the tomato adding the input and then minus the output in time interval $\left[t,t+\Delta t\right]$, that is,

$W_C\left(t+\Delta t\right)=W_C\left(t\right)+R_{3}W\left(t\right)\Delta t-Vf\left(C,N,Z_n\right)\Delta t$

where $W_C\left(t\right)=V\left(t\right)C\left(t\right)$, $R_3$ is ratio coefficient of the amount of carbon formed by tomato per unit time to plant mass and $V\left(t\right)=\frac{W\left(t\right)}{\rho }$. Let $\Delta t\to 0$, then

$\frac{\text{d}\left(W_C\right)}{\text{d}t}=\rho R_{3}W\left(t\right)-Wf\left(C,N,Z_n\right).$ (4)

Similarly, the nitrogen mass of the tomato at time ( $t+\Delta t$ ) should be equal to the nitrogen mass at time t plus the input and then minus the output in $\left[t,t+\Delta t\right]$, that is,

$W_N\left(t+\Delta t\right)=W_N\left(t\right)+R_{5}W\left(t\right)\Delta t-\mu Vf\left(C,N,Z_n\right)\Delta t$

where $W_N\left(t\right)=V\left(t\right)N\left(t\right)$, $R_5$ is ratio coefficient of nitrogen absorbed by the root organ in ∆t time and $\mu$ is ratio coefficient of nitrogen consumption in ∆t time according to (H4), and

$W_{Z_n}\left(t+\Delta t\right)=W_{Z_n}\left(t\right)+R_{7}W\left(t\right)\Delta t-\tau Vf\left(C,N,Z_n\right)\Delta t$

where $W_{Z_n}\left(t\right)=V\left(t\right)Z_n\left(t\right)$, $R_7$ is ratio coefficient of zinc absorbed by the root organ in ∆t time and $\tau$ is ratio coefficient of zinc consumption in ∆t time according to (H4). Let $\Delta t\to 0$, we get

$\frac{\text{d}\left(W_N\right)}{\text{d}t}=\rho R_{5}W\left(t\right)-\mu Wf\left(C,N,Z_n\right)$, (5)

$\frac{\text{d}\left(W_{Z_n}\right)}{\text{d}t}=\rho R_{7}W\left(t\right)-\tau Wf\left(C,N,Z_n\right)$. (6)

By combining (2), (4), (5) and (6), we get the one-compartment ordinary differential equation model of carbon, nitrogen and zinc content in growing tomato

$\{\begin{array}{l}\frac{\text{d}W}{\text{d}t}=\frac{r\left(a-bW\right)}{\rho }Wf\left(C,N,Z_n\right),\\ \frac{\text{d}\left(W_C\right)}{\text{d}t}=\rho R_{3}W-Wf\left(C,N,Z_n\right),\\ \frac{\text{d}\left(W_N\right)}{\text{d}t}=\rho R_{5}W-\mu Wf\left(C,N,Z_n\right),\\ \frac{\text{d}\left(W_{Z_n}\right)}{\text{d}t}=\rho R_{7}W-\tau Wf\left(C,N,Z_n\right)\end{array}$ (7)

where $r,\rho ,\mu ,\tau ,R_3,R_5$ and $R_7$ are all positive constants.

In the thorough experiment on cultivated tomato [12], Song, et al. proved that dynamic liquid level method can promote the growth and development of tomato, and obtain the experimental results as in Table 1.

In order to make better use of Matlab simulation, we introduce new transformation,

$y_1\left(t\right)=W\left(t\right),y_2\left(t\right)=W_C\left(t\right),y_3\left(t\right)=W_N\left(t\right),y_4\left(t\right)=W_{Z_n}\left(t\right).$

Then, (7) can be transformed into

$\{\begin{array}{l}\frac{\text{d}{y}_1}{\text{d}t}=\frac{r\left(a-b{y}_1\right)}{\rho }\frac{\alpha y_1{y}_2{y}_3{y}_4}{y_1^3+\beta y_1{y}_2{y}_3{y}_4},\\ \frac{\text{d}{y}_2}{\text{d}t}=\rho R_3{y}_1-\frac{\alpha y_1{y}_2{y}_3{y}_4}{y_1^3+\beta y_1{y}_2{y}_3{y}_4},\\ \frac{\text{d}{y}_3}{\text{d}t}=\rho R_5{y}_1-\frac{\mu \alpha y_1{y}_2{y}_3{y}_4}{y_1^3+\beta y_1{y}_2{y}_3{y}_4},\\ \frac{\text{d}{y}_4}{\text{d}t}=\rho R_7{y}_1-\frac{\tau \alpha y_1{y}_2{y}_3{y}_4}{y_1^3+\beta y_1{y}_2{y}_3{y}_4}.\end{array}$ (8)

With the measured data of tomato experiment Table 1, we choose the initial conditions $y_1\left(0\right)=5,y_2\left(0\right)=0.01,y_3\left(0\right)=2,y_4\left(0\right)=2$, and parameter values in the model (8)

$\begin{array}{l}a=200,b=1,r=30,\rho =100,\mu =0.22,\tau =0.29,\alpha =0.08,\beta =1.6,\\ R_3=0.0002,R_5=0.00002,R_7=\mathrm{0.00004.}\end{array}$

Numerical solution of model (8) calculated by Matlab is shown in Figure 2, which reveals that the tomato after the 15th day enters into rapid growth, at this time tomato requires a large amount of fertilizer and the absorption of nutrients by tomato accelerates accordingly. By comparing the curve with the “o” data and simple computation in Figure 2, we get the relative error $\epsilon =0.0023$ which shows that the model has a good fitting effect on the measured data. Therefore, model (8) can be used as a simulation model of tomato growth and development.

4. Two-Compartment Differential Equation Model

According to the facts (F1) and (F3), we consider a two-compartment model, that is, the tomato is made up of roots and leaves and the two parts can transport nutrients to each other (see Figure 3).

Let $W_s,C_s,N_s,Z_n{}_s,W_r,C_r,N_r,Z_n{}_r$ represent the mass of leaf, carbon concentration, nitrogen concentration, zinc concentration and the mass of root, carbon concentration, nitrogen concentration, zinc concentration respectively. A two-compartment model with four equations is established by using one-compartment modeling method. The form of tomato nutrient consumption rate function $f\left(C,N,Z_n\right)$ selected here is still fractional linear, which is the same as (3) in the previous model. We give the equations of leaf weight $W_s$ and root weight $W_r$ as follows

$\frac{\text{d}{W}_s}{\text{d}t}=\frac{r\left(a-b{W}_s\right)W_s}{{\rho }_s}f\left(C_s,N_s,Z_n{}_s\right)$, (9)

$\frac{\text{d}{W}_r}{\text{d}t}=\frac{r\left(a-b{W}_r\right)W_r}{{\rho }_r}f\left(C_r,N_r,Z_n{}_r\right)$. (10)

Suppose that the rate of the carbon being transported from leaf to root is proportional to the difference in carbon concentrations between the two parts, and let the ratio be $R_2$. According to the mass conservation of carbon element, the mass model of carbon element can be obtained,

$\frac{\text{d}\left(W_{s{C}_s}\right)}{\text{d}t}={\rho }_s{R}_3{W}_s\left(t\right)-{\rho }_s{R}_2\left(C_s-C_r\right)-W_{s}f\left(C_s,N_s,Z_n{}_s\right)$. (11)

Assuming the coefficients $R_4$ and $R_6$ similarly, the mass equation models of nitrogen and zinc are obtained,

$\frac{\text{d}\left(W_{r{N}_r}\right)}{\text{d}t}={\rho }_r{R}_5{W}_r\left(t\right)-{\rho }_r{R}_4\left(N_r-N_s\right)-\mu W_{r}f\left(C_r,N_r,Z_n{}_r\right)$. (12)

$\frac{\text{d}\left(W_{r{Z}_n{}_r}\right)}{\text{d}t}={\rho }_r{R}_7{W}_r\left(t\right)-{\rho }_r{R}_6\left(Z_n{}_r-Z_n{}_s\right)-\tau W_{r}f\left(C_r,N_r,Z_n{}_r\right)$. (13)

And the model of nitrogen in leaf organs is as follows

$\frac{\text{d}\left(W_{s{N}_s}\right)}{\text{d}t}={\rho }_s{R}_4\left(N_r-N_s\right)-\mu W_{s}f\left(C_s,N_s,Z_n{}_s\right)$. (14)

The quality model of zinc in leaf organs is as follows

$\frac{\text{d}\left(W_{s{Z}_n{}_s}\right)}{\text{d}t}={\rho }_s{R}_6\left(Z_n{}_r-Z_n{}_s\right)-\tau W_{s}f\left(C_s,N_s,Z_n{}_s\right)$. (15)

The mass model of carbon element in root organs can be obtained from mass conservation

$\frac{\text{d}\left(W_{r{C}_r}\right)}{\text{d}t}={\rho }_r{R}_2\left(C_s-C_r\right)-W_{r}f\left(C_r,N_r,Z_n{}_r\right)$. (16)

Combining (11)-(16), we can obtain a two-compartment differential equation model of carbon, nitrogen and zinc components in growing tomatoes

$\{\begin{array}{l}\frac{\text{d}{W}_s}{\text{d}t}=\frac{r\left(a_s-b{W}_s\right)W_s}{{\rho }_s}f\left(C_s,N_s,Z_n{}_s\right),\\ \frac{\text{d}{W}_r}{\text{d}t}=\frac{r\left(a_r-b{W}_r\right)W_r}{{\rho }_r}f\left(C_r,N_r,Z_n{}_r\right),\\ \frac{\text{d}\left(W_{s{C}_s}\right)}{\text{d}t}={\rho }_s{R}_3{W}_s\left(t\right)-{\rho }_s{R}_2\left(C_s-C_r\right)-W_{s}f\left(C_s,N_s,Z_n{}_s\right),\\ \frac{\text{d}\left(W_{r{C}_r}\right)}{\text{d}t}={\rho }_r{R}_2\left(C_s-C_r\right)-W_{r}f\left(C_r,N_r,Z_n{}_r\right),\\ \frac{\text{d}\left(W_{s{N}_s}\right)}{\text{d}t}={\rho }_s{R}_4\left(N_r-N_s\right)-\mu W_{s}f\left(C_s,N_s,Z_n{}_s\right),\\ \frac{\text{d}\left(W_{r{N}_r}\right)}{\text{d}t}={\rho }_r{R}_5{W}_r\left(t\right)-{\rho }_r{R}_4\left(N_r-N_s\right)-\mu W_{r}f\left(C_r,N_r,Z_n{}_r\right),\\ \frac{\text{d}\left(W_{s{Z}_n{}_s}\right)}{\text{d}t}={\rho }_s{R}_6\left(Z_n{}_r-Z_n{}_s\right)-\tau W_{s}f\left(C_s,N_s,Z_n{}_s\right),\\ \frac{\text{d}\left(W_{r{Z}_n{}_r}\right)}{\text{d}t}={\rho }_r{R}_7{W}_r\left(t\right)-{\rho }_r{R}_6\left(Z_n{}_r-Z_n{}_s\right)-\tau W_{r}f\left(C_r,N_r,Z_n{}_r\right).\end{array}$ (17)

Let

$\begin{array}{l}{y}_1\left(t\right)=W_s\left(t\right),y_3\left(t\right)=W_{s{C}_s}\left(t\right),y_5\left(t\right)=W_{s{N}_s}\left(t\right),y_7\left(t\right)=W_{s{Z}_n{}_s}\left(t\right),\\ y_2\left(t\right)=W_r\left(t\right),y_4\left(t\right)=W_{r{C}_r}\left(t\right),y_6\left(t\right)=W_{r{N}_r}\left(t\right),y_8\left(t\right)=W_{r{Z}_n{}_r}\left(t\right).\end{array}$

Then (17) can be converted into the following ordinary differential equations

$\{\begin{array}{l}\frac{\text{d}{y}_1}{\text{d}t}=\frac{r\left(a_s-b{y}_1\right)}{{\rho }_s}\cdot \frac{\alpha y_1{y}_3{y}_5{y}_7}{y_1^3+\beta y_3{y}_5{y}_7},\\ \frac{\text{d}{y}_2}{\text{d}t}=\frac{r\left(a_r-b{y}_2\right)}{{\rho }_r}\cdot \frac{\alpha y_2{y}_4{y}_6{y}_8}{y_2^3+\beta y_4{y}_6{y}_8},\\ \frac{\text{d}{y}_3}{\text{d}t}={\rho }_s{R}_3{y}_1-{\rho }_s{R}_2\left(\frac{y_3}{y_1}-\frac{y_4}{y_2}\right)-\frac{\alpha y_1{y}_3{y}_5{y}_7}{y_1^3+\beta y_3{y}_5{y}_7},\\ \frac{\text{d}{y}_4}{\text{d}t}={\rho }_r{R}_2\left(\frac{y_3}{y_1}-\frac{y_4}{y_2}\right)-\frac{\alpha y_2{y}_4{y}_6{y}_8}{y_2^3+\beta y_4{y}_6{y}_8},\\ \frac{\text{d}{y}_5}{\text{d}t}={\rho }_s{R}_4\left(\frac{y_6}{y_2}-\frac{y_5}{y_1}\right)-\mu \frac{\alpha y_1{y}_3{y}_5{y}_7}{y_1^3+\beta y_3{y}_5{y}_7},\\ \frac{\text{d}{y}_6}{\text{d}t}={\rho }_r{R}_5{y}_2-{\rho }_r{R}_4\left(\frac{y_6}{y_2}-\frac{y_5}{y_1}\right)-\mu \frac{\alpha y_2{y}_4{y}_6{y}_8}{y_2^3+\beta y_4{y}_6{y}_8},\\ \frac{\text{d}{y}_7}{\text{d}t}={\rho }_s{R}_6\left(\frac{y_8}{y_2}-\frac{y_7}{y_1}\right)-\tau \frac{\alpha y_1{y}_3{y}_5{y}_7}{y_1^3+\beta y_3{y}_5{y}_7},\\ \frac{\text{d}{y}_8}{\text{d}t}={\rho }_r{R}_7{y}_2-{\rho }_r{R}_6\left(\frac{y_8}{y_2}-\frac{y_7}{y_1}\right)-\tau \frac{\alpha y_2{y}_4{y}_6{y}_8}{y_2^3+\beta y_4{y}_6{y}_8}.\end{array}$ (18)

Based on Table 1, for the programming calculation of (18) the initial conditions are taken as follows

$\begin{array}{l}{y}_1\left(0\right)=0.11,y_2\left(0\right)=0.00243,y_3\left(0\right)=0.35,y_4\left(0\right)=0.035,\\ y_5\left(0\right)=0.008,y_6\left(0\right)=0.0378,y_7\left(0\right)=0.05,y_8\left(0\right)=\mathrm{0.058.}\end{array}$

Take the parameter values

$\begin{array}{l}{a}_s=320,a_r=80,b=1,R_2=R_4=0.0003,R_6=0.0006,\\ R_3=R_5=0.002,R_7=0.00004,r=30,{\rho }_s={\rho }_r=100,\\ \mu =0.22,\tau =0.29,\alpha =0.08,\beta =\mathrm{1.6.}\end{array}$

By using Matlab program, the results are obtained in Figure 4, which show that the mass growth of tomato root and leaf organs is slow at the beginning and then becomes faster and faster. In general, the growth of leaf organs is faster than that of root organs, but there was little difference between them in the early stage. The demarcation point is about 15 days, after which the leaf organs begin to grow faster than the root organs. Compared with one-compartment model, two-compartment model shows not only root growth but also leaf growth. So the simulated data values are more consistent with the facts.

5. Conclusion

In this paper, the growth and development of tomato were studied and verified by modeling the differential equation based on nutrients. Based on reasonable assumptions, the law of tomato growth and development and the law of conservation of element mass, the one-compartment model and two-compartment model were constructed, then Matlab was used to simulate the model and the growth curve was obtained. From model (8) and its numerical solution, i.e. Figure 2, we know that the tomato after the 15th day enters into rapid growth, at this time tomato requires a large amount of fertilizer and the absorption of nutrients by tomato accelerates accordingly. From model (18) and its numerical solution, i.e. Figure 4, we know that the mass growth of tomato root and leaf organs is slow at the beginning and then becomes faster and faster. In general, the growth of leaf organs is faster than that of root organs, but there was little difference between them in the early stage. The demarcation point is about 15 days, after which the leaf organs begin to grow faster than the root organs. Through the modeling and analyzing (8) and (18), we have a clear understanding of tomato growth mechanism by using plant nutrients C, N and Zn as variables. This is significant to improve the quantity and quality of tomato production by precise fertilization.

Acknowledgements

This work has been supported by the NNSF of China (Grant No. 11961021), the NSF of Guangdong Province (Grant No. 2022A1515010964), the Innovation and Developing School Project (Grant No. 2019KZDXM032) and the Key Project of Science and Technology Innovation of Guangdong College Students (Grant No. pdjh2021b0309, pdjh2022b0320).

Fund

Science and Technology Planning Project of Zhanjiang (2021A05040).

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References

[1]	Zhang, F.Y., Liu, Y.C., Cai, W., et al. (2018) Effects of Water and Nitrogen Regulation on Tomato Growth and Yield in Solar Greenhouse. China Rural Water and Hydropower, 4, 1-5, 9. (In Chinese)
[2]	Spitters, C., Toussaint, H. and Goudriann, J. (1986) Separating the Diffuse and Component of Global Radiation and Its Implication for Modeling Canopy Photosynthesis Part I: Components of Incoming Radiatio. Agricultural and Forest Meteorology, 38, 217-229. https://doi.org/10.1016/0168-1923(86)90060-2
[3]	Heuvelink, E. (1996) Tomato Growth and Yield: Quantitative Analysis and Synthesis. Ph.D. Thesis, Wageningen Agriculture University, Wageningen.
[4]	Zhou, X.F., Shen, B. and Luo, Z.Y. (1997) Simulation Model of Tomato Growth and Development in Greenhouse and Harm of Cotton Bollworm. Chinese Journal of Research Ecology, 17, 303-310. (In Chinese)
[5]	Zhang, D.K. (1998) Theoretical Model for Predicting the Effect of Nitrogen Fertilizer on Vegetable Yield. Journal of Biomathematics, 13, 118-123. (In Chinese)
[6]	Wang, X.W. (2012) Differential Equation Model for Plant Growth. Journal of Lanzhou Polytechnic University, 19, 59-62. (In Chinese)
[7]	Ji, R.H., Li, X., Qi, L.J. and Wang, J.Q. (2014) Construction and Realization of Three-Dimensional Growth Model of Potted Tomato Root System. Journal of Drainage and Irrigation Machinery Engineering, 9, 795-801. (In Chinese)
[8]	Li, D.S. (2019) Differential Equation Modeling for Plant Growth and Development. Ph.D. Thesis, Yunnan Normal University, Kunming.
[9]	Zhang, L. (2020) Proportional Differential Equation Model of Carbon, Nitrogen and Potassium Requirements for Tomato Growth and Development with Influence of Audio Frequency. Ph.D. Thesis, Yunnan Normal University, Kunming.
[10]	Chatterjee, A., Jesus, A., Goyal, D., Sigdel, S., Cihacek, L., Farmaha, B., Jagadamma, S., Sharma, L. and Long, D. (2020) Temperature Sensitivity of Nitrogen Dynamics of Agricultural Soils of the United States. Open Journal of Soil Science, 10, 298-305. https://doi.org/10.4236/ojss.2020.107016
[11]	Obayomi, A., Ayinde, S. and Ogunmiloro, O. (2019) On Trigonometric Numerical Integrator for Solving First Order Ordinary Differential Equation. Journal of Applied Mathematics and Physics, 7, 2564-2578. https://doi.org/10.4236/jamp.2019.711175
[12]	Song, W.T., Zhang, S.G. and Huang, Z.D. (2003) Cultivation of Tomato Nutrient Solution with Deep Flow and Unlimited Growth (IV) Experimental Study on Cultivation of Tomato by Nutrient Solution with Dynamic Liquid Level. Chinese Agricultural Science Bulletin, 4, 92-95. (In Chinese)