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Strategic Assets Advisors (ISO 55000)

Technology

Theme: Alignment - Lawful Collaboration - Strategic Integration

Way Forward: Actionable Strategy - Private Equity

Our Focus: Digital Infrastructure | AI Projects |

Quantum Ecosystem

SECTORS

Aerospace | Agriculture | AI-Ilm | AI Economy | Deep Space

Economy | Education | Energy | Logistics | Manufacturing

Mining | Optical Systems | Technology | Water

MUGHALS Quantum Ecosystems Program (MQEP)

MQCI Project

MUGHALS Quantum Compatible Interfaces (MQCI)

MQCI CONTEXT

On May 9th 2018, after 3 years of multiple studies,

MUGHALS Group Launched Strategic Program

MQCI Mission

Maximizing AI Potential Minimizing Harms

MQCI Business Scope

By 2025, more than 50 billion devices will be connected to the IoT, generating 79.4 zettabytes of data yearly. Annual installations of Industrial Robots, which have increased two times to about 450,000 since 2015, will grow to about 600,000 by 2022, even as 70 percent of Manufacturers will be regularly using Digital Twins by 2022. Gradually, across Industries, manufacturing processes will be replaced by Additive Manufacturing (AM).

MQCI Program

MQCI Program Advisor: Mohammad Afzal Mirza

President, AMCO Engineering & AEC LLC USA

MQCI Project Lead: Afro Eurasian Coalition (AEC) LLC USA

AEC USA SAM & DoD CAGE Code Status: Active

AEC U.S. Prime NAICS Code: 541690 (S&T)

MQCI Research: PEIS | Prime Source: USA Government

MQCI Lead Policy Advisor

Pacific Enterprises International Syndicate (PEIS)

PEIS USA SAM & DoD CAGE Code Status: Active

PEIS U.S. Prime NAICS Code: 541690 (S&T)

PEIS Prime SIC Code: 87420501

Federal Communications Commission (FCC) FRN #: 0034792853

MQCI Product Specific Methodology

Algorithms | AI Entanglement | Generative AI

Alignment | Lawful Collaboration | Strategic Integration

Case Study - 18C

Case Study - 11H

Governments, Industry, Academia leading the Acceleration

Fundamental Technology

Quantum Research and Development

We Are Quantum System Developers!

Quantum Interface Development involves a number of considerations, including:

Quantum-Classical Interface

Information is passed between qubits and classical circuits using digital-to-analogue converters (DACs), analog-to-digital converters (ADCs), and other classical circuits. Application-specific integrated circuits (ASICs) and field-programmable gate arrays (FPGAs) can implement feedback and High-Speed Logic.

Quantum Circuit Design

Quantum Circuits are created to execute Quantum Algorithms. This process is similar to programming an analog computer for each use case. The choices made during this process can have significant effects on the outcome.

Qubit Technology and Control Methods

The design process starts with the underlying Qubit Technology and Control Methods.

Qubit Simulations are used to extract specifications for the Control and Read-Out Signals.

Trade-offs

Trade-offs between qubit performance and the performance of the control electronics can be identified.

Documentation

Documentation is important for maintaining systems and ensuring that future developers can understand them.

Code quality

Code quality is important for ensuring that the code is reusable and understandable. Debugging, test-ability, and readability are all components of code quality.

Compatibility

A low-level implementation needs to be compatible with any future updates or replacements of the control system.

Partitioning

The low-level systems need to be carefully partitioned to avoid negatively impacting the correctness of operations.

Digital Twins

Asset or Product Digital Twins | Component Twins |

Process Twins | System Twins

Technologies Trends up to 2050

10 Tech Developments are attracting the most Venture Capital and producing the Most Patent Filings.

All using Data Sciences; Artificial Intelligence (AI); Machine Learning etc., include next-level Process Automation; Virtualization, and seamless connectivity through 5 & 7G.

AI Virtual Agents have dominated the Social Media Platforms, Marketing & Sales, Internet of Things (IoT). Other areas to watch include Trust Architecture – which verifies the Trustworthiness of Devices as Data Flows Across Networks – Next-Generation Smart Materials and Artificial Intelligence (AI) Algorithms that Train Machines and Strategic Human Capital.

Venture Investment Strategy

Autonomous Economics At Scale: Capability Assessment & Analysis Processes (CAAP)

Deliverable: Quantum Compatible Autonomous Digital Infrastructure (CADI)

Product: Digital Infrastructure Distributed Clusters (DIDC)

Cybersecurity Framework: Post-Quantum Advanced Encryption Standard (PAES)

User Friendly Interface: Autonomous Digital Assets Management (ADAM)

MUGHALS Development Focus: Economic Development Programs (EDPS)

Innovative Technologies Transforming Industries

Artificial Intelligence (AI)

1. Machine Learning (ML)

2. Deep Learning (DL)

3. Natural Language Processing (NLP)

4. Computer Vision

5. Robotics

Additive Manufacturing

1. 3D Printing

2. 4D Printing

3. Direct Energy Deposition (DED)

4. Selective Laser Sintering (SLS)

5. Stereolithography (SLA)

Internet of Things (IoT)

1. Industrial IoT (IIoT)

2. Smart Sensors

3. Real-time Data Analytics

4. Cloud Computing

5. Cybersecurity

Robotics

1. Collaborative Robots (Cobots)

2. Autonomous Robots

3. Human-Machine Interface (HMI)

4. Robot Vision

5. Sensor Integration

Digital Twins

Definition: A virtual replica of a physical asset, system, or process, simulated in real-time to optimize performance, predict maintenance, and improve decision-making.

Types of Digital Twins:

1. Component Twin (e.g., engine, pump)

2. System Twin (e.g., manufacturing line, power grid)

3. Process Twin (e.g., supply chain, logistics)

4. Facility Twin (e.g., building, factory)

Key Characteristics

1. Virtual representation

2. Real-time data integration

3. Simulation and analysis

4. Predictive maintenance

5. Optimization and improvement

Blockchain

1. Supply Chain Management

2. Quality Control

3. Authentication

4. Secure Data Storage

5. Smart Contracts

Nanotechnology

1. Materials Science

2. Energy Storage

3. Medical Devices

4. Water Purification

5. Textiles

Advanced Materials & Alloys

1. Carbon Fiber Reinforced Polymers (CFRP)

2. Graphene

3. Nanomaterials

4. Smart Materials

5. Biomaterials

Industry 4.0

1. Smart Manufacturing

2. Digital Thread

3. Predictive Maintenance

4. Quality 4.0

5. Industrial Cybersecurity

Applications:

1. Aerospace

2. Agriculture

3. Automotive

4. Healthcare

5. Energy

6. Consumer Products

7. Logistics

8. Food Processing

9. Pharmaceuticals

Virtual and Augmented Reality

1. Virtual Reality (VR)

2. Augmented Reality (AR)

3. Mixed Reality (MR)

4. Industrial Training Simulators

5. Design Visualization

Comprehensive Sustainability Framework

Environmental Pillars

1. Climate Change and Energy: Reduce greenhouse gas emissions, increase renewable energy use.

2. Water Conservation: Efficient water management, reduce waste.

3. Waste Management: Minimize, reuse, recycle, optimize waste-to-resource.

4. Biodiversity and Ecosystems: Protect, restore, promote eco-friendly practices.

5. Resource Efficiency: Optimize materials, reduce consumption.

Social Pillars

1. Human Rights and Labor Practices: Ensure fair labor conditions, respect human rights.

2. Community Engagement and Development: Foster positive relationships, support local economies.

3. Health and Well-being: Promote employee and community health.

4. Diversity, Equity, and Inclusion: Encourage inclusive culture, equal opportunities.

5. Education and Training: Develop skills, promote sustainability awareness.

Economic Pillars

1. Sustainable Supply Chain: Manage suppliers, promote responsible practices.

2. Sustainable Products and Services: Develop eco-friendly offerings.

3. Innovation and Technology: Leverage clean tech, innovative solutions.

4. Economic Growth and Development: Support local economies, create jobs.

5. Transparency and Accountability: Report progress, ensure responsible governance.

Implementation and Governance

1. Policy and Strategy: Establish clear sustainability goals.

2. Organization and Governance: Define roles, responsibilities.

3. Metrics and Reporting: Track key performance indicators (KPIs).

4. Stakeholder Engagement: Collaborate with internal, external stakeholders.

5. Continuous Improvement: Regularly review, refine framework.

United Nations Sustainable Development Goals (UN SDGs)

Integrate SDGs into framework, aligning with global priorities.

Some sustainability frameworks:

1. Global Reporting Initiative (GRI)

2. Sustainability Accounting Standards Board (SASB)

3. Dow Jones Sustainability Index (DJSI)

4. CDP (Carbon Disclosure Project)

5. UN Global Compact

Critical and Emerging Technologies

Areas Having Particular Importance to the National Security

1) Advanced Computing

2) Advanced Engineering Materials

3) Advanced Gas Turbine Engine Technologies

4) Advanced Manufacturing

5) Advanced and Networked Sensing and Signature Management

6) Advanced Nuclear Energy Technologies

7) Artificial Intelligence

8) Autonomous Systems and Robotics

9) Biotechnologies

10) Communication and Networking Technologies

11) Directed Energy

12) Financial Technologies

13) Human-Machine Interfaces

14) Hypersonics

15) Inter Satellite Communication Algorithms

16) Networked Sensors and Sensing

17) Quantum Information Technologies

18) Renewable Energy Generation and Storage

19) Semiconductors and Microelectronics

20) Space Technologies and Systems

Underlying Technologies

As per one legal definition, Underlying Technology MEANS "the level of technology that Underlies Multiple Applications, at least one application of which is outside of the Business, as of the Closing Date, rather than being directed to only a specific application, but only to the extent such technology is common to such applications."

👉 In an environment of rapidly evolving cybersecurity threats, the continued reliance on the Data Encryption Standard (DES) and other Non-Standard Encryption Algorithms poses a significant threat to the security of sensitive Data and Information Systems.

👉 In accordance with the OECD and the U.S. Laws, Policies and Guidelines, we are developing Suits of Algorithms to Lawfully Strengthen and Integrate Interoperability and Compatibility of existing Digital Infrastructures.

👉 As currently, one of the major challenges include to overcome the vulnerabilities of the continued use of the deprecated DES and other non-standard algorithms.

Additive Manufacturing | Artificial Intelligence |

Augmented Reality (AR) | Blockchain |

Combined Heat & Power (CHP) | Digital Twin |

Directed Energy Deposition (DED) | Distributed Ledger |

Electric Propulsion | Geothermal | Infrared Remote Sensing | LiDAR |

Microwave Reaction Technology (MRT) |

Machine Learnings (ML) | SMART Contracts | Virtual Reality (VR)

HOME

ECONOMY

INITIATIVES

WATER

Critical and Emerging Technology (CET) Subfields

Each identified CET Area includes a set of Key Subfields

Advanced Engineering Materials

Materials by design and material genomics
Materials with new properties
Materials with substantial improvements to existing properties
Material property characterization and lifecycle assessment

Advanced Computing

Supercomputing
Edge computing
Cloud computing
Data storage
Computing Architectures
Data Processing and Analysis

Deep Space Technologies and Systems

On-Orbit Servicing, Assembly, and Manufacturing
Commoditized Satellite Buses
Low-Cost Launch Vehicles
Sensors for Local and Wide-Field Imaging (LWFI)
Space Propulsion
Resilient Positioning, Navigation, and Timing (PNT)
Cryogenic Fluid Management (CFM)
Spacecraft Entry, Descent, and Landing (SDL)

Advanced and Networked Sensing and Signature Management

Payloads, Sensors, and Instruments
Sensor Processing and Data Fusion
Adaptive Optics
Remote sensing of the Earth
Signature Management
Nuclear Materials Detection and Characterization
Chemical Weapons Detection and Characterization
Biological Weapons Detection and Characterization
Emerging Pathogens Detection and characterization
Transportation-sector Sensing
Security-sector sensing
Health-sector sensing
Energy-sector sensing
Building-sector sensing
Environmental-sector sensing

Advanced Nuclear Energy Technologies

Nuclear energy systems
Fusion energy
Space nuclear power and propulsion systems

Artificial Intelligence (AI)

Autonomous Systems and Robotics

1. Air
2. Maritime
3. Space
4. Surfaces

Hypersonics

1. Propulsion
2. Aerodynamics and Control
3. Materials
4. Detection, Tracking, and Characterization (DTC)
5. Defense

Renewable Energy Generation and Storage (REGS)

1. Renewable generation
2. Renewable and Sustainable Fuels
3. Energy Storage
4. Electric and Hybrid Engines
5. Batteries
6. Grid Integration Technologies (GIT)
7. Energy-Efficiency Technologies (EET)

Gas Turbine Engine Technologies

Aerospace, Aviation, Maritime
Industrial Development and Production Technologies

Advanced Manufacturing

Additive Manufacturing
Clean, Sustainable Manufacturing
Smart Manufacturing
Nanomanufacturing

Biotechnologies

Nucleic Acid and Protein Synthesis
Genome and Protein Engineering including design tools
Multi-omics and other Biometrology, Bioinformatics, Predictive Modeling, and Analytical Tools for Functional Phenotypes
Engineering of Multicellular Systems
Engineering of Viral and Viral Delivery Systems
Biomanufacturing and Bioprocessing Technologies

Communication and Networking Technologies

Radio-frequency (RF) and Mixed-Signal Circuits (MSC), Antennas, Filters, and Components
Spectrum Management Technologies
Next-Generation Wireless Networks including 5G and 6G Optical Links and Fiber Technologies
Terrestrial / Undersea Cables (TUC)
Satellite-Based Communications
Hardware, Firmware, and software
Communications and Network Security
Mesh Networks / Infrastructure Independent Communication Technologies

Financial Technologies

Distributed ledger technologies
Digital assets
Digital Payment Technologies
Digital Identity Infrastructure

Human-Machine Interfaces

Augmented reality
Virtual Reality
Brain-Computer Interfaces (BCI)
Human-Machine Teaming (HMT)

Quantum Information Technologies

Quantum Computing
Materials, Isotopes, and Fabrication Techniques for Quantum Devices
Post-Quantum Cryptography
Quantum Sensing
Quantum Networking

Semiconductors & Microelectronics

Design and Electronic Design Automation Tools
Manufacturing Process Technologies (MPT) and Manufacturing Equipment
Beyond Complementary Metal-Oxide-Semiconductor (CMOS) Technology
Heterogeneous Integration and Advanced Packaging
Specialized / Tailored Hardware Components for Artificial Intelligence, Natural and Hostile Radiation Environments, RF and Optical Components, High-Power Devices (HPD), and other Critical Applications
Novel Materials for Advanced Microelectronics
Wide-Bandgap and Ultra-Wide-Bandgap Technologies (WUBT) for Power Management, Distribution, and Transmission