**Applied Mathematics**

Vol.06 No.08(2015), Article ID:57844,5 pages

10.4236/am.2015.68112

Liquor Habit Transmission Model

Nita H. Shah^{1}, Bijal M. Yeolekar^{1}, Nehal J. Shukla^{2}

^{1}Department of Mathematics, Gujarat University, Ahmedabad, India

^{2}Department of Mathematics, Columbus State University, Columbus, USA

Email: nitahshah@gmail.com, bijalyeolekar28@gmail.com, shukla_nehal@columbusstate.edu

Copyright © 2015 by authors and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY).

Received 28 May 2015; accepted 7 July 2015; published 10 July 2015

ABSTRACT

In this paper, we analyse population dynamics of liquor habit. Liquor free and Liquor endemic equilibrium are computed. The local and global stabilities of the proposed problem are established. The numerical simulation is given to validate the transmission of population indifferent compartment using state-space model.

**Keywords:**

Liquor Habit, Basic Reproduction Number, Local Stability, Global Stability, State-Space Simulation

1. Introduction

The Ayurvedas depicted that the alcohol behave as a medicine if it is taken for the purpose of meditation otherwise it behave as a poison if it is taken in addiction manner for the humans. The liquor habits reflect person’s social status and cultural prestige. It is observed that transmission of liquoring spreads frequently these days due to availability of the liquor in the market. There is a similarity between spread of infectious disease and liquor habits. In other words, liquor habit can be treated as a virus which transmits among the compartments by social pressure like parties with friends, peers and executive meetings.

In this paper, we analyze quantitative model of a liquor habit transmission in a population similar to SEIR- model. The notations are described in Section 2. The mathematical model and basic reproduction number are formulated in Section 3. The local and global stability are derived in Sections 3.2.1 and 3.2.2 respectively. Numerical simulations are illustrated in Section 4 using State-Space model. Discussions and conclusions are given in Section 5.

2. Notations

The model is derived using following notations.

3. Mathematical Model

Anybody in the population is susceptible to liquor. In general, one starts taking pegs and increases it gradually. The consumption of two pegs is considered as a normal which falls in E-compartment. The work stress, financial stress, and many more factors to go for more than two pegs which fall under I-compartment. Certain fraction of population from E- and I-compartments may be removed. It is taken as R-compartment. Thus, it resembles toSEIR-model.

Let us call and R the portion of total population of each class. Now, we make SEIR-model with some assumptions. The portion of liquored person’s who increases liquor habit at a rate proportional to with. So, the portion of liquored will decrease with the some rate. Here, is called the effective liquoring rate. The portion of liquor person’s starting liquoring habit with a rate (progression rate) with and with. The portion of excessive liquored with the rate c with. The portion of removing liquor habit with the rate with and with. See the transfer diagram given in Figure 1.

From Figure 1, the model is formulated as following system of differential equations.

(1)

Figure 1. Transfer diagram.

Since, an epidemic model occurs in a short time period, we ignore moving portion of removal from liquor. So, we will analyze the first three equations forming new reduced system

(2)

Adding all these three equations, we have

Which gives,.

Therefore, the feasible region for (2) is

.

Now, the basic reproduction number will be found by using the next generation matrix. It is easy to see that (2) always has a liquor free equilibrium.

Let, where dash denotes derivative. So that

where denotes the rate of appearance of new liquored in compartment and represents the rate of transfer of liquors, which is given as

F and V are matrices defined as

.

So

where V is non-singular matrix, so that

(3)

Hence, the basic reproduction number is

= spectral radius of matrix.

(4)

Next, we need to discuss equilibrium of the liquor habit system.

3.1. Equilibrium

The liquor free equilibrium is locally asymptotically stable if all the eigenvalues of the matrix have positive real values (Al-Amoudi et al. (2014) [1] ).

Theorem 1 (Johnson (2004) [2] ): Consider the liquor transmission model given by (2) with. If is a liquor free equilibrium of the model, then is locally asymptotically stable if, and unstable if, where is given by (4).

Proof Let. Since V is a non-singular matrix and F is non-negative,

Thus has the Z-sign pattern.

Û isa non-singular matrix.{ is spectral abscissa of j}

Since is non-negative, also has the Z-sign pattern.

Then, we have is a non-singular matrix Û is a non-singular matrix.

Finally, since is non-negative, all eigenvalues of have magnitude less than or equal to.

Thus, is a non-singular matrix Û.

Hence, if and only if.

Similarly, it follows that Û is a singular matrix.

Û is a singular matrix.

Û.

Hence, if and only if.

It follows that if and only if.

3.2. Stability of the Equilibrium

3.2.1. Local Stability

The liquor free equilibrium is stable if all the eigenvalues of the Jacobian matrix of the system (1) have negative real parts. For this, the Jacobian of the system (1) at takes the form

Here.

3.2.2. Global Stability

The liquor free equilibrium is globally stable if.

where.

4. Numerical Simulation

In this section, we perform numerical simulation of the system (1) using with the state-space model.

State-Space Model

State equation

Output equation where u-input, y-output, x-state vector.

The general state-space description for a linear time invariant, continuous time dynamical system is

where are matrices,. Using this state-space model, we find the solution of the system (1). Taking data as follows:

in and

We carry out the simulation. The results are shown in Figure 2.

5. Discussion and Conclusions

From Figure 2(a), it is observe that 11% of the population from the susceptible compartment start liquoring exponentially in first five weeks. Liquoring habit in the susceptible class is small initially but thereafter it increases exponentially. Figure 2(b) is about those who are taking two or less than two pegs in 10 weeks which shows uniform increase, while 44% of the population is getting liquored in infectious class (Figure 2(c)). It is observed

Figure 2. (a) Susceptible vs weeks; (b) Expose vs weeks; (c) Infectious vs weeks; (d) Removal vs weeks.

that more than two pegs are taken immediately after 3^{rd} week and increases exponentially. Almost 15% gets chain liquor (those who can’t survive without liquor). The removal compartment (Figure 2(d)), 44% enters either into less than two pegs i.e. E-compartment or into never liquor that is S-compartment.

In this paper, a nonlinear mathematical model for liquor transmission is analysed. The local and global stability of the liquor free equilibrium point are established. It is proved that the free equilibrium is locally asymptotically stable when basic reproduction number and global stability of liquor transform.

This model can be extended by educating youth for non-liquoring via advertisement, rehabilitation centre etc.

Acknowledgements

The first author thanks DST-FIST file # MSI-097 for technical support.

Cite this paper

Nita H.Shah,Bijal M.Yeolekar,Nehal J.Shukla, (2015) Liquor Habit Transmission Model. *Applied Mathematics*,**06**,1208-1213. doi: 10.4236/am.2015.68112

References

- 1. Al-Amoudi, R., Al-Sheikh, S. and Al-Tuwairqi, S. (2014) Behavior of Solutions to a Mathematical Model of Memes Transmission. International Journal of Applied Mathematical Research, 3, 36-44.
- 2. Johnson, L. (2004) An Introduction to the Mathematics of HIV/AIDS Modelling. Centre for Actuarial Research.