A cyber-anima-based model of material conscious information network

3.1 Model the basic information

The MCIN is a large-scaled, open-styled, self-organized and ecological intelligent network. The nodes of the MCIN are information counterparts of supply and demand sides in realistic trading activities or interactions, which can be divided into four categories: person, enterprise, administrative department and thing. Each of the MCIN node has basic and supply–demand information. The basic information reflects the material world of a node, whereas the supply–demand information represents the history of the conscious world of a node.

In the light of the aforementioned characteristics, a model which can generically represent the basic information of all four categories of the MCIN nodes should be designed from a cross-disciplinary perspective. In particular, each category of the MCIN nodes relates to both general and specific disciplines, shown in Table I.

In our previous work (Shen, 2015), we proposed a semantic model, called cyber-anima, to reflect individuals in the cyberspace and reason their desires and intentions for recommender systems. In light of the equivalence between “individual” and “person” in our previous work and this work, respectively, the basic information of the MCIN person node can be modeled by cyber-anima. Without the loss of generality, we formalize the basic information of The MCIN nodes based on cyber-anima as tuple I_B with four attributes, as explained below.

Definition 1 (Model of the basic information of the MCIN node). The basic information of the MCIN node is modeled based on cyber-anima as tuple I_B with four attributes:

D_ST is the structure dimension;

D_CH is the character dimension;

D_EX is the experience dimension; and

D_KN is the knowledge dimension.

In accordance with Definition 1, the dimensions of the basic information of the MCIN person node are designed with cross-disciplinary perspective shown in Table II. The basic information of the MCIN person node has four dimensions including structure, character, experience and knowledge.

For the sake of self-organized, the basic information of The MCIN nodes are modeled semantically. Dimension is the maximum granularity composition of the semantic model. Formally, we define a dimension of the basic information of the MCIN nodes as tuple D with two attributes, as explained below.

Definition 2 (Dimension). A dimension of the basic information of the MCIN node is modeled as tuple D with two attributes:

C is the set of concepts, and C ∷ = <MC, AXC>, where MC is the marker of concept, and AXC is the set of concept axioms; and

R is the set of relations, and R ∷ = < MR , CP, AXR>, where MR is the marker of relation, CP is the pair of concept, and AXR is the set of relation axioms.

To clarify the representation of dimensions, we give each dimension several classifications to distinguish their concepts with different perspectives. For example, the structure dimension of the basic information of the MCIN person node has two classifications of DNA and physique distinguished in perspectives of biology and medical science, respectively. Accordingly, we can extend the MCIN person node to model the other three categories of the MCIN nodes with identical dimensions but different classifications of concept. Tables III-V show the dimensions of the basic information of the MCIN enterprise node, the MCIN administrative department node and the MCIN thing node with their classifications and perspectives.

Based on cyber-anima, the basic information of all four categories of the MCIN nodes has been modeled generically and semantically. In maximum granularity level, such models have uniform dimensions: structure, character, experience and knowledge. Albeit the dimensions of the basic information of the MCIN nodes are identical in semantic structure, they are distinguished by different classifications generated in different perspectives. We use these classifications as an explanatory tool, so these classifications of dimensions illustrated above are not exclusive and varied with weights of blended perspectives.

3.2 Construct information for the material conscious information network node

The basic information of The MCIN nodes has been generically and semantically modeled with four dimensions including structure, character, experience and knowledge. As we all know, anything in the material world will be changed by the environment eventually with the time. The dimensions of the basic information of the MCIN nodes have to be synchronized with these changes. As aforementioned, the history of the conscious world of the MCIN node can be represented by its supply–demand information. In a temporal perspective, the two worlds of a the MCIN node interact as both cause and effect. For the sake of modeling, the MCIN nodes, both basic and supply–demand information have to be constructed in a temporal chain styled formation. Formally, we define the model of the MCIN nodes as tuple A with four attributes, as explained below.

Definition 3 (Model of the MCIN node). An MCIN node is modeled based on cyber-anima as tuple A with four attributes:

I_B is the basic information of a MCIN node;

I_S is the supply information of a MCIN node;

I_D- is the demand information of a MCIN node; and

T is the set of time points.

The model of the MCIN node has a DNA-styled double-chain structure. As shown in Figure 1, there are two chains in the model which represent the supply information and demand information, respectively. The connector of these two chains stands for the basic information of the MCIN node. The whole chain is growing with time, and each minimum segment of the double chain refers to the basic and supply–demand information of the MCIN nodes in a particular time point.

4.1 Spontaneous interactions required for the material conscious information network nodes

The MCIN is a ternary system of material, conscious and information, which networks any supply–demand relationships. Figure 2 illustrates the interactions between the MCIN nodes which are in a trading style. Services and information are demanded and supplied by the MCIN nodes mutually.

No matter which kind of the MCIN nodes, they have the same pattern of interactions including creating supply–demand information, searching supply–demand information, conforming supply–demand information, delivering service, searching particular nodes, linking with other nodes, etc. Though persons, enterprises, administrative departments and things can interact among themselves, most of such time-consuming work has better been efficiently accomplished by intelligent federated agents facilitated by the MCIN nodes.

These intelligent federated agents perceive, think, interact and evolve as a whole through cooperating and collaborating. Each agent has its particular intelligence and generates outputs by handling different inputs. As an example, some of the agents can handle vision (graphics), auditory (audio) and touch (pressure, vibration, temperature and humidity) inputs and generate manageable outputs, and others can think of the subsequent reactions toward such outputs. Different MCIN nodes have different levels of intelligence on account of its agents and can evolve to a higher level via interacting mutually.

4.2 Build anima-desire-intention-based multi-agent architecture

For the purpose of perceiving, thinking, behaving and evolving as a whole, the federated agents of the MCIN nodes require an efficient multi-agent architecture to self-organize. In our previous work (Shen, 2015), we proposed an ADI-based multi-agent architecture for recommender system. As intelligent interactions between the MCIN nodes have a similar scenario of recommending items between users, we can extend and use the architecture for the agents of the MCIN nodes. To this end, we formalize the spontaneous interaction generation problem as follows:

Definition 4 (Spontaneous interaction generation problem). For each MCIN node, n ∈ N has a desire dtiw ∈ D_n and an interaction itiw ∈ I_n on time point t_i ∈ T in possible world w ∈ W according to its Cyber - Anima A_n, we want to choose such interaction itiw that itiw = δ (maxexpval, dtiw).

where:

W is a set of possible worlds, and for each w ∈ W, we have w ∷ = < T_w, A_w, E_w >. T_w ⊆ T is a set of time points in possible world w; A_w is a binary relation of time points, namely, ∀i(t_i, t_i+1) ∈ A_w; E_w is a set of event type in possible world w;

D_n is the possible desire world of The MCIN nodes n ∈ N, and D_n ⊆ W × T × W;

I_n is the possible interaction world of The MCIN nodes n ∈ N, and I_n ⊆ W × T × W;

δ is the deliberation function;

A_n is the Cyber-Anima model of The MCIN nodes n ∈ N; and

maxexpval is the maximizing expected value.

In light of Definition 4, generating an optimum interaction for a particular MCIN node in a specific time point is a twofold process shown in Figure 3. First, we reason the desire dtiw of the MCIN node based on its cyber-anima model. Second, we reason and find such an interaction itiw that itiw=δ(maxexpval, dtiw).

For the purpose of reasoning the desire of the MCIN node, we acquire the model of the MCIN node model A_n on current time point t_i, then drive the agents for perceiving and thinking to reason each event type etiw of node’s desire dtiw along with its payoff value PAYOFF(etiw) on current time point t_i based on the MCIN node model A_p. The node’s desire dtiw illustrates who it expects to interact with and what service or information it expects to interact for. Next, we drive the agents for perceiving and thinking again to reason the node’s interaction itiw which illustrates the probability PROB(etiw) and payoff value PAYOFF(etiw) toward each candidate to be interacted on current time point t_i based on node’s desire dtiw . Finally, we sum up the utility value PAYOFFetiw ·PROB(etiw) of each candidate in the node’s interaction itiw and sort for the optimal interactions. As the model, desire and interaction of the MCIN node are built on material world, conscious world and information world, respectively, the process of generating spontaneous interaction based on ADI reasoning is an exploration from unary world to ternary world via binary world.

Furthermore, the process of evolving intelligence level of The MCIN nodes is just a remix of ADI reasoning process, namely ADI evolving. In ADI evolving, we can explore from ternary world to unary world via binary world, to train the agents with given sets of model, desire and interaction of the MCIN node.

5.1 Build the material conscious information network based on six-degrees-of-separation blockchain

As a future networked system of supply–demand relationship, the MCIN has the characteristics of coevolving intelligence, decentralized organization and efficient addressing. Coevolving intelligence relies on the multi-agent architecture of the intelligent federated agents of the MCIN nodes, which has been discussed in the last sections. Once an MCIN node is created, it would like to link to other nodes, evolve constantly and never destroy. For the purpose of linking, these MCIN nodes together and building the decentralized network, we propose a six-degrees-of-separation blockchain.

Blockchain (Nakamoto, 2008) is a kind of distributed database, which serves as the public ledger for all transactions of Bitcoin, a decentralized digital currency, after conceptualization. We use blockchain to enable the decentralization of the MCIN and make the following specifications of the MCIN blockchain:

• each MCIN person, enterprise or administrative department node must join a blockchain with at least N different The MCIN nodes, where N=total amount of MCIN person, enterprise and administrative department nodes5 ;

• each MCIN thing node must join a blockchain with at least five different the MCIN nodes; and

• each MCIN blockchain must have at least one MCIN administrative department node.

The joining of the MCIN blockchain is driven by a supply–demand relationship. Whenever the MCIN nodes construct new supply–demand relationships with other the MCIN nodes, they may join or create new MCIN blockchain. As one of the interactions, the selection of blockchain is accomplished by the agents of the MCIN nodes spontaneously according to abovementioned specifications. Therefore, in each MCIN blockchain, we have the following truths:

• each member of the blockchain has a supply–demand relationship with at least one other member;

• all members of a blockchain maintain an equilibrium of supply–demand relationship; once the equilibrium is broken, new members may join the blockchain; otherwise, the old members may join or create new blockchain; and

• via at most six MCIN blockchains, any two MCIN nodes can link with each other. It means that the MCIN blockchain satisfies six-degrees-of-seperation (Milgram, 1967).

Leveraging the MCIN blockchain, each MCIN node can acquire a unique, immutable address. Formally, we define the address of the MCIN nodes as follows:

Definition 5 (the MCIN blockchain and node address). For each MCIN blockchain bc ∈ BC has a member set of the MCIN nodes N. Then, we have ADDR_bc = Hash(I_B1, I_B2, I_B3, …, I_Bn). For each MCIN node n ∈ N in the MCIN blockchain bc, we have ADDR_n = ADDR_bc + HASH(I_Bw).

where:

I_B is the basic information of a MCIN node;

ADDR_bc is the address of the MCIN blockchain bc ∈ BC;

ADDR_n is the address of the MCIN nodes n ∈ N; and

HASH is the hash function to generate the address code.

Figure 4 illustrates the process of generating the MCIN blockchain and node address. As an example, China government, Beijing city government and Haidian district government are the MCIN administrative department nodes, which are linked to the same MCIN blockchain. In the light of Definition 5, the address of the MCIN blockchain can be generated by hashing all basic information of these three MCIN administrative department nodes, which is a unique, immutable address. Meanwhile, the address of a single MCIN node, e.g. China government, can be generated by hashing its basic information concatenating the address of the MCIN blockchain.

5.2 Supply–demand-oriented addressing

As a decentralized network, the MCIN requires an efficient addressing method. Compared to a centralized network, the addressing method of the MCIN has the characteristics of socialization, information integration, collective intelligence, traceability, high robustness, unification of producing and consuming, high scalability and decentralization. As the MCIN is a future networked system of supply–demand relationship, we propose a supply–demand-oriented addressing method to locate target nodes efficiently via supply–demand relationships.

In light of Definition 3, the MCIN nodes are modeled with supply and demand chains, i.e. the supply information I_S and the demand information I_D, which represent the history of supply and demand respectively. The supply and demand information is materialization of conscious world of the MCIN nodes and can be modeled in the same way. Formally, we define the model of the supply and demand information as tuple with two attributes, as explained below:

Definition 6 (Model of the supply and demand information of the MCIN node). The supply and demand information of the MCIN nodes are modeled as tuple I_S and I_D with two attributes:

R is a set of supply and demand request, we have R ∷ = < C_object, C_attribute >, where C_object is the set of concepts of request object, and C_attribute is the set of concepts of the attributes correspondent to the object; and

P is a set of addressing path correspondent to the request. For each addressing path p ∈ P, we have the partially ordered set p = (ADDR_bc,…, ADDR_n).

The request of the MCIN node addressing is a segment of the supply and demand information. The supply–demand-oriented addressing method begins from the MCIN node of requester and traverses a certain number (not all) of blockchains to locate the MCIN nodes which match the request. Leveraging the supply and demand information of the MCIN nodes, the performance of addressing can be improved with the amount of similar requests. Figure 5 illustrates an example of supply–demand-oriented addressing in the MCIN. In Figure 5(a), Jerry launches a request, and the addressing of his request first starts in his directly linked blockchain A to find matched requests in supply and demand information. Unfortunately, no such requests matches. Then, in Figure 5(b), the addressing extends to adjacent blockchain A and B via Haidian District Government. This time, a matched supply request is found in the supply information of Supermarket. As Jerry and Supermarket have a supply–demand relationship after the addressing, a new blockchain D is created, and the path of Jerry’s request is from Jerry to Supermarket via blockchain D. In Figure 5(c), Angela launches a similar request, and the addressing of her request first starts in blockchain A as well. Obviously, Jerry’s demand request matches. Then in Figure 5(d), a matched supply request is found in the supply information of Supermarket by leveraging the path of Jerry’s previous demand request. As Angela and Supermarket have a supply–demand relationship after the addressing, a new blockchain E is created, and the path of Angela’s request is from Angela to Supermarket via blockchain E. The first addressing traverses 3 MCIN blockchains and 7 MCIN nodes, whereas the second addressing for the similar request traverses 1 MCIN blockchain and 4 MCIN nodes. With the supply–demand-oriented addressing method, the same type of similar requests in others’ supply–demand information can efficiently improve the addressing performance.