MachineX Intelligence

land vehicle, sea vehicle, air vehicle, space vehicle

Smart Vehicle Architecture

Smart System of Systems SoS Architecture is needed in the vehicle industry for several reasons:

1. Integration: SoS architecture allows for the integration of various systems within a vehicle such as powertrain, infotainment, and safety systems. This integration improves the performance and functionality of the vehicle.

2. Advanced Features: SoS architecture enables the development of advanced features such as autonomous driving and connectivity with external devices.

3. Optimization: SoS architecture allows for optimization of the design and functionality of vehicles. This leads to cost reduction and improved efficiency in the development process.

4. Scalability: SoS architecture allows for the scalability of the vehicle systems, which enables them to adapt to new technologies, standards and regulations.

5. Safety: SoS architecture ensures that all the vehicle systems are designed and integrated in a way that guarantees the safety of the vehicle's occupants and other road users.

6. Testing: SoS architecture allows for more efficient testing and validation of the vehicle systems, which leads to a more robust and reliable final product.

Overall, the use of SoS architecture in the vehicle industry helps to improve the performance, functionality, safety and cost-effectiveness of vehicles while ensuring compliance with regulations and standards.

The New Car/Truck/Bus Making Industry

Smart SoS Architecture is needed in the car, truck and bus industry for several reasons.

It allows for:

1. the integration of various systems and subsystems within a vehicle, such as powertrain, braking, infotainment and safety systems.

2. the easy scalability and upgradability of vehicles, as new technologies and features are developed, they can be incorporated into the architecture.

3. playing a crucial role in vehicle safety and reliability.

4. ensuring that all systems are designed & tested to meet industry standards & regulations, and that they can handle various operating conditions & potential failure scenarios.

5. reducing the cost of manufacturing and maintenance of vehicles by reducing the number of components and simplifying the design of vehicle.

The New Construction-Vehicles Making Industry

Building new construction-vehicles require SoS architecture for several reasons.

the integration of various systems and subsystems within a construction-vehicle such as powertrain, braking, guidance, control, and communication systems. This ensures that these systems work together seamlessly and efficiently, improving the overall performance and functionality of the vehicle.
allows for the easy scalability and upgradability of construction-vehicles, as new technologies and features are developed, they can be incorporated into the architecture, allowing vehicles to stay current and competitive.
plays a crucial role in the safety and reliability of construction-vehicles. It helps to ensure that all systems are designed and tested to meet industry standards and regulations, and that they can handle various operating conditions and potential failure scenarios, thus improving the safety of the workers and the public.
helps in reducing the cost of manufacturing and maintenance of construction-vehicles by reducing the number of components and simplifying the design of vehicle.
helps in improving the efficiency of construction operations by allowing the integration of advanced technologies such as GPS, sensors, and telemetry.

The New Airplanes-Making Industry

Building new airplanes requires SoS architecture for several reasons.

the integration of various systems and subsystems within an airplane, such as the powerplant, avionics, flight control, and communication systems. This ensures that these systems work together seamlessly and efficiently, improving the overall performance and functionality of the airplane.
allows for the easy scalability and upgradability of airplanes, as new technologies and features are developed, they can be incorporated into the architecture, allowing airplanes to stay current and competitive.
plays a crucial role in the safety and reliability of airplanes. It helps to ensure that all systems are designed and tested to meet industry standards and regulations, and that they can handle various operating conditions and potential failure scenarios, thus improving the safety of the passengers and crew.
helps in reducing the cost of manufacturing and maintenance of airplanes by reducing the number of components and simplifying the design of the airplane.
helps in improving the efficiency of flight operations by allowing the integration of advanced technologies such as GPS, sensors, and telemetry.

The New Trains-Making Industry

Building new trains requires SoS architecture for several reasons.

the integration of various systems and subsystems within a train, such as the power plant, propulsion, braking, communication, and control systems. This ensures that these systems work together seamlessly and efficiently, improving the overall performance and functionality of the train.
allows for the easy scalability and upgradability of trains, as new technologies and features are developed, they can be incorporated into the architecture, allowing trains to stay current and competitive.
plays a crucial role in the safety and reliability of trains. It helps to ensure that all systems are designed and tested to meet industry standards and regulations, and that they can handle various operating conditions and potential failure scenarios, thus improving the safety of the passengers and crew.
helps in reducing the cost of manufacturing and maintenance of trains by reducing the number of components and simplifying the design of the train.
helps in improving the efficiency of train operations by allowing the integration of advanced technologies such as GPS, sensors, and telemetry.

The New Ship-Making Industry

Building new ships requires innovative SoS architecture for several reasons.

the integration of various systems and subsystems within a ship, such as the propulsion, navigation, communication, and control systems. This ensures that these systems work together seamlessly and efficiently, improving the overall performance and functionality of the ship.
allows for the integration of new and advanced technologies such as automation, IoT, and AI, which can improve the safety, efficiency and performance of the ship.
plays a crucial role in the safety and reliability of ships. It helps to ensure that all systems are designed and tested to meet industry standards and regulations, and that they can handle various operating conditions and potential failure scenarios, thus improving the safety of the crew, passengers and cargo.
helps in reducing the cost of manufacturing and maintenance of ships by reducing the number of components and simplifying the design of the ship.
helps in improving the efficiency of ship operations by allowing the integration of advanced technologies such as GPS, sensors, and telemetry.

Potential Customers … They are After Markets Estimated at $1.5 Trillion In-Value Annually

Infiniti BMW Lexus Kia Land Rover Yamaha Caterpillar

Jaguar Audi Ferrari Rolls-Royce Scania Dodge Mercedes

Northrop Gruman Porsche Saab Ford Chevrolet SpaceX Opel

Volkswagen Buick GMC Cadilac Suzuki Airbus Accura

Honda Cadilac Fiat Tesla Mc Douglass Boeing ToyotaNissan

Jeep Subaru Hyundai HII-NNS Deere Isuzu Mazda

Lincoln Mitsubishi Maserati Lockheed Martin GDLS Volvo Komatsu

Architecting New Vehicles: Autonomous, Semi-Autonomous, Electric, Regular

When a new vehicle is thought, overall goal comes in-mind: “what would make it so appealing to customer?” This overall goal is a multi-tier each clarifies the tier above. At the bottom, you end-up with metrics that measure your overall goal, and are in-conflict among each other by-nature.

Different options of shapes, designs, parts are thought that might exist in different forms, has different plusses & minuses w.r.t. the overall goal, and different interactions with the car other parts that must be recognized & respected

Show me:

a. the best options of the new vehilce?

b. the best part or parts that are playing pivotal role among those options?

c. the best part or parts that are pivotal to make this option of the new vehicle?

d. a better way to make the new vehicle even better than thought?

Engineering Design Process

Engineering design is the process of devising a system, component, or process to meet desired needs. It is a decision making process, in which the basic sciences, mathematics and engineering sciences are applied to convert resources optimally to meet stated objectives. Among the fundamental elements of the design process are the establishment of objectives and criteria, synthesis, analysis, construction, testing, and evaluation.

Accreditation Board for Engineering and Technology

Evolvable Systems Technology

NASA Exploration Missions will require new advances in engineering design and optimization. Evolvable Systems technologies are poised to deliver these advances through the use of algorithms that can automatically design and optimize systems without being explicitly told how to do so.

Benefit
- The benefits of the proposed technologies fall under sustainability, affordability, and modularity.
- In order to realize a sustainable campaign of space exploration, the underlying technologies must enable affordable, reliable, and effective exploration and infrastructure systems. Evolvable Systems algorithms are highly adaptable, relatively fast, and can be set up to optimize cost, robustness, and performance by embedding these measures directly into the multi-objective utility functions that comprise the algorithms.

https://www.nasa.gov/centers/ames/research/technology-onepagers/evolvable_systems.html

Challenge & Solution

Challenge

Before architecting & building the next machine or vehicle, decision-makers are looking for a way to see all possible alternatives to what the next machine or vehicle would be in terms of cost, performance, weight, risks, and customer appeal.

Solution

MachineX is a System of Sub-Systems or System of Systems decision-making application that helps new vehicle makers envision:

o the right Machine

o made of the right subsystems

o using the right subsystem’s options

o that work together to meet ALL the business objectives before building it.

A system of subsystems is a structure in which a larger system is made up of multiple smaller subsystems. Each subsystem is a separate system that performs a specific function or set of functions, and the subsystems work together to achieve the overall goal or purpose of the larger system. This type of structure is often used in engineering, manufacturing, and other technical fields to create more efficient and effective systems or vehicles using MachinX.

Vehicle subsystems are the various components and systems that make up a vehicle and allow it to function. Some common examples of vehicle subsystems include:

Powertrain subsystem: This includes the engine, transmission, and other components that generate and transmit power to the wheels.
Chassis subsystem: This includes the frame, suspension, and other components that support and control the vehicle's movement.
Electrical subsystem: This includes the battery, alternator, and other components that generate and distribute electrical power throughout the vehicle.
Brake subsystem: This includes the brake calipers, brake pads, and other components that allow the vehicle to slow down and stop.
Steering subsystem: This includes the steering wheel, steering column, and other components that allow the driver to control the direction of the vehicle.
Climate control subsystem: This includes the air conditioning, heater and other components that control the temperature and ventilation inside the vehicle.
Infotainment subsystem: This includes the audio system, navigation system, and other components that provide entertainment and information to the occupants.

These are some of the common subsystems present in most of the vehicles, however, depending on the type of vehicle, the subsystems might vary.

MachineX is:

100% Data-driven
Zero-Coding, Zero-Modeling
SaaS
100% Secured

MachineX incorporates advanced concepts of:

System of Subsystems Architecture
Overall Goal Hierarchy Structure
Gated Various Interactions
Many In-conflict Objectives Optimization
Machine Profiling, Recommendation, and Learning
Automative IoT for Smarter Vehicles
Knowledge, Intelligence, & the Tradeoff-Killer New Vehicle!
Innovative Visualization

So, How Does MachineX Work?

A machine or vehicle is a whole system of subsystems. Each subsystem has a variable number of candidate options defined by the client’s new vehicle departments.

Infopundits will work with the client to define technically, not physically:

1. the subsystems, and each of the subsystem's candidate options,

2. the overall goal hierarchy: categories, subcategories, metric types, and the data related to the subsystem-option's metrics.

For security, all subsystem & option names might be coded or encrypted so only the client has them.

3. Options across the subsystems might be subject to any type of gated interactions that must be defined & respected. Those gated interactions might be of different types: co-requisite, incompatible, forward pre-requisite, or backward pre-requisite.

4. MachineX will formulate a multi or many in-conflict optimization data model where all the non-inferior candidate systems, also known as Pareto solutions, with their selected options will be generated while all constraints and option's gated interactions are fully respected.

5. MachineX's ML is used next to profile all the non-inferior tradeoff optimal systems to make the selection to be built today, extract the knowledge they share, and the intelligence they hide to define the tradeoff-killer systems for the vehicle to be explored for tomorrow making!

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