Abstract

Aiming to improve the current models describing the diffusion of innovation, a method based on an analogy with a physical system is presented. In particular, we model the movement of adopters of a particular innovation as a flow and the diffusion of the innovation as heat diffusion, thus making use of mathematical tools such as the Navier-Stokes equation. Building on our previous work, in this study we focus on the movement of adopters in the simulation domain, which we refer to as convection. As an application to modeling the convection phenomenon, we simulate the flow of people in a real building floor, the Tokyo Aquarium. Besides being a necessary part when simulating diffusion of innovations, such a modeling approach may also prove useful in different fields, such as deciding layout of public spaces or evacuation policies.

1. Introduction

The spread of information in general and, in particular, the diffusion of various innovations are strongly influenced by the movement of people. Although the movement of each particular individual is dictated by complex rules, at a macrolevel it is possible to consider the collective movement of large numbers of people (crowds of people) as continuous and model it as a type of flow. Such flows have been previously considered in the literature and the relations between crowd velocities, flow rates, and densities have been studied in crowded places as commuter stations [1].

Flows of people, with characteristics strongly influenced by the structure of the particular domain the flow takes place in (e.g., office building, public places) are important for a number of reasons. From an economical point of view, they spawn economic activity in the region, as various entrepreneurs compete for high-visibility spots to sell their merchandise. From a social point of view, they are the main places where information is disseminated. From a safety point of view, they are potentially dangerous places where accidents or panic can result in mass injury and loss of life. Because of this, flows of crowds have been analyzed using both continuous and discrete formulations [2–6].

Our purpose is to elucidate the spatial spread of innovations by means of a physical analogy with the phenomenon of heat diffusion. This builds on our previous work, where we have modeled the diffusion of innovation [7] making use of various data such as population density or the economic situation. In the innovation diffusion phenomenon, we define three main ways by which an innovation can propagate among the members of a population. This is achieved via an analogy with the phenomenon of heat propagation through some medium, which can take place in three different modes: heat transfer (when heat is transferred through a solid, a stationary liquid, or a vaporous medium), heat convection (when heat is conveyed by the movement of particles in a liquid or a vaporous medium), and heat radiation (when heat is transferred between two disconnected media).

In this paper, we concentrate on modeling the movement of adopters in a continuous way, using mathematical tools such as the Navier-Stokes equation. After introducing the theoretical aspects of our model, we perform a real simulation by modeling the flow of people in the Tokyo Aquarium.

2. Definition

2.1. Adoption Ratio

In order to calculate the number of accumulated adopters by employing the relevant equations, the value of each variable in those equations must be continuous in the domain. However, this is usually not true for the number of potential adopters, as it depends on the population in the respective region of the domain. The number of adopters should therefore be substituted with a continuous average value. The level of saturation with respect to the diffusion of an innovation, after a given period of time, will vary between the nodes of the domain mesh (segmented domain). This is often the result of differences in innovation adoption between a region with a large population and a region with a small population. The diffusion equation is not capable of capturing this aspect of diffusion, with the exception of the defined boundary conditions. That is, the saturation values of different nodes over the computational domain equalize over time, according the diffusion equation. To overcome this problem, we introduce the concept of adoption ratio, defined as follows:𝑀𝑁=𝐺,(2.1) where 𝑁 and 𝑀 denote the adoption ratio and the number of the accumulated adopters, respectively. The adoption ratio is distributed over space. After enough time has passed, the adoption ratio becomes 𝑁=1 over the entire computational domain. This adoption ratio is intended to be similar to the distribution of temperature over a medium in the transfer of heat. In natural sciences, temperature is considered a macroscale (or statistical) value. When a microscale region is observed, a small set of molecules would be considered. In this context, the temperature becomes statistically unstable (unreflective of the larger medium) and has little meaning. In addition, it would be effectively impossible to observe the motion of numerous molecules, independently, in tandem using available measurement equipment. In social science, the adoption ratio is also a macroscale (or statistical) value. In the microdomain, in which only a few potential adopters are considered, this value similarly becomes statistically unstable and thus has little meaning. As a result of the associated increase in computational costs, as observed with the agent models [8, 9], the computation necessary to capture the movement of numerous independent adopters in real time is effectively impossible.

2.2. Density of Potential Adopters

It is assumed that the set of potential adopters, 𝐺𝑖, lives within an area 𝐴𝑖. The density of the number of potential adopter is therefore defined as follows:πœŒπ‘–=𝐺𝑖𝐴𝑖(𝑖=1,2,…,𝑛).(2.2) This parameter is defined as a constant and is distributed over the computational domain according to the domain segmentation (index 𝑖). The index of parameter 𝜌 will coincide with the indices of 𝐺 and 𝐴.

2.3. Pressure

In areas such as crowded public spaces, direct physical interaction between people is generally unavoidable. In large crowds, there is a potential for injury and even loss of life, resulting from the dynamics of the crowd’s behavior. Using the standard forward-backward autoregressive modeling approach for spectral analysis of a measured signal, predictions of pressures generated by very high densities of pedestrians have been formulated [10]. In this study, pressure is defined in a similar way. Basically, it is assumed that two persons A and B found in close contact will fill uncomfortable and thus try to move away from each other.

2.4. Viscosity

In the same way as we defined the pressure as a repulsive force, where people try to avoid and move away from close contacts, we also define an attractive force, where groups of people try to keep moving together. One possible reason for such behavior is friends, family members, or tour groups trying to keep together. This also prevents groups of people from mixing. In this study, this effect, similar to the viscosity in a fluid, is defined as viscosity.

3. Theory

3.1. Innovation Convection Based on Navier Stokes Equation

Figure 1 shows an infinitesimal element of width 𝑑π‘₯ and the height 𝑑𝑦 in the flow of people. The speed of movement with respect to the π‘₯-axis and the 𝑦-axis are denoted 𝑒 and 𝑣, respectively. In the π‘₯ axis, the change with respect to time in the number of people found in the infinitesimal element must equal the difference between the number of people coming in and the number of people going out. This fact is described in the equation below: ξ‚ΈπœŒπ‘’π‘‘π‘¦βˆ’πœŒπ‘’+πœ•(πœŒπ‘’)ξ‚Ήπœ•π‘₯𝑑π‘₯𝑑𝑦=βˆ’πœ•(πœŒπ‘’)πœ•π‘₯𝑑π‘₯𝑑𝑦.(3.1)


Figure 1 
Flow of people in the infinitesimal element.

Similarly, for the 𝑦 direction we haveξ‚ΈπœŒπ‘£π‘‘π‘₯βˆ’πœŒπ‘£+πœ•(πœŒπ‘£)ξ‚Ήπœ•π‘¦π‘‘π‘¦π‘‘π‘₯=βˆ’πœ•(πœŒπ‘£)πœ•π‘¦π‘‘π‘₯𝑑𝑦.(3.2)

The number of peoples (πœŒπ‘‘π‘₯𝑑𝑦) in the infinitesimal element increases by an amount of πœ•(πœŒπ‘‘π‘₯𝑑𝑦)/πœ•π‘‘. The equation is as follows:βˆ’πœ•(πœŒπ‘’)πœ•π‘₯𝑑π‘₯π‘‘π‘¦βˆ’πœ•(πœŒπ‘£)πœ•π‘¦π‘‘π‘₯𝑑𝑦=πœ•(πœŒπ‘‘π‘₯𝑑𝑦),πœ•π‘‘πœ•πœŒ+πœ•πœ•π‘‘(πœŒπ‘’)+πœ•πœ•π‘₯(πœŒπ‘£)πœ•π‘₯=0.(3.3)

Newton's second law is applied to the infinitesimal element as shown in Figure 1. The forces acting on the infinitesimal element are denoted by 𝐹π‘₯ and 𝐹𝑦 with respect to the π‘₯ direction and the 𝑦 direction, respectively. From the equilibrium of forces, the following equations are obtained:πœŒπ‘‘π‘₯𝑑𝑦𝑑𝑒𝑑𝑑=𝐹π‘₯,πœŒπ‘‘π‘₯𝑑𝑦𝑑𝑣𝑑𝑑=𝐹𝑦.(3.4)

The change of the velocity occurs both the time and the space. The velocity 𝑑𝑒 with respect to the time 𝑑𝑑 is as follows:𝑑𝑒=πœ•π‘’πœ•π‘‘π‘‘π‘‘+πœ•π‘’πœ•π‘₯𝑑π‘₯+πœ•π‘’πœ•π‘¦π‘‘π‘¦.(3.5) Equation (3.5) is transformed as follows:𝑑𝑒=π‘‘π‘‘πœ•π‘’+πœ•π‘‘πœ•π‘’πœ•π‘₯𝑑π‘₯+π‘‘π‘‘πœ•π‘’πœ•π‘¦π‘‘π‘¦=π‘‘π‘‘πœ•π‘’πœ•π‘‘+π‘’πœ•π‘’πœ•π‘₯+π‘£πœ•π‘’πœ•π‘¦.(3.6) Using (3.6), and so forth, (3.4) are as follows:πœŒξ‚΅πœ•π‘’πœ•π‘‘+π‘’πœ•π‘’πœ•π‘₯+π‘£πœ•π‘’ξ‚Άπœ•π‘¦π‘‘π‘₯𝑑𝑦=𝐹π‘₯,πœŒξ‚΅πœ•π‘£πœ•π‘‘+π‘’πœ•π‘£πœ•π‘₯+π‘£πœ•π‘£ξ‚Άπœ•π‘¦π‘‘π‘₯𝑑𝑦=𝐹𝑦.(3.7)

The friction 𝐹 is assumed to be consist of the pressure term 𝑃 and the viscosity term 𝑆. These equations are as follows:𝐹π‘₯=𝑃π‘₯+𝑆π‘₯,𝐹𝑦=𝑃𝑦+𝑆𝑦(3.8) The pressure (𝑝π‘₯,𝑝𝑦) is obtained as follows:γ€€ 𝑃π‘₯ξ‚΅=π‘π‘‘π‘¦βˆ’π‘+πœ•π‘ξ‚Άπœ•π‘₯𝑑π‘₯𝑑𝑦=βˆ’πœ•π‘π‘ƒπœ•π‘₯𝑑π‘₯𝑑𝑦,(3.9)𝑦=𝑝𝑑π‘₯βˆ’π‘+πœ•π‘ξ‚Άπœ•π‘¦π‘‘π‘¦π‘‘π‘₯=βˆ’πœ•π‘πœ•π‘¦π‘‘π‘₯𝑑𝑦.(3.10) The viscosity (𝑆π‘₯,𝑆𝑦) is obtained as follows:γ€€ 𝑆π‘₯πœ•=πœ‡ξ‚€πœ•π‘₯πœ•π‘’+πœ•π‘₯πœ•π‘’ξ‚πœ•πœ•π‘₯𝑑π‘₯𝑑𝑦+πœ‡ξ‚΅πœ•π‘¦πœ•π‘’+πœ•π‘¦πœ•π‘£ξ‚Άπ‘†πœ•π‘₯𝑑π‘₯𝑑𝑦,(3.11)π‘¦πœ•=πœ‡ξ‚΅πœ•π‘₯πœ•π‘£+πœ•π‘₯πœ•π‘’ξ‚Άπœ•πœ•π‘¦π‘‘π‘₯𝑑𝑦+πœ‡ξ‚΅πœ•π‘¦πœ•π‘£+πœ•π‘¦πœ•π‘£ξ‚Άπœ•π‘¦π‘‘π‘₯𝑑𝑦.(3.12) Using (3.9)–(3.12) and (3.7), (3.8) are as follows:πœŒξ‚΅πœ•π‘’πœ•π‘‘+π‘’πœ•π‘’πœ•π‘₯+π‘£πœ•π‘’ξ‚Άπœ•π‘¦=βˆ’πœ•π‘πœ•πœ•π‘₯+πœ‡ξ‚€πœ•π‘₯πœ•π‘’+πœ•π‘₯πœ•π‘’ξ‚πœ•πœ•π‘₯+πœ‡ξ‚΅πœ•π‘¦πœ•π‘’+πœ•π‘¦πœ•π‘£ξ‚Ά,πœŒξ‚΅πœ•π‘₯πœ•π‘£πœ•π‘‘+π‘’πœ•π‘£πœ•π‘₯+π‘£πœ•π‘£ξ‚Άπœ•π‘¦=βˆ’πœ•π‘πœ•πœ•π‘¦+πœ‡ξ‚΅πœ•π‘₯πœ•π‘£+πœ•π‘₯πœ•π‘’ξ‚Άπœ•πœ•π‘¦+πœ‡ξ‚΅πœ•π‘¦πœ•π‘£+πœ•π‘¦πœ•π‘£ξ‚Ά.πœ•π‘¦(3.13)

3.2. Innovation Convection Based on Energy Equation

In the previous section the flow of people in an infinitesimal element is described based on the Navier Stokes equation. These people are both adopters and nonadopters of the innovation being studied. In this study, the number of adopters found in the flow is called the innovation energy [11, 12]. As shown in Figure 2, the inflow of adopters from the left side in the infinitesimal element represents the variable 𝑄𝑀. The variable 𝑄𝑀 consists of the innovation convection 𝑄𝑀1 and the innovation transfer 𝑄𝑀2. This equation is as follows:𝑄𝑀=𝑄𝑀1+𝑄𝑀2.(3.14) The variable 𝑄𝑀1 on the left side in Figure 2 is as follows:𝑄𝑀1=πœŒπ‘π‘’π‘π‘‘π‘¦,(3.15) where the variable ``𝑐'' shows the ratio of the adopter capacity. This variable shows the number of adopters needed to increase the adopter ratio (𝑁) by 1.0% [11]. The number of adopter 𝑄𝑀2 is as follows:𝑄𝑀2=βˆ’πœ†πœ•π‘πœ•π‘₯𝑑𝑦,(3.16) where the variable πœ† is called innovation diffusivity [11]. This parameter reflects the number of interactions between potential adopters and existing adopters. Similarly, the number of outflow adopters 𝑄𝑒 on the right side is as follows:𝑄𝑒=𝑄𝑒1+𝑄𝑒2=ξ‚ƒπœ•πœŒπ‘π‘’π‘+ξ‚„ξ‚žπœ•π‘₯(πœŒπ‘π‘’π‘)𝑑π‘₯𝑑𝑦+βˆ’πœ†πœ•π‘+πœ•πœ•π‘₯ξ‚€πœ•π‘₯βˆ’πœ†πœ•π‘ξ‚ξ‚Ÿπœ•π‘₯𝑑π‘₯𝑑𝑦.(3.17) Similarly, the number of inflow adopters 𝑄𝑠 on the bottom side is as follows:𝑄𝑠=𝑄𝑠1+𝑄𝑠2=ξ‚ΈπœŒπ‘π‘£π‘βˆ’πœ†πœ•π‘ξ‚Ήπœ•π‘¦π‘‘π‘₯(3.18) while the number of outflow adopters 𝑄𝑛 on the upper side is as follows:𝑄𝑛=𝑄𝑛1+𝑄𝑛2=ξ‚Έπœ•πœŒπ‘π‘£π‘+ξ‚Ήξ‚Έπœ•π‘¦(πœŒπ‘π‘£π‘)𝑑𝑦𝑑π‘₯+βˆ’πœ†πœ•π‘+πœ•πœ•π‘¦ξ‚΅πœ•π‘¦βˆ’πœ†πœ•π‘ξ‚Άξ‚Ήπœ•π‘¦π‘‘π‘¦π‘‘π‘₯.(3.19)


Figure 2 
Adopter flow in infinitesimal element. (Energy of innovation diffusion is defined as the number of accumulated adopters.)

In the steady state, the number of inflow adopters should be equal to the number of outflow adopters. Therefore, it is as follows:π‘„π‘€βˆ’π‘„π‘’+π‘„π‘ βˆ’π‘„π‘›=0.(3.20) Using (3.15)–(3.19), (3.20) is as follows:π‘’πœ•π‘πœ•π‘₯+π‘£πœ•π‘=πœ†πœ•π‘¦ξ‚΅πœ•πœŒπ‘2π‘πœ•π‘₯2+πœ•2π‘πœ•π‘¦2ξ‚Ά.(3.21)

The left side of (3.21) and the right side become the innovation convective term and the innovation transfer term, respectively. In the unsteady state with respect to time, the time-derivative term is added in (3.21):πœ•π‘πœ•π‘‘+π‘’πœ•π‘πœ•π‘₯+π‘£πœ•π‘=πœ†πœ•π‘¦ξ‚΅πœ•πœŒπ‘2π‘πœ•π‘₯2+πœ•2π‘πœ•π‘¦2ξ‚Ά.(3.22) In case the flow of adopters does not occur in the infinitesimal element (𝑒=0 and 𝑣=0), the innovation diffusion equation is obtained [11, 12]. The number of adopters in the infinitesimal element can also increase via social factors (e.g., imitation), so a Bass model term [13] is added in (3.22) as follows:πœ•π‘πœ•π‘‘+π‘’πœ•π‘πœ•π‘₯+π‘£πœ•π‘=πœ†πœ•π‘¦ξ‚΅πœ•πœŒπ‘2π‘πœ•π‘₯2+πœ•2π‘πœ•π‘¦2ξ‚Ά+π‘ˆ(1βˆ’π‘)+𝑉𝑁(1βˆ’π‘),(3.23) where π‘ˆ and 𝑉 represent the innovation and imitation coefficients [13].

4. Modeling Crowd Movement

Modeling the movement of crowds is an important aspect of the previously presented innovation diffusion model. In the same way as heat can be transported by a flow field, a particular innovation can spread due to the movement of adopters. However, there are different applications for such models as well. For example, modeling the movements of people in crowded public spaces may provide insight into ways of streamlining them or to design or test efficient evacuation procedure. In this section we perform such a simulation in which we model the movement of people into the crowded space of the Tokyo Tower Aquarium [14] by making use of the Navier-stokes equations: (3.13).

4.1. Computing Model and Conditions

The computational domain, shown in Figure 3, was created according to the building schematics. The total area of the floor is 76 m2. People move from the entrance (bottom left) to the exit (bottom right).


Figure 3 
Floor Map of Tokyo Tower Aquarium [14].

At the entrance, the velocity is assumed to be 1.0 (m/s) and that people continuously enter into the floor and that they will continue their movement until leaving the domain through the exit. The calculation condition on the exit is set as 𝑃=0, that is, there is nothing blocking the exit. It is further assumed that there is no movement in the immediate vicinity of the walls (the boundary condition on the wall is set to 𝑒=0). The viscosity effect is defined as 𝜈=1 (m2/s). The system is solved using the Finite Element Method, with the domain being discretized using a triangular mesh (the number of nodes and of elements is 951 and 1652, resp.). The mesh is shown in Figure 4.


Figure 4 
Mesh of Tokyo Tower Aquarium.
4.2. Resulting Flow Field

Figure 5 shows the flow of people, according to the Navier-Stokes equations (3.13), after a steady state has been obtained. The arrows show the direction of the flow while the color indicates the walking velocity (red indicates fast movements while blue represents slow movement).


Figure 5 
Adopter flow in Tokyo Tower Aquarium (calculated by (3.13)).

5. Conclusions

In this paper the Navier-Stokes equation and an analogy with heat diffusion are used to model the diffusion of innovations. In particular, we have focused on the phenomenon of innovation convection, the movement of adopters throughout the domain. This builds on our previous work in this field, where we have only considered domains in which adopters where fixed in space.

After introducing the theoretical aspects, we have shown a numerical example consisting of a finite element analysis of the flow of people in a public space (the Tokyo Aquarium). The result of such a simulation can be used in two ways. First, one can consider these people as potential adopters and model innovation diffusion on top of this flow. In this way the innovation will not only spread in the regular (Bass-model like) way, as usually considered in the literature, but it would also be influenced by the movement of the adopters throughout the domain. As time passes, the innovations are transmitted in the same way as heat (energy) is conveyed by a water flow. In future work, we aim to combine the diffusion models proposed in out previous work with the innovation convection model explored here to perform more complex innovation diffusion simulations.

Second, without relation to innovation diffusion, such results can be used to find important spots (e.g., bottlenecks) in the design of the building and to find ways to streamline the flow of people through it. Such designs could reduce congestion and result in safer and more efficient public spaces.