## Abstract

The inner dynamics of the multiple actors of the informations systems – i.e, T.V., newspapers, blogs, social network platforms, – play a fundamental role on the evolution of the public opinion. Coherently with the recent history of the information system (from few main stream media to the massive diffusion of socio-technical system), in this work we investigate how main stream media signed interaction might shape the opinion space. In particular we focus on how different size (in the number of media) and interaction patterns of the information system may affect collective debates and thus the opinions' distribution. We introduce a sophisticated computational model of opinion dynamics which accounts for the coexistence of media and gossip as separated mechanisms and for their feedback loops. The model accounts also for the effect of the media communication patterns by considering both the simple case where each medium mimics the behavior of the most successful one (to maximize the audience) and the case where there is polarization and thus competition among media memes. We show that plurality and competition within information sources lead to stable configurations where several and distant *cultures* coexist.

## Introduction

Nowadays, there is an ongoing intense scientific debate around the definition of the foundational concepts as well as about the most appropriate methodological approaches to deal with the understanding of social dynamics^{1,2}. However, the challenge of understanding human behavior remains complex and intricate. Humans are intentional (and not necessarily rational) and the their dynamics in the social space are influenced by the surrounding social context and by the information reported on the media. Tv, newspapers, blogs act on the *memetic* diffusion which, in turn, is affected by a massive amount of individual and social factors – e.g. tastes, desires, goals, trust, social pressure etc. To understand such mechanisms we have to consider several factors from how information is produced, up to how the various information sources interact within them (and with respect to the audience).

Media industries are influenced by business concentration and market segmentation, leading toward heightened oligopolistic competition, customized delivery of messages, and vertical networking of the multimedia industry^{3,4,5}.

In the traditional theory of political communication political influence through the media is largely determined by the interaction between the political elites (in their plurality) and professional journalists. Media act as gatekeepers of the information flows that shape public opinion^{6} then resulting in collective debates for the formation of the public opinion.

The recent transformation of the media environment results mainly in the fragmentation of the audience, and the increasing control that new communication technologies give to the consumers of the media^{7,8}.

Since such an interaction manifests in terms of production and selection of the proposed contents, we introduce a novel model of opinion dynamics on coupled and interacting networks. We stress the role of the media communication strategies by considering both the simple case where each media mimics the behavior of the most successful one – to maximize the audience – and the case where there is polarization and thus competition among media reported information – to preserve and satisfy the segmented audience and to follow the editorial line.

The increasingly massive use of Internet as a source of information and as a medium of communication has led to a shift of paradigm in the production/diffusion of contents as well as in the communication process. The debate about social relevant issues spreads and persists over the web by leading to the emergence of unprecedented social phenomena such as the massive recruitment of people around common interests, ideas or political visions^{9,10,11,12}. In the past years an intensive research effort has been payed in understanding social phenomena from innovation diffusion, to social influence, up to opinions and their dynamics^{13,14,15,16,17,18,19,20,21,22,23}; some of them have focused on the role of media^{24,25,26,27,28,29,30,31} and of the web^{32,33}.

The interaction among media, with the advent of the WWW, has been subject to an important change: people are not passive anymore, but can be proactive to an extent that often main stream media acquire information directly by common people. Main stream media compete for the audience and therefore interact by adjusting their format/contents to collect the highest number of followers. Hence, if on the one hand people get informed by the media, on the other hand the information (as well as the way they are reported) are even more influenced by the evolution of the mass tastes. Media respond to the their editors which often are politically lined up and then we can have the emergence of monopoles (as in the case of regimes) or to *polarized groups* (as in the modern democracies) of information broadcasters aiming at influencing people toward one or another political party^{24,34}. The aim of this work is a) to introduce in the field of opinion dynamics the role of the media dynamics as a results of a competition/imitation process which has the goal to reach the highest number of followers; b) to highlight the changes induced by the historical evolution of the information system from the traditional main stream media to the WWW and c) to study the effect of aggregation/fragmentation of opinions in mixed communication environment.

Since we want to stress the role of trust with respect to information available to an individual, we assume that the gossipers interact with their neighbors and with the media using the *bounded confidence model* (BCM)^{35} – i.e, only if the distance between their internal state (opinion) and the received information is below a given threshold *σ* (tolerance) they will be more likely to adjust their own opinion. The higher the tolerance, the more the people are likely to be influenced by (because they trust) the information circulating^{14,36,37}.

On the other hand, the media aim to reach the highest number of followers, hence they change their message according to the attitude of the media with the highest number of followers. Finally, we introduce competition among media memes^{38,39} – i.e., we mark the edges between media with positive and negative values causing respectively to converge or diverge respect to their neighbor's attitudes. We show plurality and competition within the various information sources leads to stable configurations where several and distant *cultures* coexist coherently to the impressive multitude of debates occurring on socio-technical systems about different topics – e.g politics, economics or the he existence of chemical trails and reptilians, the new world order conspiracy and so forth).

## Model

We model the information system and its inner dynamics on two different scenarios inspired by the shift of paradigm from the main stream media (when every medium knows about the format of all the others) and to the more recent advent of the socio-technical systems such as Facebook and Twitter (with more complicated connectivity patterns). The model accounts also for the effect of media communication patterns by considering both the simple case where each medium mimics the behavior of the most successful one (to maximize the audience) and the case where there is polarization and thus competition among media memes (to preserve their audience). Hence, the model discussed in this paper relies on two interacting networks: the media, which have the goal to collect the highest number of followers, and the gossipers, which can acquire information both from other gossipers and by the media.

Even if usually an individual do not choose randamoly his information sources and his media exposure is opinion based^{40}, for the sake of simplicity, we assume that the rate with which gossipers exchange opinions among themselves and consult the media are the same. At each time-step both gossipers and media can adjust their opinions (figure 1) and a selective choice of the media, at the level of the model, would just change the convergence times. Gossipers are likely to adjust their opinion only if the received information and their own beliefs are close enough, a situation referred as bounded confidence. Mathematical models of opinion dynamics under bounded confidence have been introduced by Axelrod in^{41} and then developed by Deffuant et al.^{35} and by Hegselmann and Krause^{42}.

Inspired by^{43} media are assumed to deliver information in a leader follower dynamics – i.e. to be audience oriented by mimicking the most successful medium in terms of number of customers.

The number of followers – i.e. individuals which accept the information reported on by the medium – is updated at each time step.

Each gossiper and media is initially assigned a random opinion described by a real value within a given opinion space [0..1]. We consider two interacting networks: the gossiper network *G _{g}* and the media network

*G*. Gossipers interact through the bounded confidence model (BCM) of Deffuant and Weisbuch

_{m}^{35}- i.e., at each time step

*t*a gossiper

*i*chooses at random a neighbor

*j*in its social network and adjusts its opinion according to where

*x*is the opinion of the gossipers

_{i}*i*,

*μ*is a convergence factor,

_{gg}*σ*is the threshold (opinion distance) above which gossipers do not interact and

_{gg}*θ*() is Heaviside's theta function.

We assume that also the interaction with the media has a BCM form: Here *k* is a randomly chosen media, *y _{k}* is the information (meme) reported by the

*k*-th media,

*μ*is a convergence factor and

_{gm}*σ*is the threshold below which gossipers gets influenced by the media.

_{gm}The media choice at time *t* is described by the matrix that is equals to 1 if the *i*-th gossiper has chosen the *k*-th media, 0 otherwise; i.e. is a binary random variable that takes the value with probability 1/*M* and otherwise. We can therefore count the followers of each media as where *ξ ^{t}* is calculated at each time-step.

We then introduce our max-audience oriented bounded confidence model among media interacting on a (possibly signed) network described by the matrix with elements *J _{kq}* ∈ {−1, 0, +1}. While the matrix |

*J*| correspond to the adjacency matrix of the network, the sign of

_{kq}*J*indicates the polarization (friend/enemy) between the

_{kq}*k*-th and the

*q*-the media. The case

*J*≥ 0 corresponds to unpolarized media.

_{kq}First, the meme of the *k*-th media is influenced by the most successful (the leader) *l* (*k*) of its neighbors *neigh*(*k*) = {*q*: |*J _{kq}*| > 0} and then its meme is updated accorded a signed version of the BCM model: where the function constrains the memes in the interval [0, 1]. Notice that the use of periodic boundaries conditions is necessary as for

*J*< 0 the memes among the

_{kq}*k*-th and the

*q*-th media tend to diverge and could therefore go below 0 or beyond 1. Moreover, using periodic boundary conditions avoids the problems of extremism (converge of opinions to 0 or 1) that can be induced by fixed boundary conditions

^{44,45}.

The convergence factors *μ _{αβ}* with

*α*,

*β*∈ {

*g*,

*m*} correspond to the timescales of the dynamics. In our study, we always use

*μ*= 0.3 and

_{αβ}*σ*=

_{gg}*σ*=

_{gm}*σ*=

_{mg}*σ*.

Since the opinion space [0, 1] is continuous, we can have different configuration in the final stationary opinion state. Opinions' clusters could be one (consensus), two (polarization), or more (fragmentation). In the following, we will first consider media as audience oriented agencies without any particular competition among them – i.e., a situation in which the opinion of a medium converges to the most successful among its' neighbors. Then, we will introduce competition among media memes – i.e., according to the structural balance of Heider^{46}, we mark the edges between media with positive and negative values as in^{47,48,49} causing respectively a step toward or far from the most followed neighboring medium.

## Results and Discussion

The analytical approach reveals that the our model is not amenable of a simple analytical solution not even at the mean-field level (see Methods for more details); therefore, we have resorted on numerical investigations. More precisely, we performed a thorough simulation program which considers different connectivity patterns for the two interacting layers acting on the opinion space (gossipers and media networks). We first show the opinion dynamics in the case where gossipers are subject to the audience oriented media broadcasting. Then, we introduce competition (polarization) in the media dynamics - i.e, each node of the media network, depending on the edge signature (positive or negative), can diverge (or converge) to (or from) the value of the most followed media. Accordingly to the information system historical evolution^{50,51,52} both the audience-oriented and the competing media cases are first considered in the complete graph case. This is the case of traditional main stream media where everybody knows about everybody. Finally, we consider the model's dynamics when nodes of the media networks are linked through more complex connectivity patterns like in the case of the WWW. The nodes of the gossipers network interact over a scale-free network generated with the Barabasi-Albert model^{53} that sets the exponent of the power law distribution to be 3.0. We explored also other connectivity patterns (Watts-Strogatz small world networks^{54} with different rewiring probability) noticing that the underlying topology does not affect the model qualitative behavior. We explore the model dynamics in terms of opinion distance and number of clusters as a function of the tolerance parameter. Each point of the parameter space (5000 steps) is averaged over 100 different possible initial configurations to attain the desired accuracy. When not specified, the size of the networks is to be assumed to be 10^{4} nodes. The size of actors in traditional main-stream media (*TMSM*) is small: the number of televisions, radio stations, newspapers etc. allows everybody to check what the others are doing. For this reason, we will model interactions among the *TMSM* as a complete graph.

We first analyze the trend of opinions' extremal distances *d* – i.e., the distance between the highest and the lowest opinions in the gossipers' network – as a function of the tolerance *σ*. When *d* = 0, all the gossipers have reached consensus and share the same opinion while for *d* > 0, opinions are distributed; in the case of the standard BCM model, opinions are distributed in clusters (delta functions) separated by a distance higher than *σ*.

In Figure 2 we show the trend of the opinion distance (the highest opinion distance) as a function of the tolerance when the gossipers' network is scale-free^{53}. We have checked that qualitatively similar results hold for the other gossip network topologies. It is known that the increasing of the tolerance parameter causes a reduction of the distance within opinions until it reduces to *consensus* – i.e, when the distance is 0 – and that the critical point (without media) is reached for value of tolerance of 0.5^{55}.

Here, we show that the media action smoothens the transition. In fact, the presence of the media as audience oriented information agencies can enlarge the transition area before the consensus to a single opinion. Such an effect is more evident for a small number of media. Under this settings media always reach a stationary state where they deliver the same message. The size only affects the time to converge. The imitation the most successful one triggers a leader-follower dynamics driven by the opinion clusters having the highest fraction of users. Such an interaction pattern produces conformity in the opinion space. Only when the time needed to the media to converge is lower than the time needed to the emergence of a dominant cluster in the opinion space, the media plays the role of an external field that smoothens the phase transition toward consensus.

In fact, the situation is completely different when we introduce competition (polarization) in the media information targeting mechanisms. With this feature media can have negative or positive feedbacks from the other media; therefore the most popular medium can cause either a convergence (positive coupling) or divergence (negative coupling) of its neighbors' memes. For the sake of simplicity we set to 0.5 the fraction of negative links of the media network – i.e, the number of links that will cause divergence with respect to the most followed media message.

To measure the possible sparsity of opinions induced by the negative links, we bin the opinion space in a probability vector *φ* and measure the localization parameter^{56}: If *M _{B}* is the (large) number of bins of the probability vector,

*L*~ 1/

*M*~ 0 if the opinions are evenly distributed, while

_{B}*L*= 1 if all the opinions are concentrated in a single bin. In general, if opinions are evenly distributed in

*N*clusters,

_{C}*L*

^{−1}~

*N*is of the order of the number of different opinions.

_{C}The left panel of Figure 3 shows that for unsigned interactions among media, all the opinions converge to a single one, i.e. *L* = 1 for high values of *σ*. Notice that in the case of a large number of unpolarized media, two opinion clusters (*L* ~ 0.5) coexist at small *σ*'s (roughly between *σ* = 0.05 and *σ* = 0.10). The smoothening effect of not competing media however is visible at low level of trust (small *σ*s) where we observe a very short plateau. The right panel of Figure 3 shows a re-entrant effect in which the opinion space is highly fragmented for both low and high values of the tolerance *σ*. However, such fragmentation stems from different mechanisms; in fact, while at low *σ* opinion fragment into distinct non-interacting peaks as in the standard *BCM*, at high values of tolerance the opinions fragment because the competition among polarized memes. Low levels of trust in the circulating information allow for a broad distribution of the various opinions in the gossipers' ecosystem. Conversely, with increasing of trust, users are more prone to accept circulating memes that, in turn, lead to the formation of isolated clusters when their distribution is sparse. In fact, at high *σ* we find that while the average number of opinion peaks is stationary, their positions in the opinion space are dynamically fluctuating. Therefore, in the case of polarized media, even total trust in the information (*σ* = 1) does not produce full consensus as in the standard *BCM*, but induces a dynamically evolving stationary state in which users can still change their opinions.

The use of the Internet as a medium for sharing information has caused a shifting of paradigm from main stream centralized media to a more distributed and proactive protocol of information diffusion. At difference with traditional main-stream media, new media are composed of a large number of actors that cannot possibly check all the other media but that interact among each other through a social network. Hence, in this last scenario we use different topologies for the media network – i.e, of 10^{4} nodes with scale-free and small-world topologies (the latter with rewiring probabilities *p* = 0.1, 0.2, 0.3) – acting on a gossip scale-free gossip network of the same size. We analyze both polarized (audience oriented) and unpolarized (competing) media; in the former case, for the sake of simplicity we set to 0.5 the fraction of negative links in the media network. Figure 4 shows the behavior of the localization for scale free media networks and small world topologies, both for the polarised and the unpolarised case. The high number of media makes extreme the effects evinced in the previous scenarios. However, the effects of the network structure is minor since curves for are qualitatively and quantitatively similar both for polarised and unpolarised media.

We observe that the result for new media are qualitatively similar to the ones for the traditional main-stream media: in both cases competition among the media (polarization) introduces a non monotonic behavior in opinions' fragmentation, gossipers never reach consensus and the minimum opinion spread is reached for values of tolerance *σ* < 1.

Despite different connectivity patterns – scale free AB networks are very different from the more clustered WS – the dynamics present a very similar behavior. They evolve with a similar pattern which – in the case of unpolarized media – presents a plateau at small value of *σ* due to the smoothening effect caused by the media which are deliverying competing messages with a small probability to affect users opinion. The different values of the clustering coefficient result in a small broadening in the opinions' distribution: the higher the clustering the larger the opinions' distribution. This is due to the formation of small groups on the same opinions which increases with the transitivity among gossipers.

## Conclusions

In this paper we introduce a novel model of opinion dynamics accounting for the coexistence of media and of social influence as two separated but interdependent processes. People (nodes of the gossip network) interact with their neighbors or with the media using the Bounded Confidence Model (BCM)^{35} – i.e, only they will influence each other only if the distance between their opinions is below a given threshold *σ* (tolerance), the higher *σ*, the more people are likely to be influenced. In turn, the media (nodes of the media network) aim to capture the highest number of followers, hence they change their message by moving toward the value of the media with the highest number of followers. Finally, we introduce competition among media through polarization - i.e., media can interact with positive sign (their memes will converge) or negative sign (their memes will diverge).

We show that, when the media follow an audience oriented strategy of information delivery (i.e. everybody tries to mimic the most successful medium), there is a smoothening of consensus transition, indicating that the media messages tend to produce an impasse when amplified by the gossip dynamics. Such effect tends to disappear with increasing the number of media. On the other hand, competition (polarization) among media produces a fragmentation of the opinions' space thus preventing a system-wide consensus. Such scenario is qualitatively robust to changes in the topologies of the gossip-gossip and medium-medium interaction network; in particular, it stays true both for conventional media (where everybody can interact with everybody) and for new media (where interactions take the form of a social network). Finally, we notice that our choice of keeping equal the *σ* values is better suited to disentagle the contribution of the competition among the media to opinion fragmentation. Varying the tolerance parameters, other routes could be possible; as an example, a very small tolerance *σ _{mm}* among the media (conservative media) could keep opinions fragmented even for tolerances

*σ*among the gossipers beyond the consensus transition.

_{gg}The next envisioned step will be to fine tune our model with real data from social networks platforms where main stream media directly interact with users and together change continuously the opinions' as well as the information space.

## Methods

### * Algorithm

The gossip network *G _{g}* = (

*V*,

_{g}*E*) is composed by

_{g}*N*= |

*V*| gossipers; the edges

_{g}*E*represent social contacts among gossipers. Nodes of the gossip network interact with randomly selected a neighbor by applying the following rule: Given a node

_{g}*i*that has selected a node

*j*, having respectively opinion

*x*and

_{i}*x*(the opinion varies in a continuous space between 0.0 and 1.0)

_{j}**for** all *i* ∈ *V _{g}*

**do**

select random neighbor *j*

**if** **then**

where *σ _{gg}* is the threshold parameter (the distance between one is likely to consider the others opinions) and

*μ*is a convergence parameter varying in the interval (0, 1/2].

_{gg}The media network *G _{m}* = (

*V*,

_{m}*E*) is composed by

_{m}*M*= |

*V*| media and follows a similar rule except for the tolerance control. Each node

_{m}*α*of the media network has an opinion

*y*selects in its neighborhood the one that has the highest number of followers (audience) and then apply the updating. Given two media

_{α}*i*,

*j*∈

*V*

_{m}**for** all *α* ∈ *V _{m}*

**do**

select most influential neighbor *β*

**if** **then**

**if** **then**

**if** **then**

where *J _{αβ}* = ±1 represent the polarization among the media.

The set of edges *E _{gm}* ⊂

*V*×

_{g}*V*represents the media followed by the gossipers; i.e. an edge (

_{m}*i*,

*α*) ∈

*E*means that gossiper

_{gm}*i*can be influenced by the media

*α*. The inter-network dynamics takes place by gossipers choosing at random a media among the ones they follow:

**for** all *i* ∈ *V _{g}*

**do**

select random media *α*

**if** **then**

Thus, each node of the gossip network talks with his friend and then gets informed by the media (by randomly selecting one node from the media network) In such a mechanism: a) a leader-follower dynamics emerges among media the messages delivered by the media; b) the gossip network and the media network have a feedback loop. Notice that we have checked that the update sequence does not influence the results of the dynamics.

### * Mean field equations

A simple analytical tool that help to understand the main features of network-based models like our coupled *BCM* are the mean field (MF) approximations.

We will first sketch the MF solution in the general case of a *BCM* subject to a time dependent external field (information from the media). Let {*x _{i}*} be the

*N*opinions of the crowd and {

*y*} the

_{k}*M*opinions (memes) of the media with

*x*,

_{i}*y*∈ (0, 1). Let's suppose that at each step an individual

_{k}*i*can get information by another randomly chosen person

*j*with probability

*α*or by a randomly chosen media

_{g}*k*with probability

*α*, with

_{m}*α*+

_{i}*α*= 1. The individual then gets influenced by the other opinion with probability

_{m}*c*(

_{g}*x*,

*y*) by individuals and

*c*(

_{m}*x*,

*y*) by media: where

*c*and

_{g}*c*are functions that measure the interaction strenghts among different opinions. Notice that the standard

_{m}*BCM*corresponds to

*α*= 1 and

_{g}*c*(

_{g}*x*,

*y*) = 1 −

*θ*(

*σ*− |

_{gg}*x*−

*y*|), where

*θ*(

*x*) is the Heavyside theta-function and

*σ*is the tolerance parameter of the

_{gg}*BCM*model. Let

*p*(

_{g}*x*,

*t*) and

*p*(

_{m}*x*,

*t*) be the probability distribution of individual opinions and of media opinions at time

*t*. Rescaling the time by the average rate at which individuals receive informations, the evolution of the individual opinion distribution

*p*(

_{g}*x*,

*t*) is described by the master equation Notice that in the

*BCM*case with the standard choice

*μ*= 1/2, eq. 9 reduces to the MF equations derived for the

_{gg}*BCM*model by Ben-naim and coauthors

^{57}. Let's now consider for simplicity the case in which

*c*(

_{g}*x*,

*y*) =

*c*(

_{m}*x*,

*y*) = 1 −

*θ*(

*σ*− |

*x*−

*y*|) and the distribution of media opinions is time independent. It is easy to check that to the field with |

*y*−

_{k}*y*| >

_{l}*σ*µ

*k*,

*l*there corresponds the stationary solution

*p*(

_{g}*x*) =

*p*(

_{m}*x*). Notice that the MF approximation comes from disregarding joint correlations among the opinions, i.e. We will now consider the general case in which the dynamics of the media is coupled to the dynamics of the opinions. Such a case can be described by adding to eq. 9 an equation for the field evolution where in the MF approximation

*F*is a functional of the

*p*only. For the media-media leader-follower dynamics, one has to understand which is the meme that has the maximum number of followers. Disregarding fluctuations, this can be calculated as and the dynamics for the memes is Eq. 13 makes the mean-field system of equation not amenable of simple solutions.

_{α}A further refinement of the MF approach would be needed in the case of competing media: in such a case, it is well known that even at the MF level more complicated techniques like the cavity method or the replica trick are needed to solve systems with competing interactions^{58,59}.

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## Acknowledgements

We thank US grant HDTRA1-11-1-0048, CNR-PNR National Project “Crisis-Lab” and EU FET project MULTIPLEX nr.317532. The contents of the paper do not necessarily reflect the position or the policy of funding parties.

## Author information

## Affiliations

### Laboratory for the modeling of biological and socio-technical systems, Northeastern University, Boston, MA 02115 USA

- Walter Quattrociocchi

### LIMS the London Institute of Mathematical Sciences, 22 South Audley St Mayfair London W1K 2NY, UK

- Walter Quattrociocchi
- , Guido Caldarelli
- & Antonio Scala

### IMT Alti Studi Lucca, piazza S. Ponziano 6, 55100 Lucca, Italy

- Walter Quattrociocchi
- , Guido Caldarelli
- & Antonio Scala

### ISC-CNR Physics Dept., Univ. “La Sapienza” Piazzale Moro 5, 00185 Roma, Italy

- Guido Caldarelli
- & Antonio Scala

## Authors

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### Contributions

A.S. and W.Q. equally contributed to the simulations and the data analysis. A.S., W.Q. and G.C. equally contributed to the writing of the paper.

### Competing interests

The authors declare no competing financial interests.

## Corresponding author

Correspondence to Antonio Scala.

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