On Trimmed Data Effect in Parameter Estimation of

Some Population Growth Models

Windarto, Eridani and Utami Dyah Purwati

Department of Mathematics, Faculty of Science and Technology, Universitas Airlangga, Surabaya, Indonesia

Kampus C Universitas Airlangga, Mulyorejo, Surabaya 60115, Indonesia

Keywords: Growth Model, Parameter Estimation, Chicken Weight, Trimmed Data.

Abstract: Logistic model, Gompertz model, Richard model, Weibull model and Morgan-Mercer-Flodin model are

commonly used to describe growth model of a population. In this paper, we study the effect of trimmed data

on parameter estimation results of those models. We use chicken weight data cited from literature.

Parameter values of the models from the complete data and the trimmed data are compared. Then, the

sensitivity index of all parameters is evaluated. We found that that sensitivity order of the models from the

highest sensitivity was the Morgan-Mercer-Flodin, Weibull, Richards, logistic and Gompertz growth model.

For practical applications, Gompertz model and Richards are recommended in order to modelling growth of

a population.

1 INTRODUCTION

Mathematical growth models have been widely

applied to explain body weight and age relationship

in veterinary sciences. From the mathematical

growth model, one can evaluate some important and

practical parameters, e.g. the mature weight, the

maturing rate and the growth rate of an animal. The

parameters are beneficial tool to give estimations of

the daily feed needs or to evaluate the effect of

environmental condition on the weight growth of an

animal. In addition, the mathematical growth models

could be applied to forecast the optimum slaughter

age. Therefore, mathematical growth models could

be considered as an optimization instrument for the

animal production (López et al., 2000; Vázquez et

al., 2012; Teleken et al., 2017).

The mathematical growth model could be

classified into two groups, namely empirical growth

models and the empirical growth model and

dynamical growth models (the growth model

derived from ordinary differential equations). The

empirical growth models include Weibull growth

model and MMF (Morgan-Mercer-Flodin) growth

model. The Weibull and the MMF growth model

have been applied to describe chicken growth

dynamic (Topal and Bolukbasi, 2008). The

dynamical growth model includes logistic growth

model, Gompertz growth model, and Richards

growth model. These dynamical growth models have

been used to describe the growth kinetics of many

animals, including chicken (Aggrey, 2002),

mammal (Franco et al., 2011), fish (Santos et al.,

2013), reptile (Bardsley et al., 1995) and

amphibian (Mansano et al., 2013).

Topal and Bolukbasi reported that the MMF,

Weibull and Gompertz the MMF, Weibull and

Gompertz growth model can be useful for describing

chicken growth performance, since these models

were the best fitted models (Topal and Bolukbasi,

2008). Aggrey found that the Richards and

Gompertz growth model have the best fitted model

in explaining rooster and hen growth dynamics

(Aggrey, 2002). Zadeh and Golshani also reported

that the Richards growth model provided the best fit

to the growth curve of Iranian Gulian sheep (Zadeh

and Golshani, 2016).

A mathematical growth model could be said as

a good model if the model give accurately

predicted result and it is robust with trimmed

data. In this context, we compare robustness of

some mathematical growth model due to

trimmed data effect. We use sensitivity index to

measure robustness performance of the models.

We use chicken weight data cited from literature.

This paper is organized as follows. Section 2

briefly presents some mathematical growth models.

Section 3 presents effect of trimmed data on

robustness performance of the selected models.

Finally, conclusions are presented in Section 4.

Windarto, ., Eridani, . and Purwati, U.

On Trimmed Data Effect in Parameter Estimation of Some Population Growth Models.

DOI: 10.5220/0008516300050008

In Proceedings of the International Conference on Mathematics and Islam (ICMIs 2018), pages 5-8

ISBN: 978-989-758-407-7

2 SOME MATHEMATICAL

GROWTH MODELS

In this section, we briefly present some

mathematical growth models including empirical

growth models and dynamical growth models. Let

 represents chicken body weight at time t. The

Weibull and MMF growth model are given by













 













 (1)

and



















 (2)

respectively. Here,  is chicken mature weight,

while are empirical parameters (Topal and

Bolukbasi, 2008).

Logistic growth model is derived from the

following differential equation





  

















 (3)

Here  is per capita growth rate. The logistic growth

model is analytical solution of Eq. (3), which is

given by (Aggrey, 2002; Windarto et al., 2014)



















(4)

where 

















 Here 



is the inflection

time, where at chicken growth is maximum at the

inflection time.

The Gompertz growth model is derived from the

following Gompertz differential equation





 

















 (5)

The exact solution of Eq. (5) represents the

Gompertz growth model. The Gompertz growth

model is given by



















(6)

where 



















The Richards growth model is derived from the

Richards differential equation





   





















 (7)

Here  is the shape parameter in the Richards

differential equation. For =1, then the Richards

differential equation could be simplified into logistic

differential equation. Hence, Richards differential

equation could be considered as an extension of the

logistic differential equation. The exact solution of

the Richards differential equation in Eq. (7) is given













 











(8)

where 



 





























3 EFFECT OF TRIMMED DATA

ON THE ROBUSTNESS

PERFORMANCE

In this section, we study effect of trimmed data on

robustness performance of the growth models

presented in the previous section. We used rooster

weight data cited from literature (Aggrey, 2002;

Windarto et al., 2014). The rooster weight data







at the day







is presented in the Table 1.

Table : Means of the rooster weight data (y)

t (days)

y (grams)

(days)

y (grams)

519.72

41.74

577.27

59.19

633.59

79.94

667.18

102.96

717.17

132.13

786.35

170.18

1069.28

206.56

1326.49

250.71

1589.71

285.27

113

1859.26

324.92

127

2015.44

372.83

141

2142.31

417.41

155

2220.54

469.13

170

2262.63

At the first step, we estimate parameters in the

growth model before trimmed data. We estimate the

parameters such that the mean square error (MSE)

which is given by







 





 













, (9)

ICMIs 2018 - International Conference on Mathematics and Islam

is minimum. Here, 



and 



 are rooster weight data

and predicted rooster weight at the i-th day, while

is number of observation data.

We used Lavenberg-Marquardt algorithm to find

the optimal parameters for the optimization problem

given in Eq. (9). Estimation results of the Weibull,

MMF, logistic, Gompertz and the Richards growth

model for the rooster weight and the mean squared

error of the models are presented in the Table 2.

From the Table 2, we found that the Weibull was the

best models, while the logistic growth model was the

worst model. We also obtained that accuracy of the

Weibull model and the Richards model did not

considerably differ. We also found that mean

squared error of the Richards model and the

Gompertz model did not significantly differ. This

was apparently caused by the shape parameter  in

the Richards model was almost zero.

Table 2: Estimated parameters value for the whole data

Growth

Model

Parameters

Estimated

value

MSE

Weibull

2426.1709

347.743

58.2211

0.000197

1.8699

MMF

67.7095

793.779

14411.3917

2996.0317

2.1030

Logistic

2279.9041

1887.461

0.0403





74.6775

Gompertz

2539.6505

384.666

0.0220





63.4975

Richards

2512.9724

376.277

0.0230





64.3072



0.0541

In order to study the effect of trimmed data, we

also estimated parameters of the models for trimmed

data at the end of the original data (the data from t =

0 until 127 days). We estimated parameters in the

models for the trimmed data. We presented

estimation results for the trimmed data in the Table

3. From the Table 3, we found that the Weibull

model and the MMG model were the best models,

while the logistic growth model was the worst

model. It indicates that the empirical models are

more suit when they are applied in a short data. We

also obtained that accuracy of the Gompertz model

and the Richards model did not considerably differ.

Table 3: Estimated parameters value for the trimmed data

Growth

Model

Parameters

Estimated

value

MSE

Weibull

2992.8983

111.903

41.9675

0.000334

1.6772

MMF

43.5080

139.359

5355.9663

4540.7213

1.7266

Logistic

2132.0511

1708.691

0.0433





70.3077

Gompertz

2694.6160

230.084

0.0206





66.8981

Richards

2694.3571

230.053

0.0206





66.8987



0.0002

In order to measure effect of trimmed data on

robustness performance of the models, we defined a

sensitivity index of all parameters in the model. For

any parameter , we defined the sensitivity index as













 (10)

Here 



is the parameter value after trimmed data

process. Sensitivity index of all parameters was

presented in the Table 4.

From the Table 2 and Table 3, we found that the

mean squared error of the Weibull model and the

MMF model drastically increased due to adding a

few data. From the Table 4, we found that average

value of the sensitivity index varied from 5.94%

until 42.01%. In addition, we found that the shape

parameter  in the Richards model was very

sensitive, while the remaining parameters in the

Richards model were robust. Furthermore, we found

that the Gompertz growth model was a robust model

with respect to trimmed data. We also obtained that

sensitivity index of the empirical model were more

sensitive than the dynamical model studied in this

paper. Hence, we found that the empirical growth

model was more sensitive than the dynamical

growth models. For practical applications, Gompertz

model and Richards are recommended in order to

describing a population growth.

On Trimmed Data Effect in Parameter Estimation of Some Population Growth Models

Table 4: Sensitivity index of all parameters.

Growth

Model

Parameters

Sensitivity

index

Average

value

Weibull

0.2336

0.3278

0.2792

0.6954

0.1031

MMF

0.3574

0.4201

0.6284

0.5156

0.1790

Logistic

0.0649

0.0659

0.0744





0.0585

Gompertz

0.0610

0.0594

0.0636





0.0536

Richards

0.0722

0.3034

0.1049





0.0403



0.9961

4 CONCLUSIONS

We have studied effect of trimmed data on

parameter estimation results of some empirical

models (Weibull and Morgan-Mercer-Flodin) and

some dynamical models (logistic, Gompertz and

Richards growth model). We found that the

empirical models were more sensitive than the

dynamical models. We also found that the

dynamical models were more robust with respect to

trimmed data. For practical applications, Gompertz

model and Richards are recommended in order to

modeling growth of a population.

ACKNOWLEDGEMENTS

Part of this research was supported by Ministry of

Research, Technology and Higher Education,

Republic of Indonesia through “Penelitian Unggulan

Perguruan Tinggi” research project.

REFERENCES

Aggrey, S. E., 2002. Comparison of three nonlinear and

spline regression models for describing chicken

growth curves. Poultry Science 81(12):1782-1788.

Bardsley, W. G., Ackerman, R. A., Bukhari, N.A.,

Deeming, D.C., Ferguson, M. W., 1995.

Mathematical models for growth in alligator

(Alligator mississippiensis) embryos developing at

different incubation temperatures. Journal of

Anatomy 187(1):181-190.

Franco, D., García, A., Vázquez, J. A., Fernández, M.,

Carril, J.A., Lorenzo, J.M., 2011. Curva de

crecimiento de la raza cerco celta (subrariedad

barcina) a diferentes edades de sacrifício. Actas

Iberoamericanas de Conservacíon Animal 1(1): 259-

263.

López, S., France, J., Gerrits, W. J., Dhanoa, M.S.,

Humphries, D.J., Dikstra, J., 2000. A generalized

Michaelis-Menten equation for analysis of growth.

Journal of Animal Science 78(7): 1816-182.

Mansano, C. F. M., Stéfani, M. V., Pereira, M. M.,

Macente, B. I., 2013. Deposição de nutrientes na

carcaça de girinos de rã-touro. Pesquisa

Agropecuária Brasileira 48(8): 885-891.

Santos, V. B., Mareco, E. A., Silva, M. D. P., 2013. Growth

curves of Nile tilapia (oreochromis niloticus)

strains cultivated at different temperatures. Acta

Scientiarum Animal Sciences 35(3):235-242.

Teleken, J. T., Galvã, A. C., Robazza, W. D. S., 2017.

Comparing non-linear mathematical models to

describe growth of different animals. Acta

Scientiarum 39: 73-81.

Topal, M., Bolukbasi, S. D., 2008. Comparison of

nonlinear growth curve models in broiler chicken.

Journal of Applied Animal Research 34(2):149-152.

Vázquez, J. A., Lorenzo, J. M., Fuciños, P., Franco, D.,

2012. Evaluation of non-linear equations to model

different animal growths with mono and bisigmoid

profiles. Journal of Theoretical Biology 314(7): 95-

105.

Windarto, Indratno, S. W., Nuraini, N., Soewono, E.,

2014. A comparison of binary and continuous genetic

algorithm in parameter estimation of a logistic

growth model. AIP Conference

Proceedings1587:139–142. 2014.

Zadeh, N. G. H, Golshani, M., 2016. Comparison of non-

linear models to describe growth of Iranian Guilan

sheep. Revista Colombiana de Ciencias Pecuarias

29(3):199-209.

ICMIs 2018 - International Conference on Mathematics and Islam