Integrated Project Delivery

• Examine complex mega hospital projects with early involvement from all stakeholders, including owners, designers, manufacturers, support teams, management, estimators, construction teams, engineers, and more. Establish a transparent master estimate structure from the project's inception that remains effective through to the execution and production stages of Lunar operations.

Unit Cost Historical

• Clear, relevant, and defined unit cost tracking. Including specifics of micro and micro unit delineations that represent time, and spatial coordinates (X, Y, Z). Also, involves sequencing that accurately captures the state of prediction cycles from the initiation of engineering and design through to project completion and lifecycle management.

Work Breakdown Structure

• A hierarchical decomposition of the total scope of work to accomplish the project objectives and deliverables. Additionally, it organizes and defines the total work scope of the project and subdivides it into manageable sections or components. Each descending level represents an increasingly detailed definition of the project work.
• Key points about WBS in construction estimating:
  1. Hierarchy
  2. Delineation of Work Packages
  3. Cost Estimation (Micro, Macro)
  4. Resource Allocation
  5. Schedule and Time Eliminates
  6. Accountability and Performance tracking
  7. Risk Management and Predictive State

Estimate Structure

• Estimate Structure serves several crucial functions as a tool:
  1. Budgeting: Managing financial resources effectively. Including major lunar project breakout sections.
  2. Planning: Provide detailed breakdown for relevant components and its quantity as well as the meaning of specific relevant components.
  3. Resource Allocation: Types and quantities of resources needed throughout the project lifecycle.
  4. Decision Making: Aids stakeholders in making informed decisions
  5. Cost Control: Monitor and control predictive expenditures as it relates to the active state of design, engineering, and ensuring the project stays in a low variable fluctuation state.
  6. Risk Management: Identification of risks and developed strategies to mitigate those risks
  7. Performance Measurement: benchmark for measuring project performance and progress.
  8. Transparency and Communication: Transparency and clear communication among all stakeholders by detailing costs and resources, fostering trust and collaboration.
  9. Full Cycle Structure: Allowing Agile and Rigid structure that facilitates predictions and downstream verifications, as well as Historical throughput.

Two Way Data Flow Process

• Considerations for downstream and upstream micro and macro unit components and their configurations to enable real-time predictive analysis and verification feedback loops. This approach uses a mirrored predictive reality model and estimate, allowing for omni-directional instant throughput. It facilitates the historical real-time refinement of actual full-cycle unit costs and associated time allocations.

AR Model and Design Model

• Digital content is interactive and responds to changes in the user's environment in real-time. Used for projecting sequence analysis, practice scenarios for mood construction production and time costing component live feed display

Verification Predictive Analysis Engineering Model (Time Sequence)

• Verification Predictive Analysis Engineering leverages data and advanced analytics to ensure the accuracy, efficiency, and reliability of modern engineering processes and systems. This approach integrates mega data, analytics, simulation, and modeling to validate that engineering designs and operations meet specified criteria. It also applies real-time predictive outcomes and intelligent verification to assess the true state of events as they become measurable.

Scheduling

• Using advanced analytics to create precise, optimized schedules that improve project performance and outcomes by anticipating and managing future events and uncertainties.
• Predictive time and sequence allocations of resources and timelines for tasks and activities to a micro and macro level of output for an extreme condition environment.
• Interacts with AR, engineering, design, and master sequenced estimate models.

Means and Methods

• Planning and navigating complex and extreme conditions, ensuring safety, efficiency, compliance, quality, and adaptability in project execution.
• Full cycle consideration of difficult staging and simulated sequencing for optimization within extreme situational cause and effect conditions

Active Developing Technologies for Design Components

• A relevant collection of developing technologies and apparatuses related to moon construction, including peripheral cause/effect and means and methods.
• Since many design and engineering details will be finalized later in the estimating cycle, it's crucial to stay updated on all potential design and engineering elements. This ensures a reliable rationalization of assumptions made during the estimating process, which can be confirmed as the design matures.
• Examples include:
  • Types of infrastructure being considered for the power grid
  • Types of habitat structures being examined
  • Various road construction techniques being evaluated

Construction Project/Mission Planning and Design

• Early project planning and considerations for the mission's business case, structural functionality, and proposed project scope
• Master planning and site layout
• Initial systemic considerations, including systems integration and the relational sequence of building phases

Other

• Relevant, but not within the categories listed.