Multi-Blockchain XRPL MATIC-SOLO SmartContract{Smart NFTs}

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  All 10,000 sick NFTs could gain some kinda sick NFT utility via adopting this project TigerGraph Solution.

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  Startup IPO SmartContract demonstration worldblockchaincomputer{.org .crypto} 1000 XRP Dividend payment to {Smart NFT #0000001}...it works!

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  1000 XRP dividend payment using human-readable .crypto address.

by David Harness, contact on Twitter: davidtech.crypto @tensornerdo (reload page if Youtube video not visible above)

• Self-Defined Problem Statement
• Multi-blockchain Starter-Kit Solution
• Corporate Startup IPO SmartContract{Smart NFTs} Network Template
• Data: Moralis Cross-chain Smart Contract Event APIs
• What Makes XRPL MATIC-SOLO SmartContract{NFTs} Smart?
• Educational Value of TigerGraph Multi-Blockchain Visualization
• What's Next for XRPL MATIC-SOLO SmartContract{Smart NFTs}

Self-Defined Problem Statement

The problem of cross-blockchain transaction tracking requires an innovative solution to keep up with the exponential global adoption of the multi-blockchain critical infrastructure and its exponential increases in sovereign fiat-cryptocurrency transaction densities, as indicated in the review Consortium Blockchains: Overview, Applications and Challenges. NFTs are all the rage experiencing wild price speculation on the expectation of developing some unrealized future value in the emerging global multi-blockchain critical infrastructure network. Accordingly, the Ethereum scaling problem of extremely slow transactions and extremely high gas fees, as described in the Forbes article Ethereum: The $640 Billion Dollar Question, has only gotten worse: Ethereum Gas Prices Continue To Soar Due To Stablecoin Transactions.

New Multi-blockchain Transaction Solution Starter-Kit

TigerGraph really helps to interactively visualize the present Ethereum scaling problem solution which introduces an Enterprise Knowledge Graph Crunchbase-type Multi-Blockchain Starter-Kit design schema to analyze the cross-blockchain transaction histories starting with the original wallet ownership of the XRPL Hackathon Compound-Minting blockchaindomain{.crypto. nft .wallet .x} MATIC IPFS website & SOLO NFT project copies. Thus establishing trackable multi-blockchain network addresses in the form of iOS-Android human-readable.{crypto .nft .wallet .x} XRP Ledger XRP MATIC USDC HBAR BTC LTC ZIL ETH addresses for IPFS & conventional{.com .org} websites hosting Polygon-Solidity-MATIC smart contract transactions via compound-minting into MATIC-SOLO smart NFTs dApp network addresses on the Sologenic DEX which is already trading over 40,000 stocks, commodities, ETFs, and securities from over 30 top global stock exchanges located in Europe, Asia, Oceania, and North America. Hence the present TigerGraph Graph For All Million Dollar Challenge entry establishes an Ethereum ETH-Solidity smart contract SCALING PROBLEM SOLUTION.

For example, (see demonstration GIF in the image gallery above and YouTube video link below) one solution is via compound-minting XRPL MATIC-SOLO Smart Contract Smart NFTs representing shares of stock where it is desired to track the current owner of each smart NFT/share XRPL wallet "address" (Vertex SOLO_NFT_n Owner_XRP_Public_Key) before sending a dividend or any other type of transaction or notice to shareholders of said smart NFT/shares, as updated by XRPL Explorer Transaction Search. The initiation of the dividend payment, escrow, payment channel, or any other transaction is via smart contract event.

TigerGraph then tracks Polygonscan smart contract events via Moralis Transaction History APIs to generate data to find the current owner of each smart NFT/share XRPL wallet "address" represented in terms of GSQL having the XRPL MATIC-SOLO Smart Contract Smart NFT (Vertex SOLO_NFT_n Owner_XRP_Public_Key) "name" (Vertex: SOLO_NFT_n NFT_Name) as "minted by" (Vertex: SOLO_NFT_n Issuer_blockchain_domain) original information of the corporate dApp stock smart contract metadata.json:

CREATE QUERY FindShareNFTholderWalletAddressesAndNumberOfShareNFTs(address (Vertex SOLO_NFT_n Owner_XRP_Public_Key) STRING, minted_by (Vertex: SOLO_NFT_n Issuer_blockchain_domain) STRING, name (Vertex: SOLO_NFT_n NFT_Name) STRING) FOR GRAPH CompoundKnowledge1 {Brief steps: 1. Find current shareNFTholders wallet "address" (Vertex: SOLO_NFT_n Owner_XRP_Public_Key) which shareNFTs "name" (Vertex: SOLO_NFT_n NFT_Name) were "minted by" (Vertex: SOLO_NFT_n Issuer_blockchain_domain) original wallet address of Company. 2. Display number of shareNFTs per shareNFTholders wallet "address" (Vertex: SOLO_NFT_n Owner_XRP_Public_Key). 3. Find "external_link":"https://gateway.pinata.cloud/ipfs/QmeBmtT9PERNQLnGkECbTY3Fbfi7kmPFz91ezJ27Ls79os" ...}

XRP Ledger MATIC-SOLO NFT 4D Photon-Electron Gauge Group Mathematica® Proof #0001 metadata.json

Corporate Startup IPO SmartContract{Smart NFTs} Template

See additional YouTube video: Corporate Startup IPO Demonstration worldblockchaincomputer{.org .crypto} Sends 1000 XRP Dividend Payment to {Smart NFT #0000001}.

TigerGraph really helps bring this Smart Contract{Smart NFTs} Network idea into focus by means of the decentralized corporate worldblockchaincomputer{.org .crypto} IPO network shown in the GIF, which TigerGraph Solution Export file is available in the GitHub repository export_064629446.tar.

This TigerGraph starter kit design schema starts with the conventional domain worldblockchaincomputer.org website, wherein the Unstoppable Domains human-readable crypto address worldblockchaincomputer.crypto is minted by Polygon-MATIC to redirect crypto transactions to the machine-readable crypto addresses shown.

Not only that, the worldblockchaincomputer.crypto address - when entered into the URL address bar of a Brave or Chrome browser - will also redirect to the worldblockchaincomputer.org website, as shown in the video and GIF. Safari does not yet seem to be up to speed with {.crypto .nft .x} blockchain domain redirects to {.com .org .net} conventional domains.

Hence Polygon-MATIC-Solidity smart contract transactions can be executed by means of the .org and .crypto domains according to the detection of smart contract related events, for example, by the Moralis Smart Contract Event APIs.

The present Smart Contract{Smart NFTs} Network is then formed by compound-minting the {.org .crypto} domains on the XRP Ledger via the Sologenic DEX decentralized exchange into SOLO NFT_Shares with the same XRP wallet address as the .crypto redirect list, since the NFT_Shares have not been sold yet, hence still redirecting payments via the original .org website.

Accordingly, TigerGraph represents in the project GIF the dApp network GSQL metadata sequence sending a 1000 XRP dividend payment to the owner of worldblockchaincomputer{.org .crypto} SmartContract{Smart NFTs} #0000001.

It works.

The present SmartContract{Smart NFTs} Network starter-kit is available for Import into TigerGraph via the export_064629446.tar file on GitHub demonstrating a SOLUTION to the Ethereum extremely slow processing & high gas fees SCALING PROBLEM. The present solution being the Polygon-MATIC Mainnet handles the Solidity smart contract internal transactions minimizing the need for the expensive deal-breaking Ethereum-Layer 2 BRIDGING FEES described in the Forbes article above while the XRP Ledger Javascript library HTML browser commands provide fast, efficient, and secure XRP USDC bridging transactions with the sovereign fiat central banking networks.

Data: Moralis Smart Contract Event Polygonscan APIs

Watching the world blockchain data develop is reminiscent of watching a film negative develop in a civil war darkroom wherein as quantum mechanical observer-participants we are also the developing agents in the solution. Hence the present TigerGraph solution requires a data source keeping up with the developing changes such as the Moralis Smart Contract Event APIs. One thing taken into consideration here is the cross-blockchain tracking of events requires a synthesis of the variations in multi-blockchain metadata nomenclature, such as pointed out in the Loading Data into TigerGaph tutorial pointing out the importance of the naming convention of variables to make the network transactions more readily understandable and optimize the communication of GSQL query results.

(In order to add data files and run GSQL queries it is of course necessary to have a Microsoft Azure or Google account. However, I subscribed to Microsoft Azure but the Azure subscription never indicated an active connection to TigerGraph and a support ticket was never answered. I already have a Google Developer Account but the Google Subscription was indicated on the Google site to not be available at this time. In any event the present TigerGraph project is on track with moralis.io to sync a smart contract event server subscription to conduct TigerGraph GSQL queries.)

What Makes XRPL MATIC-SOLO SmartContract{NFTs} Smart?

By symmetry, all the TigerGraph vertice-edge design schema replicate an AI neuron-axon design schema, the common function of which is the neurotransmission of information. Accordingly, wherein information metadata generation and the transmission of said metadata has been gaining in monetary value, the present TigerGraph solutions provide a significant advancement in the multi-blockchain generation, transmission, transactional-monetization, and tracking of said vertice-edge neuron-axon neurotransmission of information.

The present TigerGraph solution upgrades the 10,000 monkey NFT images into smart NFTs by means of the present Multi-Blockchain Starter-Kit building on a successful prior Devpost XRPL Hackathon project creating the components and generating the top-level data for this project via compound-minting XRP Ledger Unstoppable Domains human-readable.{crypto .nft .wallet .x} XRP MATIC USDC BTC LTC ETH addresses for IPFS & traditional websites hosting Polygon-Solidity smart contract transactions via compound-minted into MATIC-SOLO smart NFTs network addresses on the Sologenic DEX NFT Marketplace.

The NFT image used in the prior XRPL Hackathon Compound-MInting project is of a Mathematica® theorem proving operator computational mathematical physics proof, which in the interests of AI computationally reproduces the experimentally measured photon-electron quantum mechanical observables to all 31 & 34 decimal places, in anticipation AI developers seeking to apply the classical logic of automated theorem proofs, such as the University of Cambridge Isabelle archive of Formal Proofs, to the non-classical logics of artificial intelligence, computer science, mathematics, and philosophy in order to formalize an AI world view computational replication of the observed psychophysical experiences Automated Reasoning in Non-classical Logics in the TPTP World.

Accordingly, the use of the Mathematica® human-intelligence computer algebra formalized computational mathematical physics proof is meant to complement the expectation many have for NFTs to gain functionality towards representing stocks, bonds, real estate smart contracts, mortgages, and all other debt instruments, patents, intellectual, and physical property. The present multiple Compound-Minted XRPL IPFS Solidity MATIC smart contract transactional smart SOLO NFT copies represent a new category of GSQL queries in the field of sovereign fiat-cryptocurrency cross-blockchain vertices and edge transactions analytics.

Educational Value of TigerGraph Multi-Blockchain Visualization

A human-machine information revolution termed the Industrial Revolution 4.0 is well underway, wherein most of the general public and government regulators lack the faintest understanding of the basic terminology and schematic overview of the network reset the revolution is meant to benefit.

The lack of blockchain understanding is not at all surprising given that even the most sophisticated developers are finding the exponential pace of new developments difficult to communicate to regulators and corporate management as new players take the field. It is as if we are all developing a future global university curriculum in a decentralized research lab where even local companies and indeed private individuals are now transacting more and more directly with the global blockchains.

Recalling Algebra 101 the first step to solving a story problem is to first define the problem by drawing a picture. This TigerGraph Cross-Blockchain Solution first draws the vertices and edges multi-blockchain networks to define the problem and then provides the interactive GSQL means to analyze the developing story of the Industrial Revolution 4.0 critical infrastructure scaling problem towards finding a big picture solution.

What's Next for XRPL-Polygon SmartContract{Smart NFTs}

Another potential application under consideration is the CarbonLand Trust XRPL Grant Waves 1 & 2 carbon credit precision forestry project utilizes drone surveillance with multi-spectral cameras and LiDAR metrology to generate 3D individual tree images to calculate biomass for the duration of the 20-year carbon credit bonds. However, once again, smart contract transactions and image storage fees on the Ethereum Virtual Machine are pricing many applications out of range where at this writing the gas fees for swapping 7 MATIC from the Ethereum Mainnet to Polygon is more than $50.

Fortunately, the present SOLO smart NFTs each have an image storage capacity of 50MB wherein each collection XRP wallet can store 10 NFTs. The XRP create wallet fee is currently 10 XRP. Each SOLO NFT costs 2 SOLO to mint. So currently the cost of minting 10 SOLO NFTs is 10 XRP at $.76 and 20 SOLO at $.57 ≈ $19 for 500MB image storage per collection.

▶️ Best Polygon-Solidity NFT YouTube Tutorial series by Etisha Garg

Acknowledgements

I first got the idea for human-readable.crypto domain name NFT owership while watching a @RippleXDev video hosted by @HammerToe with @yyolk demonstrating the RippleX html NFT minting UI, wherein as they explained, one field requires a URL to store the image. I immediately thought of using one of all the Unstoppable domains I had been buying thinking they would be useful for something someday.

My experience with Devpost is it's a great platform for facilitating software development wherein the full-stack has worked flawlessly in the two projects I have been having success with.

Built With

• ipfs
• mathmatica
• matic
• polygon
• python
• ripple
• solo
• sologenic
• tigergraph
• xrpl