WHITE PAPER VERSION 1.03
The ICO public sale:
2018 Q4
The Mobile Computational Network
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PREFACE
We exist in a computer age where there is a struggle to cope with a scarcity of computational resources. A vast digital influx of critical data emerges daily, yet our reach to such capacity is challenged to keep afloat. It all stems from “Big Data” commercial applications, and exponential growth of ambitious scientific research. We seek to understand everything and everyone - from subatomic particles, to analysis of DNA genomes, social behavior and the outer limits of astrophysics and cosmology. From the “micro” to the “macro”, our insatiable computational needs kept spiraling out of control. The NATEE project is one of computational conservation.
NATEE is a word in the Thai language which translates as “minute”. We can envision the millions of smartphone conversations unravelling “per minute” across the internet helps to illuminate the company’s name, and untapped potential of “mobile grid computing”
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Table of Contents
1 Introduction 4
2 Understanding grid computing 7
3 Market situation 8
4 Problem statement 9
5 Solution outline of the vision 11
6 NATEE’s applications for big data 12
7 Business model 13
8 NATEE company and research 17
9 Key success factors 18
10 NATEE ecosystem 20
11 NATEE architecture 21
12 NATEE platform 25
13 Grid management 27
14 Incentive Mechanism for Mobile Decentralized Computing Systems 30
15 NATEE Research collaboration with NTU 32
16 Tokenomics the NATEE token 33
17 Crowd sale NATEE ico plans 35
18 Team NATEE 39
19 References 42
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INTRODUCTION
“Connecting passive usages of personal device to some passive income” 1 Global computing power is a critically important resource of our time. While most internet enabled mobile devices sit idle, on standby, they are under-utilized. NATEE’s platform can empower a new generation of smartphone users to earn passive income while awake, or asleep by simply downloading a mobile app. Today’s smartphones CPU/GPU cores are more powerful than most desktop computers, so with Wi-Fi & 4G are ripe for sharing. Intensive R&D projects will pay top dollar for available computational outsourcing of “Big Datai” (petabytes).
Computing power is the critically important resource of our time, yet is mostly untradeable, because it is dispersed across the globe, segregated on businesses servers, or dedicated to personal desktops, laptops and smartphones. While mobile devices’ power is on, they are largely under-utilized, sitting idleii waiting for a call, and especially unused when people sleep.
An innovative way has recently been developed by NATEE to safely capture various parts of your mobile devices’ performance redundantly and with dynamic scalability. It can share memory capacity and processing capacity. The NATEE platform bridges these shared capacities and commoditizes computer power in a coordinated way.
NATEE views your mobile device as a virtual gold mine! There is the precious potential of your smartphone’s CPU / GPU processor core and available unused memory. NATEE estimates to capture 2 percent of the cloud computing market share by creating a disruptive “mobile grid network” to efficiently cope with Big Data with scalability.
THREE-PHASES APPROACH
According to milestones shown in the Road Map section, NATEE will roll out its technology plan in three phases beginning with CPU harvesting of smartphones in the CPU Genesis Phase, and then moving to GPU (Graphics Processor Units) and the GPU Phoenix Phase optimized for renting a smartphone’s GPU for Video Graphics Rendering and advanced A.I.iii machine learningiv tasks. Finally, in phase 3, the Storage Mirror Phase will signal the launch of Decentralized Storage development.
• Phase 1: CPU Genesis Phase: NATEE’s CPU harvesting of smartphones for computational outsourcing on decentralized cloud computing networks.
• Phase 2: GPU Phoenix Graphic A.I. Phase: Graphics Processor Units that already embedded in smartphones, tablets and other mobile devices will be harnessed.
• Phase 3: STORAGE Mirror Phase (Decentralized Storage Mirroring): Distributed Storage across various smartphones and other mobile devices necessarily involves redundancy protection, encrypted privacy, peer-to-peer file sharing protocols, shardingv, and guaranteed retrievability. In this way more, the capabilities and features of mobile devices can be recruited and exploited on the NATEE grid supercomputervi.
"Decentralized file storagevii systems have the potential to eliminate high markup costs and market inefficiencies and provide a much higher level of privacy, reliability and quality of service than we see today." – Vitalik Buterinviii
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All core capabilities of the CPU, GPU and Memory can become golden assets. The value of opportunity is located deep within each device’s heart center and onboard memory banks enabled by device cores and IC “chip sets”.
The NATEE challenge will be to incentivize and engage the community of billions in new ways, to buy into token exchanges for sharing their raw compute power and allowing CPU’s, GPU’s and memory to be exploitable for either charitable beneficence, or monthly profits.
A VAST UNUSED POTENTIAL
Few realize the implications of emerging raw computational powers that modern smartphones now possess. Exceptional core CPUs on the new iPhoneTM or SamsungTM devices “show off” blazing performances with superior GPU (Graphics Processor Units) speeds to 60% of desktop home computers and exhibiting impressive on-board memory as well. The astounding powers of today’s smartphones continue to amaze the public with ever accelerating performance and novel capabilities. The question is how to monopolize on all this?
Distracted and addicted to their smartphones, most users are largely unaware of the potential earning machine inside their pockets (or purses as the case may be!). They often pay top dollar for a latest model smartphone ($1000 USD), only to surrender an associated fee gauging of WIFI or 4G internet access. Yet much of the overall compute power is simply wasted! While Stellar iOS or Android performance is under- utilized, its memory storage can be made available. The opportunity to harness this computing power as part of a coordinated, resilient mobile grid network is immense.
As worldwide demand and competition for compute power explodes, we observe several billions of internet ready mobile devices severely underutilized. They live whilst lamenting a wasted potential for sharing CPU, GPU and storage memory. Aggravating the predicament are expensive solutions such as cloud computing, or grid computing farms (at double the cost of NATEE). Similarly, existing competitors from supercomputers and cluster farms are considered too capital intensive to support large scale R&D and commercial “Big Data” graphics applications. Meanwhile, quantum computing remains an unattainable dream for most.
• for target customers intensive video focus for applications like A.I. machine learning programs and the video & gaming industries requirements for CGIix graphics renderingx. For example, each second of high-definition video, for example, generates more than 2,000 times as many bytes as required to store a single page of text.
GOLDEN OPPORTUNITY FOR SMARTPHONES USERS
Smartphones are severely under-utilized. Like cars in a garage, most of the time these devices sit idle on standby an estimated 90% of the time; and especially as users are asleep. Presently, this untapped compute potential is untradeable and goes mostly wasted. The same for other mobile devices such as Tablets, IoTxi (Internet of Things), FOGxii / Edgexiii routers, and POSxiv (Points of Sale), boxes. Collectively, this pool of latent resources is 1,000 times the size of Amazon’s global cloudxv.
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The same goes for tablets, IoT (Internet of Things) smart devices, POS (Points of Sale) and many other mobile FOG or network edge devices. Desktop computers, while not the present focus of the NATEE target demographic, are no different, they run screensavers languishing without a dedicated purpose while their computing potential is huge.
The average person uses their smartphones 11% of the time, between 2-3 hours per day. So 20+ hours free for grid computing!
The timings and logistics are fully programmable by users, who may want to reserve full access to their mobile devices at specific times such as working hours. However, even during a lengthy phone conversation or mobile video game, a smartphone’s runs well below maximum load capacity, so can still be exploited at these times, on grid.
The NATEE App is intended to exploit these unused performance availability gaps, to bridge multitudinous supply with industry’s growing computational needs. As internet access speeds grow (4G, 5G & beyond) most smartphones are simultaneously connected to Wi-Fi or cell towers. Until now, mobile devices such as tablets, POS, FOG and IoT have NOT been included in the data intensive work unfolding across distributed grid computing networks.
NATEE Systems novel distributed sharing solution can recruit mobile CPU cores from various devices, to render raw compute power. NATEE believes mobile computational outsourcing to grid computing networks is destined to become a next logical future game changer.
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UNDERSTANDING GRID COMPUTING
The goal of grid computingxvi is simply to merge computers and their processors (CPUs) from distributed geographic locations towards a common computational goal. It is a field of 2 computer science that aims to speed up the processing of large datasets by chopping the data into small chunks and sending each part out to a different computer for processing. By running the same software over different compute resources in parallelxvii, tasks that would take years on a single computer can be completed in days.
The term grid computing originated in the early 1990s as a metaphor for making computer power as easy to access as an electric power grid. It was first coined by Ian Foster and Carl Kesselman published their seminal work, "The Grid: Blueprint for a new computing infrastructure" (1999).
It enlists computing resources from multiple locations to share the workloads for a common project goal, usually solving massive scale computations requiring very high core processing power.
Grid computing technology has become a critical resource for many. For example, massive data processing projects physics research (CERNxviii produces 10 petabytes of particle collision data per year [note: 1 petabyte = millions of gigabytes], NASA), and DNA biology projects for unravelling the human genome (HGP), and a growing demand for CGI graphics, sophisticated movie animations with special effects, and the lucrative 3D video game industry. It also helps in modelling the changes in molecular structures, analyse brain behaviour, and compute complex physics models. It is also used to perform weather and economic simulations.
Unlike many ICO’s, the NATEE’s business model demonstrates an immediate path to revenue, with lead customers with committed MOUs, and minimal capital infrastructure to implement the NATEE platform solution
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MARKET SITUATION
It appears staggering that since 2015, the number of computers in the world is more than twice the global human population of 6 billion. Our demand for computing power far outweighs the 3 supply. This scarcity is a growing concern. Big Data analytics is making processing power scarce. Computational demand is on the rise, while a potential exists for billions of Smartphones & Mobile Edge Devices to lend a helping hand. The technical possibility to orchestrate, and social opportunity to participate and earn well deserved profits, is a subject this white paper examines.
In terms of present cloud computing markets, NATEE estimates its target market share to be $7.19 Billion of out a possible $306 Billion cloud computing business. Therefore, roughly 2 percent of the cloud can soon be supplied by mobile phones. However, the overall markets for mobile grid computing comprises all of grid computing networks and render farms.
Workload outsourcing of intensive “Big Data” computation projects is big business for Scientific R&D and the Video Graphics rendering. Massive scale workloads can now be delegate to a multitude of smaller, tiny devices such smart phones, mobile POS (points of sale), SOC (system on a chip), The power of smart phone chips make it all possible, and high bandwidth internet (4G/5G & Wi-Fi) is opening a new paradigm never possible. High profile, mass computation projects like CERN, AI Machine learning, the human Genome projectxix as well as video games and 3D movie CGI rendering.
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PROBLEM STATEMENT
Global demand for computational power appears insatiable, and the supply problems is worsening. It is a precious commodity and vital asset, yet difficult to access or trade since no 4 micropayment system exists. Profit potentials in computational outsourcing are unfairly controlled. Science research projects and citizens needs help.
WASTED CPU CORE, COMPUTE POWER CANNOT MONETIZE LOST POTENTIAL UNTRADABLE
There is currently no way for private individuals to rent their smartphones for computational outsourcing income. The average person’s mobile device contains enormous hidden potential, but computational power goes to waste when idle, and over 2 billion smartphones languish on standby. Even if this alienated compute potential could be harvested, there is no sharing ecosystem to facilitate trade or economic earning. Monetizing raw compute power appears an impossible dream.
BIG DATA CAPACITY ISSUES, SCIENTIFIC RESEARCH ZETTABYTES & GROWING… SLOWDOWN PARALYSIS…
Cloud computing, and traditional on-premises centralized IT services will not be able to handle the tsunami of massive Big Data on its way. An order of magnitude increase in big data is expected to paralyse many intensive computation operations soon. Vital scientific analysis, modelling and simulations are desperate for compute resources. Speeding delays can save lives, with breakthrough medical cures. We need compute conservation and re-use options.
CENTRALIZED CONTROL OF CLOUD MARKETS & GRID COMPUTING
Centralized businesses frustrate smartphone owners who have extra performance capacity to offer, but no easy way to participate. Access to markets for “computational outsourcing” are closed to average
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people, and big corporations control prices and supply. A lack of technology for CPU scavenging and sharing is missing for the average citizen.
EQUALITY OF OPPORTUNITY, ECONOMIC SUFFICIENCY ACCESSIBILITY, REDISTRIBUTION CLASS CONSCIOUSNESS
Lower-middle income classes struggle to earn income. Sometimes a little goes a long way. Enlisting their mobile devices could help. The is no easy way to donate compute power to good causes like scientific research, or sufficiency economies. The average person in their daily lives is alienated from access, and opportunity to participate their mobile compute resources.
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SOLUTION OUTLINE OF THE VISION
By leveling a tilted economic playing field, blockchain innovations have a power to create financial freedoms, tokenized micropayments, and thus an opportunity for ordinary people to 5 prosper. Unleashing smart phones on grid computing markets has mass potential, and can earn immediate revenue streams for all classes of people.
MOBILE DEVICE BRIDGE PLATFORM
NATEE has built a bridge to huge profits, which can now be shared by everyday people with a mobile devices and internet. A smartphone’s CPU core computing and storage are often severely under-utilized, and so offers a great potential for CPU harvesting profits. Now earning income from the NATEE platform across grid computing networks at any time their mobile device is turned “on” and connected to the internet. Profits come even if the device is in use, or the smartphone user is asleep.
PUBLIC SUPERCOMPUTER - ACCELERATING BIG DATA R&D PROJECTS
NATEE’s aims to accelerate Big Data processing for both science and commercial applications. Supercomputers are common tools for accelerating scientific research, or various profit driven projects. Billions of smartphones can combine in unison to yield super-computing powers worth millions of dollars per minute! It is an idea whose time has come! Simulations can be made easy for A.I. or CGI movie graphics, and modeling cures for various cancers by accelerating R&D tasks. It is important work that may save lives, so it is vital to assist in any way.
MONETIZING COMPUTATIONS WITH NATEE TOKENS
Leveraging blockchain’s DLTxx can safely monetizes raw compute power harvested from mobile devices. Tokens earned, shared, exchanged for fiat cash, can also be donated to science. Since anybody can participate, centralized control is shattered; corporate “compute cartels” disrupted.
DISTRIBUTED COMPUTE POWER ON GRID NETWORKS SERVERS
NATEE’s orchestrated mobile network is distributed. Shared mini-gadgets (smartphones, tablets, IoTs) offload big data projects that often pay millions of dollars to complete. Grid management servers are the brains for dynamically assigning tasks in small, manageable “bite sized” parallel processes. In this way processing can become truly distributed across a global grid network. Sharing was never so easy! The power of the many outweighs the few.
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EMPOWERING EQUAL OPPORTUNITY – EARNING FOR ALL CLASSES
A small handful of elites control the prosperity and economic realities of the majority. The blockchain community has been yearning for a new kind of Autonomous Digital Sharing Economy based on DLT and SEP. Everyday people seek an authentic open ecosystem that works for everyone – even newcomers to smartphones. The ability to freely partake in the lucrative computational outsourcing industry is a social justice issue. NATEE is emphasizing the need for egalitarianism society with equal opportunity and low barriers of entry. Our priority is to derive profit for the less fortunate, while giving to science. NATEE’s platform and mobile app can elevate lower-middle class lives to greater prosperity.
Popularizing the use of the NATEE system will proliferate early adopters, and the habitual usage by participants. A worldwide deficit of compute power can thus be alleviated, while enabling small incomes for millions of mobile device owners; more than enough monthly income to pay their mobility service provider bills.
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NATEE’S APPLICATIONS FOR BIG DATA
Corporations and scientific researchers foment Big Data by capturing trillions of bytes of information. These massive pools of data are captured every second, to be communicated, 6 aggregated, stored, and analyzed. Humans have the unique ability to develop insights, review data, determine next steps, and think creatively. In contrast, computers excel at processing, storing and explaining this information.
Big Data is a category applied to a wide range of uses, in a wide range of industries and efforts. There is no single big data product or application or technology. Big Data is defined simply as datasets that can't fit into a simple database network because they are too large to handle. Usually petabytes of data need to be filtered, groomed and worked on well after it is sampled; in other worlds asynchronously. Examples include R&D projects that analyze massive datasets, often from live streams. Other applications run simulations or model the lives of users, environments, climatology, or specific demographics and historical operations. From social science to pure science, the amount of data in our world has been exploding.
Grid computing customers spring from diverse Big Data industries. These buyers include “data intensive” mega scientific research programs, and big entertainment companies with massive CGI, graphics and rendering needs such as movies, video games, etc. This kind of large-scale work is too cumbersome to do in-house, and so 3rd party rendering companies are often needed. Examples include:
1. A.I. Machine Learning
2. 3D animation market. data intensive CGI graphics and videogame renderings
3. Scientific Data Analysis: massive data crunching for analysis, modeling and simulations Scientific R&D projects the same story is also true for data storage demands.
4. Decentralized and blockchain-based applications.
5. Video rendering on CPU/GPU Instant access to top consumer-grade GPUs, currently occupied in crypto-mining. CDNxxi and video streaming
6. Geo distributed resources available in any ISP all around globe. A content delivery network or content distribution network (CDN) is a geographically distributed network of proxy servers and their data centers.
7. Scientific calculations: Raw power to crunch numbers on CPU and GPU.
Essentially these projects arrive anywhere big data analysis is in demand, custom processing needed, and the puzzle can be partitioned into tiny “bite-sized”, parallel tasks, and simultaneously shared for solving.
There are presently two paradigms by which this process works: grid computing and cloud computing.
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BUSINESS MODEL
The NATEE business model is decentralized. It threatens to disrupt today’s powerful corporate cartels involved in cloud computing, and grid computing. Private individuals can now partake in 7 compute resource sharing directly with R&D projects, bridged by NATEE. This supercomputer grid and blockchain profit sharing scheme is an attempt to reverse a centralized business model. The sincere hope is to redistribute profits from large corporate giants to vast numbers of people. Freedom of opportunity can then flourish for the common person.
The selling of computational power is big business. The typical end customer who can buy, and best leverage NATEE’s computational outsourcing work are “Big Data” clients. These are the scientific and commercial entities who traditionally have deployed their own supercomputer clusters, or otherwise rented grid computing services. The latest applications in the greatest need of compute boosts include A.I. Machine Learning, Scientific data analysis, Video Rendering in gaming and CGI movies, – all suitable candidates for compute outsourcing on distributed grid computing networks.
WHO ARE THE BUYERS?
Astoundingly, the estimated the market for “computational outsourcing” is a $300 Billion / year, and growing. Our hope is to convert between 2%-10% of the world’s compute market, meaning $7 Billion out of an estimated $300 Billion annual compute sales. This group includes mainly a specialized niche of asynchronous “Big Data” projects that are not time-sensitive. In this way, the numbers can be crunched whenever significant
The cloud refers to homogenous servers in data centers that single entities like Google or Amazon manage. The grid is a group of heterogeneous machines in offices and homes that different economic actors manage. NATEE intends to outsource a smartphone’s core computational powers onto managed grid computing networks.
An example of NATEE’s income, a 1GHz smartphone can expect to receive $30 USD per month.
Mass distributed computational outsourcing projects that can leverage mobile devices are poised to become a new public norm within the NATEE ecosystem. Voluntary donations to scientific research are expected to become a more popular trend, and tokenized profit taking another tendency. Sharing resources within a decentralized unified community builds social capital; a beneficent act that can elevate those in need.
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ACHIEVABILITY
Computational outsourcing is already a proven business model, and so NATEE’s supercomputer partakes in a grid computing networks to solicit donations, find paying customers, and ultimately to accelerate scientific research and commercial applications for the betterment of mankind.
Those who volunteer their smartphone CPUs to the NATEE cause will be rewarded handsomely, and feel proud if they opt to donate proceeds from their 1 GHz smartphone idle times to NATEE’s selected medical research programs.
As the example illustrated on the above diagram, the fact that the Cloud Platform cost twice as much as NATEE aforementioned it entails that we have more room for profit margin, whilst the above pricing would still be competitive.
This core computational power can be immediately sold, and the business model validated. Once this mobile supercomputer concept is proven in a few ASEAN countries, the model can then grow organically to include more than 100 countries worldwide.
GO-TO-MARKET STRATEGY
A pre-existing smartphone user network infrastructure is poised to earn millions of dollars of profits by delivering this needed computational boost, at a considerable cost savings compared to Cloud and other Grid Computing Farms competitors.
NATEE can leverage its partnerships to immediately bridge 700K registered users to prove the concept, and launch further successful pilots. NATEE intends to go live soon, by harvesting these 700K cores from its first business partner, to build a massive distributed supercomputer from a single country, beginning with Thailand and will grow rapidly in ASEAN region where about 3 billion mobile devices estimated.
ACTIVE MEMBERS OF NATEE GRID Supercomputer Participants
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In Game and SDKxxii roll-out. NATEE’s Go-to-Market strategy involves App Game Roll Out is recruiting pre- existing user base using mobile apps of all kinds, and deployed ubiquitously, across a wide scale with accessibility and ease of use.
NATEE is taking a chunk out of the $300B+ Cloud Computing Market. We are introducing real, market- based pricing for computing resources into the $100B+ cloud-only computing market.
By freeing mobile devices for computational outsource work, NATEE is building a powerful supercomputer for public use. It can bridge a tremendous potential from millions of smartphones, tablets and other internet-enabled devices. A people’s supercomputer is designed to merge the collective powers from millions into a single, shared and unified platform ecosystem. NATEE Systems has created a new paradigm in wireless interconnectedness (Fog/Dew Computing network) with mobile device sharing, the same time a way to enable voluntary donations towards Big Data grid computing projects.1
NATEE has built the NATEE Platform Alpha version, and rigorously tested its mechanisms.
1 See “The Boinc System” & “Boinc Under NATEE System” diagrams on page 22 Page 16
NATEE COMPANY AND RESEARCH
Grid Computing research is a fascinating area of expertise. Many experiments are conducted to test theories and new compression algorithms is areas such as load balancing, 8 redundancy. Among the many challenges of mobile grid computing are device management, asynchronous collaboration, data protection (redundancy & encryption), discovery, provisioning, entitle/secure, deployment, monitoring, repair/respond, and metering. DVFS (Dynamic Voltage and Frequency Scaling) and DPM (Dynamic Power Management) for reducing energy consumption in processing units for Parallel/Distributed Systems
NATEE plans to be the world’s first Mobile Device Computational “Grid Network” to unleash the combined powers of millions of smartphones, earning tokens for “Big Data” processing. NATEE solves big data deluge by orchestrating mobile users to perform across a Grid Computing distributed network that is open to anyone!
Building the global market for compute is an ambitious mission. The NATEE team has proven our ability to design, develop, productize, market, deploy and support distributed computing solutions for a global audience.
NATEE has built the NATEE Platform Alpha version, and rigorously tested its mechanisms.
NATEE TEAM & SINGAPORE RESEARCH
NATEE is a Grid Computing research project under commercialization by Singapore’s “Seitee Pte Ltd” (UEN 201713603R) and is supported by National University of Singapore (NUS) Enterprise Incubation Programme.
The NATEE team is comprised mainly of former and current faculty and … team members who are grid computing specialists, and blockchain veterans from Switzerland and Canada from diverse backgrounds in the banking industry, semiconductor design, e-commerce, securities fund investing, and network engineering. Their cumulative experience is broad and based upon past success.
Over the years, the experienced NATEE staffs have developed many mobile apps for many satisfied customers. The team is highly experienced in diverse technology sectors such as software coding, video game development and fintech payment systems. The NATEE team is well positioned to succeed in computational outsourcing, with a motivated and highly experienced team. NATEE is leverages decades of experience in wireless communications, banking payment systems, e-commerce platform development and more recently in blockchain deployments.
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KEY SUCCESS FACTORS UNOBTRUSIVE PERFORMANCE 9 NATEE users mandate their mobile smartphones are not interrupted, or interfered with. NATEE’s Grid Management software monitors a device’s performance, so not matter what is going on in the device, it stays out of the way.
BATTERY DOES NOT DRAIN or OVERHEAT Efficient and hassle free
NATEE users mandate their batteries will not drain, and their devices do not overheat. NATEE has mechanisms in place to ensure this does not occur.
PRIVACY SECURED NATEE Secure, community trusted Anonymous Sharding
As a client, NATEE users need absolute assurance their phones will not be hacked and their private information not violated. The NATEE’s SDK and platform is designed only to harvest the computing resources and nothing else. This means there is a protection assurance that personal information will never be neither access, nor shared. In fact, the software cannot access personal data. Security experts constantly test the system for vulnerabilities to the latest threats.
INTELLIGENT AND COST EFFECTIVE
NATEE’s system shared compressed data packets for computation, and the downloads and uploads happen only after the computational tasks have been completed, in short, NATEE focuses on get competing devices working offline to mitigate side effects on a data plan’s limits. Again, research tasks and uploads results when users are connected to a wireless network (WIFI).
SMART CONNECTIVITY
The core concept and real benefit of mobile devices compared to a personal computer (PC or Laptop) is the mobility. While cloud services have been made available everywhere, yet, the connection’s latency occurred between devices to the cloud is still the great concern. The central component of NATEE’s infrastructure is the NATEE Lookup Service, which offers NATEE clients a flexible and powerful way to enables clients to locate and enlist the help of those services. Each mobile device in NATEE network will be able to communicate and transmit data/tasks/results independently by using Fog/Dew computing instead of the cloud computing.
POWER IN NUMBERS
Millions of smartphones working together in harmony can outperform the same mega-tasks as a powerful world class supercomputer.
Unlike the cloud or other supercomputers, NATEE’s will redistribute the prosperity from compute capacity derived from its user’s mobile devices, the smartphone’s CPU potential. Harvesting the core CPU power will be a blessing for Big Data computational projects.
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BLOCKCHAIN TECHNOLOGY
A vital DLT and the NATEE token are the necessary medium of exchange for raw core processing power, within a tradable tokenized ecosystem. This builds a brand-new revenue stream for the lower-middle income participants. NATEE is aware of class conscious allocations that make sense in terms
FUTURE OF MOBILE GRID COMPUTING
In today’s radically interconnected world, NATEE is focused on bringing Grid Computing to new places it has never seen before. NATEE’s supercomputer will bridge consumer mobile devices, such as smart phones. It is now possible for almost ANY electronic devices with a microprocessor chip to be recruited into the process. Ever-increasing processing power2
Massive scale workloads can now be delegated to a multitude of smaller, tiny devices such smart phones, mobile POS (points of sale), SOC (system on a chip), The power of smart phone chips make it all possible, and high bandwidth internet (4G/5G & Wi-Fi) is opening a new paradigm never possible. High profile, mass computation projects like CERN, computation projects (like the AI Machine learning, CERN, the human Genome) as well as video game rendering… Disneyxxiii can now be outsourced to personal, private mobile smart phones.
NATEE MONETIZATION SDK
NATEE allows its business partners to monetize their apps in one easy step. Our lightweight SDK offers an efficient execution of distributed/sliced tasks without affecting the performance of the apps. With no ads, this will gain user’s satisfaction/experience on NATEE’s business partners apps, an alternative to Advertising Network’s SDK.
2 https://en.wikipedia.org/wiki/Comparison_of_smartphones Page 19
NATEE ECOSYSTEM
The NATEE ecosystem gives participants a chance to monetize their smartphone’s computational potential with tokens, and redistribute profit for public good. Targeting 10 mobile devices distributed across the globe, the NATEE platform transforms compute performance into a tokenized, and tradable asset. It enables smartphone owners to morph into a unified profitable supercomputer, marshaling similar mobile devices (IoT, POS, tablets) to engage in parallel computational tasks that support big data processing programs. Many of NATEE’s chosen applications nourish our greater public good by medical research require compute power boosts to accelerate scientific R&D modeling & simulations.
NATEE ecosystem enables tokenization, and so becomes a disruptive way to redistribute earning potential to lower-middle class participants, desiring to monetizes their smartphone’s compute power. The ecosystem is unique in that tokens and monetized compute power can be shared, donated and earned by the community of smartphone users. NATEE’s supercomputer will utilize blockchain’s DLT technology to track donations and profit sharing for its grid computing outsourcing
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NATEE ARCHITECTURE
We are committed to bridging a gap in available, yet isolated, supply of compute power (distributed) with a surging demand for Big Data Computational R&D projects. Compute 11 power is an unsatiated need in our computer age, spiraling out of control, but needed for society to flourish.
NATEE has refined a platform for mobile grid computing than can assist with worldwide compute supply, conserve valuable resources and alleviate digital bottlenecks. For the first time, billions of mobile devices can participate in “computational outsourcing” over grid networks. NATEE empowers people across all classes of society, both techies and neophytes, in an egalitarian pursuit to share profits by a collective pooling of smartphone resources.
THE SUPERCOMPUTER - HOW IT WORKS
NATEE’s key challenge has been to build a platform and middleware optimized to immediately bridge many millions of mobile devices via the web, many of which sit idle or are underutilized (e.g. smartphone users are asleep). The final product will transform great numbers of small mobile devices, into a gigantic coordinated supercomputer optimized for holistic, large-scale grid computing services.
It’s unique architecture does not require mainframes or cloud server farms. Instead, it aggregates a mobile devices computational power, harvesting CPU core capacity within millions of smartphones. NATEE’s innovation will bridges people’s alienated compute supply for science and revenue sharing.
NATEE’s HPC (High Performance Computing) technology is scalable to encompass potentially billions of mobile devices worldwide. This business model rewards the average lower-middle class owners of smartphones, instead of exclusively the few elite owners of big server farms, or the transnational corporations that provide cloud computing services.
Most of this vast processing power can be harvested from available smartphone CPUs, but can also include a blend of tablets, IoT’s and countless other internet ready, and underutilized mobile gadgets. This tremendous compute capacity can be managed by NATEE’s grid computing middleware (open sourced), and operate on common grid computing networks optimized for sharing with asynchronous, parallel processes.
The NATEE Mobile grid can be thought of as an online, distributed system with non-interactive workloads that involve many files. NATEE’s platform and grid management software is optimized for geographically dispersed “Big Data” workload outsourcing. It is proficient at controlling the heterogenous flow of information in terms of the four “V’s” of mobile device data transfers: Volume, Variety and Velocity and Veracity.
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Grid Computing ties together available storage and is already providing resource efficient, self-healing, replicated drives for 30,000 users across 158 countries. It leverages available compute, deploying software onto the right computers at the right time, while providing transparent failure detection, recovery, scaling and load balancing.
As a proud supercomputer design unlimited scalability, it is different. It can bridge computational power harvested from virtually any mobile device across the internet: smartphones, tablets, or IoT devices. Its architecture uses custom software, open source middleware and private grid computing management servers and that can deliver powerful computational boosts over grid computing networks.
The novelty with NATEE is that it implements a fully distributed mobile networking protocol to implement a new kind of Grid Computing Network, with Grid Serves (each controlling 20,000 devices) optimized for task delegation in parallel multi-layer processing. Outsourcing of workload occurs asynchronously and independently with processing of atomized data puzzles amongst distributed peers.
The NATEE system takes advantage of the OpenGL, the open sourced grid management software. The blockchain of the future has been lab simulated and verified to be orders of magnitude faster, and infinitely more scalable than what presently exists. More distributed than conventional, merely decentralized blockchains, NATEE’s mesh blockchain network utilizes innovative data handling techniques and architectural advantages including:
• OpenGLxxiv
• BitTorrent-like Protocol for Data Sharing (MDHT: Mainline Distributed Hash Table)
• Grid Computing Compression Algorithms
• Load Balancing
• IPFSxxv (The Distributed Web [internet])
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• Redundancy & Fail-Safe Mechanisms.
• Supports additional devices like Android, PlayStation and Xbox.
CORES AT WORK
Putting the smartphone’s under-utilized semiconductor cores to work at full load, and overtime, is how maximum tokenized profits can be rewarded. The devices internal system will manage predictable overheating, while the NATEE’s SDK manages parallel jobs streams and task allocation. Each task is connected to the mobile grid computing network for autonomously sharing workloads. Shared cores can independently operate at different locations, yet focus to perform a specific task towards a common larger goal. Whether the cores are shared from desktops, mobile devices such as IoT, a smartphone or POS, the unused processing and storage capacities can be recruited by NATEE for tremendous effect.
THE NATEE PROPRIETARY ALGORITHM
At the core of the platform is NATEE’s proprietary algorithm. Much of the code is written in C++ and involves the necessary optimization of data flow. The NATEE algorithm prioritizes effective load balancing, data sharing and data compression algorithms.
A versatile, ultra-efficient data handling network custodian. Cleverly shifting between devices, servers between parallel processes, and recruiting the processing engine to significantly reduce bottlenecks.
The NATEE Mobile grid management software has also been designed for scalability, it can manage large scale distributed networks with speed, ease and grace
PARALLELISM
Computational grids solve processes that run in parallel, meaning the process’s calculations run independent of one another. To parallelize an application, 1) split a single job into independent subtasks that can be individually run, or 2) split the job at a group level. Monte Carloxxvi simulation is one use case. If a process’s calculations depend on previous calculations, the process is said to run in serial.
THE ARCHITECTURE COMPONENTS
The architect of a computer grid must consider not only the types of computing resources available (such as specialized mobile nodes: smartphones, POS and IoT) but also their average core speed, location,
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memory and storage requirements, along with the throughput and bandwidth available between these such as network speed and size. On top of this is the requirement for specialist grid software to assign processes, monitor performance, and manage resources. We can decompose the challenges of grid into seven major functions: discover, provision, entitle/secure, deploy, monitor, repair/respond, and meter.
Harnessing the power of heterogeneous technologies in one unified solution is not easy. Once the grid platform is stabilized (resources discovered, homogenized, provisioned, and secured), then the problem (or tasks) must be parallelized, deployed to the grid, and monitored (optimized, tracked, and controlled). The results sets must then be collected, integrated, and presented to the user. There also needs to be a way to respond to technological problems within the grid and repair them seamlessly.
FILES AS ENCRYPTED SHARDS
A shard is a portion of an encrypted file to be stored on this network. Sharding has many advantages to security, privacy, performance, and availability
Sharding large files like video content and distributing the shards across nodes reduces the impact of content delivery on any given node. Bandwidth demands are distributed more evenly across the network. In addition, the end-user can take advantage of parallel transfer, like BitTorrent [2] or other peer-to-peer networks.
Bite Sized Puzzle Pieces: Shard size is a negotiable contract parameter. To preserve privacy, it is recommended that shard sizes be standardized as a byte multiple, such as 8 or 32 MB. Smaller files may be filled with zeroes or random data. Standardized sizes dissuade side-channel attempts to determine the content of a given shard, and can mask the flow of shards through the network.
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NATEE PLATFORM
An uber-efficient mobile grid platform does the dirty work by recruiting idle smartphones, slicing the data pie, managing progress and re-assembling all the pieces of the 12 computational puzzle back together in parallel, much like a BitTorrent protocol. The NATEE ecosystem assigns utility tokens a value purely for raw computational power.
The platform handles prolific workloads by diligently harvesting large volumes of smartphones, and potentially billions of other mobile devices what compatible with C/C++ (Unix/BSD) Compiler (such as IoT device, POS terminal, smart watches) as part of a coordinated effort for processing Scientific Analysis, Graphics Rendering, CGI Movies, and A.I. Machine Learning and video games. Instead of the expensive outsourcing of this work to the cloud, or custom supercomputers, deploying to an economical Mobile Grid Network to number crunch “Big Data” saves needless upfront capital costs.
The NATEE software looks and acts like a single program, but it's actually made up of several separate programs:
The schedulers and data server programs are installed on computers owned and managed by the projects to which you will donate time on your computer. The programs in the green box will be installed on your computer. • The core client (usually referred to as the client, named boinc.exe on Windows) communicates with external servers via the HTTP communications protocol to get and report work. The core client runs and controls applications. • Applications are the programs that do scientific computing. Several of them may run at the same time on a computer with more than one CPU.
The GUI, (usually referred to as NATEE manager or the manager, named boincmgr.exe on Windows) provides a graphical interface that lets you control the core client - for example, by telling it to suspend and resume applications. The GUI communicates with the core client by a TCP connection. Normally this is a local connection; however, it's possible to control a core client remotely.
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SDK FOR MOBILE APP
The NATEE integrated mobile app is easy to download for Android and iOS. Other potential network edge devices which be recruited in the NATEE grid network include IoT and mPOS (mobile points of sale). NATEE’s proprietary platform has a lot to offer in terms of power, scalability and ease of use. It provides a clever bridge to empower anyone with a smartphone to profit from the lucrative grid computing space.
The NATEE constellation will be a marketplace where people can sell items for free on their versatile mobile devices which are fully e-commerce platform enabled! The quickest way to access crypto funds, with the most trustworthy fiat/crypto exchange payment vehicle on the planet to make e-commerce safe, easy and fun. Furthermore, a plan is in place for a viable global 10 million node NATEE ConstellationTM - the meshed backbone of a genuinely distributed Grid Computing blockchain network ecosystem (not merely decentralized).
BRIDGING SERVERS
The NATEE platform is designed to work with “big data” by bridging intense analytical workloads with eager owners of working smartphone, and other mobile devices. This platform bridge can combine the unused computing resources of millions of small mobile devices, such as the GPU and CPU cores of smartphones, towards a common goal workload outsourcing for lucrative, large-scale computing and data intensive projects. It uses specialized grid management software and grid servers to optimize the workload sharing. By bridging smartphones with distributed grid computing networks, vast numbers of non-technical people from all classes of society can participate, to earn decent profits by simply clicking “Yes” to become active members
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GRID MANAGEMENT
Grid management software is needed to manage velocity, variety and volume of data. Anyone with a smartphone can participate by downloading NATEE’s mobile bridge App 13 for “computational outsourcing”. The goal of the platform is a delivery of intense computational work for accelerating large-scale projects – such as mass data processing for scientific R&D, or video renderings for GGI & gaming. Sharing idle smartphone time, and often unused mobile devices & FOG network resources, such as IoT or POS, can greatly assist a multi-billion-dollar industry reach greater heights, and satisfy their ever-growing computational needs.
KEY STEPS
Discover, Provision, Entitle / Secure, Deploy, Monitor, Repair / Respond, Meter, Schedule, Place, Optimize, Track, Abort;
• CPU - number of central processing unit cores
• RAM - amount of random-access memory
• GPU - number of graphics processing units
• Storage - hard drive capacity
• Connection incoming - maximum incoming network traffic
• Connection outgoing - maximum outgoing network traffic
• Network type - admissible connection (in/out, out, no)
• Properties - special user's properties of resource devices, pairs of values: (name: value).
ROBUST COMPUTING WORKLOAD MANAGEMENT FOR MOBILE DECENTRALIZED COMPUTING SYSTEMS
A. General Mobile Decentralized Cloud Computing System
We consider a mobile decentralized cloud computing system (Figure 1). The system is composed of mobile computing units, e.g., smart phones with available CPU, GPU, memory, and other computing resources. The computing units run the NATEE platform (https://NATEE.io/) for receiving and processing computing workload submitted by application users.
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B. Reliability of Mobile Computing Units and Uncertainty
However, the computing units have different reliability levels. For example, if the computing units have a constant energy supply, e.g., power outlet, and a high speed wireless connection, e.g., Wi-Fi, the computing units are considered to be highly reliable. The highly reliable computing units have a high probability to finish processing the computing workload from the users. However, if the computing units use energy from its own battery and rely on a broadband cellular connection, the computing units are considered to be lowly reliable. They have a low probability to finish processing the computing workload as they can be disconnected anytime.
C. Computing Workload Manager
Given the reliability levels of the mobile computing units, the computing workload manager is introduced to support the NATEE platform to achieve the robust mobile decentralized cloud computing service. The functions of the manager are as follows:
1) The manager recruits computing units and classifies them into different reliability levels. The reliability classification can be based on the historical data and machine learning to estimate the reliability level.
2) The manager makes a contract/agreement with the recruited computing units, i.e., to reserve the computing resources. Upon the reservation, the group of the mobile computing units charges a certain price to the manager. The price depends on the reliability level of the mobile computing units. For example, the higher reliability has a higher price. However, when making the reservation, the manager does not know the exact computing workload demand from the users.
3) The manager collects computing workload from the users, and the total amount of workload, i.e., exact demand, is known.
4) The manager optimizes, assigns the workload and monitors the processing from different groups of computing units.
5) If the workload processing fails to finish, the manager has to execute a recovery plan by reassigning the workload to a guaranteed computing services, e.g., public cloud services. To handle the failure, certain costs are incurred, e.g., due to delay compensation paid to the users and/or additional prices paid to the guaranteed computing units. The computing workload manager aims to minimize the costs. On the one hand, the manager may assign workload to the lowly reliability computing units with a cheaper price, but it will risk the additional costs due to workload processing failure. On the other hand, the manager can assign the workload to the highly reliable computing units, paying a high price with the low risk of processing failure.
D. Robust Workload Management
To achieve the objective, the computing workload manager performs the robust computing workload management algorithm. The algorithm solves the following problem:
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where
• 피 [∙] s the expectation. • 푷풎 is the price charged by the group of computing units with reliability level 풎, where 푴 is the set of all groups.
• 풙풎,풊 is the computing workload from user 풊 assigned to the group of computing units with reliability level 풎, where 푰 is the set of all users.
• 푪풊,풔 is the penalty cost incurred to the workload manager if the workload of user 풊 fails to be processed, and the recovery plan 풔 is applied. 푺 is the set of recovery strategies.
• 퓨풊,풔 is the amount of failed workload of user 풊 that the recovery plan 풔 is applied.
• 푫풊 is the total computing workload from user 풊.
• 휶풎,풊 is the ratio of the workload from user 풊 that fails to be processed by the group of computing units with reliability level 풎. 휶풎,풊 is a random variable which can be regarded as a “scenario” of the unknown event.
• The objective in (1) is to minimize the expected costs of the manager. The first cost is due to allocating a certain amount of workload to a group of computing units with different reliability level. The second cost is due to the failure of workload processing when different recovery plan s is applied.
• The constraint in (2) ensures that the allocated workload to the groups of computing units must be greater than or equal to the demand from the users.
• The constraint in (3) ensures that the amount of workload failed to be processed will be all recovered by one of the recovery plans.
The algorithm first converts the problem in (1)-(3) into the deterministic equivalent problem and then ∗ ∗ evolutionary intelligent methods can be applied to obtain the decisions 훼푚,푖 and 풴푖,푠.
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Incentive Mechanism for Mobile Decentralized Computing Systems 14 In the mobile decentralized cloud computing system, the computing units run the NATEE platform (https://NATEE.io/) for receiving and processing computing workload submitted from application users through the computing workload manager. For the mobile decentralized cloud computing system to be economically sustainable, the computing units will receive an incentive in the form of money, credit, and token upon finishing the workload processing from the workload manager. Figure 2 shows the typical procedures of workload allocation and payment.
1. A computing unit registers itself to the workload manager to inform that the computing unit is active and ready to receive and process workload. The registration by the computing unit includes the information about available resources, estimated active time period, the price per resource and time unit, etc. Here, the resource price is the acceptable incentive that the computing unit is willing to accept and process allocated workload from the manager. The workload manager continually monitors the status and maintains the connection with each registered computing unit.
2. Once the manager receives user’s workload, it performs the workload allocation considering the resource price submitted by the active computing units. The workload manager requests for the computing resource not more than the available resource at each computing unit indicated during the registration. If zero resource is requested, the corresponding active computing unit will not process the workload.
3. The workload manager then assigns the workload and waits for the processing results from the computing units.
4. The computing units return the computation results to the workload manager, and the workload manager verifies the results and makes the payment to the computing units according to the amount of allocated workload.
Clearly, the workload manager acting as the buyer buys computing resources from the computing units acting as the sellers. The incentive mechanism for the workload manager and computing units are developed to answer two major questions 1) what would be the resource price that the computing unit sets to maximize its profit and 2) which computing units and how much their resources that the workload
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manager buys to maximize its utility. To answer these questions, we introduce the hierarchical game theoretic incentive mechanism framework that allows the workload manager as the buyer and the computing units as the sellers achieve their own objective. In this case, the computing units determine the resource prices before the workload manager decides to buy the resource. Hence, the former is the leaders and the latter are the followers in the incentive mechanism framework.
The formal definition of the incentive mechanism is given as follows.
1. Workload allocation and payment by workload manager: Given the resource prices registered by the computing units, where pi denotes the price of computing unit i, the utility of the workload manager is defined as follows:
where • 풔 is a set of total workload or computing resources allocated to all the computing units, i.e., 풔 = ∑풊 풔풊 , 풔풊 is the amount of workload allocated to computing unit 풊. 풔풊 can be interpreted as the resource demand by the workload manager.
• 풇 (. ) is the function describing the relationship between the workload valuation and the total computing resources.
The workload manager aims to maximize 푈 (푠, 푝) by optimizing 푠푖, i.e., resource demand.
2. Pricing by computing unit: Given the resource demand 풔풊, i.e., resource demand, from the workload manager, the computing unit aims to maximize its profit which is defined as follows:
where 풆풏풆풓품풚 • 푪풊 is the energy cost of computing unit 풊.
• 풓풊 is the processing speed of computing unit 풊. 풄풐풎풎 풎풊풔풄 • 푪풊 and 푪풊 are the communication cost and other cost of computing unit 풊, respectively.
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NATEE RESEARCH COLLABORATION WITH NTU
Seitee Pte Ltd and Nanyang Techological University of Singapore having research collaboration in the topic "Algorithm Design of Mobile Decentralized Computing Systems" 15 which started on October 1st, 2018. The main purpose is to assess and optimize mobile decentralized computing systems.
The research will focus on algorithm design and scalability evaluation of NATEE, Seitee’s decentralized computing systems. The research plans to develop resource management algorithms for decentralized computing systems to support distributed mobile machine learning and to apply the algorithms and incentive mechanisms with real machine learning applications.
The followings are the details of the research project use case
1 2
3 4
5 6
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TOKENOMICS THE NATEE TOKEN
The ecosystem assigns utility tokens based purely on the value of raw computational power. Each token represents FLOPS, or MIPS (millions of instructions per second) which 16 have a value in the real world, and on the open market. Thus, NATEE is creating a new consumer market economy for exchange. Therefore, a NATEE token has the utility of core computation within a grid computing network, and empowers NATEE to monetizes CPU & GPU cores processing capacity. The raw computational power needed for large-scale projects can be monetized into the NATEE token for donation, purchases by science or industry, and profit-taking by the registered public users.
The project highlights a tokenized ecosystem to harness and unleash the collective powers of the world’s mobile computing devices in a coordinated way, for efficient use. Many millions of smartphone users can now participate together to earn passive income by contributing to large-scale “big data” processing projects. NATEE will only focus on mobile devices (not PC, not laptop) for its crowdsourcing.
NATEE UTILITY TOKEN
Within tokenomics, the word utility is most often defined as "use case." From NATEE’s perspective and business model, the NATEE Token has 3 compelling use cases: • USE CASE 1: COMPUTE POTENTIAL: It is a utility token for Raw Computational Power. Within NATEE’s Ecosystem the token enables liquidity for compute power. The exchange of each computational unit will depend on market forces (supply and demand) and other conditions. Outsourcing of compute potential from mobile devices through NATEE’s Supercomputer and Bridge Platform creates a new market, allowing people of all socio-economic classes to access revenue with smartphones. • USE CASE 2: NATEE ICO PUBLIC SALE: A means for self-funding - the ICO. A way to fund development activities (see milestones, roadmap and timeline) through crowdfunding. A payment vehicle for startup services, salaries to support these activities. This process reduces the need for venture capital and establishes a direct relationship between NATEE and an open field of crypto investors. There is a SAFTE (Simple Agreement for Tokens or Equity) seed funding and/or private sales involved, but it is the public sale that will generate the most capital. Recently, Goldman Sachs issued a report noting that
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token sales have eclipsed venture capital as the primary source of funding for early-stage tech companies. • USE CASE 3: A TRADABLE DIGITAL CURRENCY AND PROGRAMMABLE ASSET: It was difficult to have automated, speedy, secure global payments before digital currency came into existence. As cryptocurrency, the NATEE token can trade or share units of computational power. The NATEE token will do whatever it is programmed and to continue to perform that function if the network is active. This is made possible by NATEE’s deployment of trustworthy smart contracts with digital ledger record- keeping.
"Tokenomics” is defined as: (1) a means of self-funding within the crypto economy, (2) the deployment of a token within the ecosystem of an ICO project and (3) the set of all economic activity generated through the creation of tokens.
TOKEN FLOWS
Within the ecosystem, the token flows permit NATEE to issue tokens to valued partners such as 3ND who are committed to registering new users with their mobile apps. Their pre-existing users who may be interested in computational outsourcing can then earn tokens by renting their mobile devices.
NATEE’s ecosystem is not just about harnessing extra compute power, but allowing hundreds of millions of mobile devices owners to monetize their smartphones. Among the possible candidates are the often- overlooked billions of lower-middle income classes around the world - the overwhelming majority. NATEE gives these people accessibility to business opportunities, investment capital, monthly revenues and special knowledge. It enables income redistribution to lower and middle class. These days, there are a few of jobs available for the lower middle class, Although, the government / local authorities give support such as free water supply, electricity but still, not adequate for them as there are not support for food while the cost of living keeps rising.
FUTURE OF BLOCKCHAIN
Blockchain technologies have the potential to elevate and transform our way of life. NATEE system will be utilizing blockchain so that we could know where, and for whom to transfer the money for commission payout. An opportunity now exists to share computational minutes from a mobile device’s unused capacity, in exchange for tokens.
The next step is to expand the technology beyond what we’ve developed into a global, decentralized network phenomenon. For this, we are creating a new market economy. NATEE, the blockchain-powered cryptocurrency, incentivizes users to join the network and makes global transactions possible without introducing a central point of control become possible, nor a central point of failure. NATEE enables the first global market for compute by bridging a distributed ledger technology (DLT) to a pre-existing distributed system.
NATEE System is different from other ICOs, we don’t create the business that only a few groups of people will benefit but we will change the world, distributing income (commission from selling processing power) to the lower middle class which is most of the world population. We will create jobs for them as we strongly believe in sustainability (Sufficiency Economy Philosophy).
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CROWD SALE NATEE ICO PLANS
Radical decentralist impulses with a Wild West entrepreneurial spirit have inspired the initial coin offering (ICO) phenomenon, with the proliferation of the utility token as a new asset 17 class.
A PUBLIC SALE OF TOKENS, 2018
NATEE is planning to raise investor funds in an exclusive SAFTE offer, followed by a public sale involving a Pre-ICO and ICO. This public sale will feature deeply discounted tokens and begin March 1st, 2018. The ICO will follow in Q2/Q3, 2018. All proceeds raised will be used in accordance with NATEE’s Go-to-Market strategy, Financial Planning Framework detailed below. to ensure that the management team stays committed to delivering the NATEE platform.
The NATEE tokenomic structure briefly summarized as follows:
TOKEN EVENT PERCENTAGE NATEE TOKENS
Private/Partner Round 9.17% 11,000,000
Pre-ICO Q3 2018 16.67% 20,000,000
Public Sale Q4 2018 33.33% 40,000,000
Operation 12.50% 15,000,000
Reserve 4.17% 5,000,000
Bounty / Rewards (NATEE-W1) 16.67% 20,000,000
Founding Team / Advisors 7.50% 9,000,000
TOTAL 100.00% 120,000,000
*Remark: Test run with 5,000,000 NATEE Token
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TOKEN ALLOCATION
TOKEN DISTRIBUTION DETAILS
Purchase Stage Period NATEE Token / SGD Soft Cap Hard Cap Level
400 NATEE Token + 50% Warrant Bonus* first 4,000,000 NATEE Token ICO 270 400 NATEE Token + 40% Warrant Bonus* 4,000,001st – 12,000,000th NATEE Token Pre-sales days 400 NATEE Token + 30% Warrant Bonus* Min : 200 5,000,000 30,000,000 12,000,001st – 20,000,000th NATEE Token Singapore Singapore Singapore 400 NATEE Token + 20% Warrant Bonus* first 10,000,000 NATEE Token Dollars Dollars Dollars
ICO 400 NATEE Token + 10% Warrant Bonus* 60 days Crowdsale 10,000,001st - 20,000,000th NATEE Token
400 NATEE Token
A Warrant Bonus will be paid in a form of NATEE Warrant. NATEE Warrant is a security that entitles the holders to receive the NATEE tokens at the ratio of 1:1 (1 NATEE Warrant will be converted to 1 NATEE Token). In addition, the NATEE Smart Contract locks the NATEE warrant conversion for 2 years. Subsequently, NATEE Warrant will automatically be converted to NATEE token handled by NATEE Smart Contract. However, NATEE Warrant holders may request the NATEE Warrant conversion anytime during the 2 years lockup period and the conversion fee of 1 Singapore Dollar is applied per 1 NATEE Warrant.
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USE OF PROCEEDS
The chart above illustrated how the funds will be spent over the 3-year-roadmap based on fund from Soft Cap (5 Million Singapore dollars).
1. NATEE Development team, as of now NATEE consists of 6 developers
2. Research and Development, we will utilize the fund for research and development into Singapore’s universities and institutes to enhance NATEE project for more efficiency and stability decentralized cloud computing.
3. Operation Cost, other expenses to operation.
4. PR/Marketing
5. Legal
6. Reserve, this reserved fund can be utilized for our business partners as incentivized program.
7. Miscellaneous
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NATEE DEVELOPMENT PROJECT
1. Develop donate services of computing power for BOINCxxvii research projects such as SETI@home and other medical/astronomy projects.
2. Develop fully commercial NATEE SDK (Software Development Kit) for mobile app integration in both iOS and Android systems.
3. Develop cryptocurrencies mining on NATEE nodes (NATEE SDK layer).
4. Develop AI / Deep learning on NATEE nodes (Research collaboration with Nanyang Technological University of Singapore – “Algorithm Design of Mobile Decentralized Computing Systems”).
5. Develop CGI (Computer Graphic Imagery) rendering services on NATEE nodes.
6. Develop NATEE Decentralized Cloud Storage on NATEE nodes.
7. Develop adoption of IPFS on NATEE nodes.
8. Develop NATEE’s own blockchain.
ROADMAP
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TEAM NATEE CORE TEAM 18 NATEE’s Engineering TEAM are creative inventors! World-class parallel computing, high- performance clustered file system, fin-tech specialists and programmers of game consoles, micro-electronic devices, blockchain digital currency payment systems – strong skills, experience in mobile App and IoT design.
Mr. Nuttapong Wong-aree Mr. Samret Wajanasathian CEO / Co-Founder CTO / Co-founder
Over 15 years work experience in Thailand More than 15 years’ work experience in and Singapore for multinational mobile application and game companies (IBM, Lenovo, HP, Citibank, development. Starting with J2ME, Toyota Motor and AIS) in several domains Symbian and to date. Expert in Native such as Telecommunication, automobiles, programming in both PC and game banking - financial, cryptography, supercomputer, and server console system (Sony, Nintendo, and Microsoft). Highly cluster. experienced in full cycle of MMORPG game development. Passionate in core engine software development. With the experienced that I gain over time, today, I love to create huge networks with the complex computational system.
Mr. Ekkarach Pusuwan Dr. Nguyen Tan Dat CTO / Full Stack Data Scientist
An all a rounder who can work in any role Lead data scientist, specialized in applying in IT software development starting from machine learning on unstructured data UI/UX, multi-tier Web Application, complex such as video, text, and medical signals databases handling or even creating the mobile applications in both iOS and Android. Aside from my 15 years working in IT, I also love to meet and greet people and I am an easy-going guy.
Mr. Chaiyapong Lapliengtrakul Mr. Chanon Yaklai Data Scientist Full Stack IT Developer / Software Engineer Been actively working in internet technology company since 2007. More than 7 years’ work experience in IT Currently, as a CEO of Big Data Analytic industry. Specialize in UX/UI (React), Cloud company and focus on data analytics in solution on Firebase and Unity3d for 2D/3D digital marketing. game development. I am also a founder of "EOSIO Developer Thailand" community, GamingIdea.com - CEO Big Data Analytics and lecturer at King Mongkut's [email protected] - CEO 3DS Interactive Technology and Kasetsart [email protected]. Codecamp instructor, React, Native, Redux, Firebase
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NATEE ADVISORY TEAM
Professor Dusit (Tao) Niyato Dr. Niracharapa Tongdhamachart Ph.D., IEEE Fellow. Principle Investigator for School of Computer "Grid Computing for Science and Engineering College of 3D CGI Rendering" Engineering initiative in Thailand.
Dusit Niyato (PhD, IEEE Fellow) has Deputy Director of Software Industry extensive research experience in mobile Promotion Agency (SIPA, Currently known computing for more than 20 years. He has published more as DEPA) in Ministry of Digital Economy and Society Thailand. than 400 technical papers and five books in the topics related
to mobile networking and cloud computing. He is the inventor of two granted US patents and two filed German patents. His research interests are in distributed mobile cloud computing, machine learning, and Internet of Things (IoT).
Dr. Rujee Lorpitthaya Mr. Worawut Worawittayanon Scientist / Date Scientist / Consultant Editor-in-chief and Entrepreneur Editor-in-chief, more than 20 years and Research on advanced science and have been working in the magazine, engineering of structured materials at the newspaper, comics, and game media. micro and nanoscale, which support key Vibulkij Printing Press has long been industries in chemicals, medical, knowing as number one for the game automobile, semiconductor, foods, and lifestyle technologies. magazine and comic books, collaborated with "Famitsu" the all-time number one game magazine in Japan. A wire-puller for copyrights of the top rank comics in Thailand.
Mr. Puuwamate Akkachairin Mr. Charaslah Bhumiwat Financial Advisor Legal Advisor
A stellar and nation-wide recognized top Highly experienced Lawyer with more than financial consultant/adviser in Thailand. 30 years’ experience in Law both Thailand With more than 35 years’ experience and and overseas. Currently, I am a Legal many companies exit (IPO) under Mr. Advisor for multination companies (Pepsi, Puuwamate even during "Tom Yum Kung" Shell Oil Company, Tesco, Land & House, 1997 Asian financial crisis. Mr. Puuwamate loves to keep low- etc...). profile and will only do the high challenging financial work.
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Viren Gandhi Thomas Schibli Strategic Marketing / Founder Quanto Chief Strategy Officer Group Thomas is a serial entrepreneur and An early cryptocurrency adopter and strategic mind in the blockchain space. strong believer in the power of He is a native of Switzerland with a decentralized applications and blockchain background in Swiss banking, and technologies. Vee participates in ICO engineering education. A joyful and valuations and evaluations of cryptocurrency investment charismatic leader he has the uncanny ability to devise and funds. A Management Consultant with 12+yrs in USA, EU and orchestrate business strategies which elevate all involved. He Asia, also a Canadian certified Financial Consultant by CSI has worked as a management consultant internationally, and (Canadian Securities Inst). in ASEA as entrepreneur in commodities, rare wood, & cryptocurrency mining and strategic partnerships.
Mr. Songkran Wajanasathian Pongsakorn Sutantayawalee Founder of SETPointer Co., Ltd. Digital Marketing / Founder Bitcoin Trader Thailand SETPointer, Bitcoin Thailand and Litecoin Thailand. Over 230K Followers on Social Embrace the future with knowledge of Media including Facebook, Twitter, Line, technology, as a professional business Reddit. Writer of the book “Diamond in consultant for competitive advantage, Stocks Market” that become Best Seller. He corporate development, I'm interested in also a developer of various Algorithms for Automate trading deep technology, blockchain and innovations will improve such as “SETPointer Algo”, “FRxPointer” and “TrendSurfer”. the world. Embrace the future with knowledge of technology, Invested in Bitcoin and many cryptocurrency since 2011 and as a professional business consultant for competitive become an important member that promoted the advantage, corporate development, I'm interested in deep adaptation of various cryptocurrency such as Bitcoin, technology, blockchain and innovations will improve the Litecoin, Ethereum, Dodgecoin etc. world.
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REFERENCES
19
i Big Data, “Big Data”, https://en.wikipedia.org/wiki/Big_data ii Idle, “Idle (CPU)”, https://en.wikipedia.org/wiki/Idle_(CPU) iii A.I., “Artificial intelligence”, https://en.wikipedia.org/wiki/Artificial_intelligence iv Machine Learning, “Machine learning”, https://en.wikipedia.org/wiki/Machine_learning v Sharding, “Shard (database architecture)”, https://en.wikipedia.org/wiki/Shard_(database_architecture) vi Supercomputer, “Supercomputer”, https://en.wikipedia.org/wiki/Supercomputer vii Decentralized storage, “Cooperative storage cloud”, https://en.wikipedia.org/wiki/Cooperative_storage_cloud viii Vitalik Buterin, “Vitalik Buterin”, https://en.wikipedia.org/wiki/Vitalik_Buterin ix CGI, “Computer-generated imagery”, https://en.wikipedia.org/wiki/Computer-generated_imagery x Rendering, “Rendering (computer graphics)”, https://en.wikipedia.org/wiki/Rendering_(computer_graphics) xi IoT, “Internet of things”, https://en.wikipedia.org/wiki/Internet_of_things xii FOG, “Fog computing”, https://en.wikipedia.org/wiki/Fog_computing xiii Edge, “Edge computing”, https://en.wikipedia.org/wiki/Edge_computing xiv POS, “Point of sale”, https://en.wikipedia.org/wiki/Point_of_sale xv Amazon’s global cloud, “Amazon Web Services”, https://en.wikipedia.org/wiki/Amazon_Web_Services xvi Grid computing, “Grid computing”, https://en.wikipedia.org/wiki/Grid_computing xvii Parallel, “Parallel computing”, https://en.wikipedia.org/wiki/Parallel_computing xviii CERN, “CERN”, https://home.cern/ xix “The Human Genome Project”, https://www.genome.gov/12011238/an-overview-of-the-human-genome- project/ xx DLT, “Distributed ledger”, “https://en.wikipedia.org/wiki/Distributed_ledger” xxi CDN, “Content delivery network”, https://en.wikipedia.org/wiki/Content_delivery_network xxii SDK, ”Software development kit”, https://en.wikipedia.org/wiki/Software_development_kit xxiii Disney, “The Walt Disney Company”, https://en.wikipedia.org/wiki/The_Walt_Disney_Company xxiv OpenGL, “OpenGL”, https://en.wikipedia.org/wiki/OpenGL xxv IPFS, “InterPlanetary File System”, https://en.wikipedia.org/wiki/InterPlanetary_File_System xxvi Monte Carlo, “Monte Carlo method”, https://en.wikipedia.org/wiki/Monte_Carlo_method xxvii BOINC, “BOINC”, https://boinc.berkeley.edu/wiki/BOINC:About
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