DNA Dual Chain Design and its Benefits

The layered design of the Internet inspires the DNA’s Dual Chain Design. Layered protocol architecture is utilized by the Internet to address each functionality separately. The difference between different networking technologies is abstracted by the Internet Protocol (IP). A common infrastructure for all sorts of different applications is created by this layered abstraction design to connect and communicate. They use the difference under these underlying networks. A layered design is adopted by DNA to tackle both scalability and Interoperability in one big monolithic layer. This layer design addresses two issues separately in two distinct layers. These layers are the Performance Layer (DNA-PL) and the Interoperability Layer (DNA-IL).

When the system is divided into multiple sub-layers, it gives each layer the flexibility to evolve separately and independently. These features allow the Internet to be grow and scale at incredible speed. Also, it has upgraded from dial-up to fiber optics such as 4G and 5G links. Layered protocol architecture separately addresses each functionality in different layers. It also ensures the Internet's growth and the success of its Interoperability. DNA-IL independently improves the Interoperability. It does not affect the performance of the DNA-PL layer. Without damaging its compatibility and sacrificing its Interoperability, DNA can able to scale.

Lightning Network and Channel Design

Lightning network allows for extremely fast transactions, and it significantly reduces the fees. In order for the payment routing to happen, channels between two transacting parties need to be re-established. For transacting parties to create channels, there are no clear incentives. Also, the speed of adoption remains unsatisfactory for the Lightning Network. 23 Super Nodes and 529 Regular Nodes are already built. These are built due to pre-existing delegating and staking processes. Parties transactions will be lightning-fast when transacting parties have channels with of any of the nodes. They pay only a fraction of the regular fees.

Real-world data are not automatically captured and included by blockchain, like new events and stock prices. These data are essential for smart contracts. Due to this, they function properly. Oracles become more feasible as the scalability issue is addressed. Oracles provide data feeds in a decentralized fashion. The number of assets created or exchanged in the system, the number of digital identities and smart contracts, the size of data feed, and the number of oracles are the following criteria measured the success of the Dualchain. Problems like redundancy, incompatibility of data, and loss or leaks of data are controlled by the team of Metaverse DNA. Centralized identity is the root of all these data problems.

That’s why Metaverse DNA ensures decentralized identities that are harder to hack or steal as compared to centralized identities. In this way, fragmented data takes more work to steal and compile. Applications will have KYC/AML requirements. A decentralized identity will be able to access other decentralized blockchain services. This solves the redundancy issue. Privatization of identity is ensured through a decentralized identity. Individuals hold private keys that can access data. No other individuals will be able to this data. The token economic model realizes the value of such token economics.