Fact-checked by Grok 2 weeks ago

Model-based definition

Model-based definition (MBD) is a digital engineering practice that uses 3D models as the primary and authoritative source of product information, embedding geometric dimensions and tolerances (GD&T), product manufacturing information (PMI), and other specifications directly into the model to define a product completely without relying on separate 2D drawings. This approach, also referred to as digital product definition (DPD), establishes the 3D CAD model as the single source of truth for the entire product lifecycle, from design through manufacturing and inspection. In contrast to traditional drawing-centric workflows, where 2D technical drawings serve as the main communication tool and often lead to interpretation errors or data inconsistencies, MBD integrates all necessary details—such as annotations, , and assembly instructions—directly into the environment, streamlining processes and minimizing redundancy. This methodology emerged with the advancement of CAD technologies in the late and gained formal structure through industry standards, enabling more efficient data exchange across , , and teams. Key standards supporting MBD include ASME Y14.41 (first published 2003), which outlines practices for organizing and presenting digital product definition data in models, including methods for annotated models and associated data elements, and its companion ASME Y14.47 (first published 2019) for model organization practices. Internationally, ISO 16792 (first published 2006) provides guidelines for technical product documentation using 3D CAD models, ensuring interoperability and consistency in MBD implementations. These standards have been pivotal in promoting widespread adoption, particularly in , automotive, and industries where precision and traceability are critical. MBD forms the foundation of the broader model-based enterprise (MBE) framework, where digital models drive enterprise-wide processes, reducing time-to-market, costs, and errors by facilitating automated data flow to downstream applications like CNC programming and quality inspection. Benefits include improved product quality through unambiguous information, enhanced collaboration via standardized 3D data, and support for advanced manufacturing technologies such as additive manufacturing. As of the mid-2020s, major CAD providers like , , and PTC have integrated robust MBD tools, accelerating its transition from niche to standard practice in product development.

Definition and Fundamentals

Core Concept

Model-based definition (MBD) is the practice of embedding all product-defining data—including geometry, dimensions, tolerances, materials, and assembly instructions—directly into a 3D CAD model, establishing it as the authoritative source for product specification without reliance on separate 2D drawings. This methodology leverages 3D models to serve as a comprehensive digital representation that supports downstream processes in design, manufacturing, and inspection. Product Manufacturing Information (PMI), such as annotations for geometric dimensioning and tolerancing, is integrated as embedded data within these models to convey essential manufacturing requirements. Unlike broader frameworks, MBD specifically targets geometric product definition within , focusing on the 3D model as the primary artifact for mechanical design and production details. In contrast, (MBSE) addresses system-level modeling across interdisciplinary domains, incorporating requirements, architecture, and behavior at a higher level rather than confining itself to CAD-centric product . At its foundation, MBD adheres to core principles of establishing a —where the model serves as the unified, unambiguous reference for all stakeholders—and promoting digital continuity to maintain and from initial through and beyond. This ensures reduced errors, enhanced collaboration, and efficient reuse of product information across the enterprise.

Key Components

Product Manufacturing Information (PMI) forms the foundational metadata layer in model-based definition (MBD), embedding essential manufacturing details directly into the 3D model to serve as the authoritative source for product realization. This includes , which specifies controls for form, orientation, location, profile, and runout to ensure parts meet functional requirements, as defined in ASME Y14.5. specifications denote required texture characteristics, such as roughness average () values, waviness, and lay direction, using standardized symbols to guide processes, per ASME Y14.36. Material specifications detail composition, , and properties like strength or , while the bill of materials (BOM) enumerates components, quantities, and hierarchical assembly structures. These elements are prepared and presented according to ASME Y14.41 for digital product definition data practices and ISO 16792 for technical product documentation, ensuring interoperability and completeness in 3D datasets. 3D model formats critical to MBD must retain both geometric shapes and associated PMI without loss during exchange. Native formats from CAD systems, such as those compliant with ASME and ISO standards, preserve full PMI fidelity, including editable annotations and . The neutral STEP AP242 format (ISO 10303-242), tailored for managed model-based 3D engineering, supports semantic preservation of PMI elements like GD&T tolerances and their geometric associations, enabling downstream applications in and . Lightweight formats, such as 3D PDF viewers, facilitate visualization and basic PMI display but typically do not support full PMI editing or preservation, limiting their use to review rather than authoritative definition. Annotation types in MBD integrate instructional data seamlessly into the 3D environment, enhancing clarity without relying on separate documents. Direct model annotations attach dimensions, tolerances, and to specific faces, edges, or vertices, providing context-specific guidance. Exploded views disassemble assemblies to highlight mating interfaces and locations, while section views reveal cross-sectional details and internal annotations, all governed by presentation rules in ISO 16792 to maintain and accuracy in digital formats. Data validation mechanisms ensure the reliability of MBD models by verifying and of embedded data. checks confirm the presence of all required , such as fully defined GD&T callouts and material assignments linked to . assessments identify discrepancies, including stack-up violations or orphaned annotations. The NIST Model-Based Enterprise () PMI Validation and project offers standardized test cases, including combined and fully-toleranced models, to evaluate adherence to ASME Y14.41 and Y14.5 through round-robin CAD comparisons and validation of derivative files like STEP AP242.

Historical Development

Origins in CAD

The origins of model-based definition trace back to the emergence of (CAD) systems in the and , which fundamentally shifted from manual to digital representations. In 1963, Ivan Sutherland's introduced interactive , enabling users to construct and manipulate wireframe drawings on a display using a interfaced with the TX-2 computer, thereby pioneering the concept of digital geometric modeling over traditional pen-and-paper methods. Throughout the , CAD evolved with the proliferation of wireframe modeling techniques, where engineers represented complex three-dimensional objects as interconnected lines and curves, facilitating early computational analysis and visualization that reduced reliance on physical prototypes. The 1980s marked a pivotal era of CAD maturation, with innovations in parametric and solid modeling establishing 3D data as a viable primary artifact for design. Autodesk's AutoCAD, released in 1982, democratized CAD by providing affordable 2D drafting on personal computers, and by the late decade, it incorporated scripting via AutoLISP that enabled automation and enhanced flexibility for iterative engineering. Concurrently, Dassault Systèmes advanced solid modeling via CATIA software, initially developed in the late 1970s but refined in the 1980s for precise volumetric representations, allowing engineers to define complete 3D geometries with internal and external boundaries, which laid the groundwork for comprehensive digital product definitions. A landmark in this progression came in the , as industries embraced fully digital CAD workflows, exemplified by Boeing's design of the aircraft using , which debuted in 1995 as the first commercial airliner created without physical mockups or traditional drawings, relying solely on integrated models for all specifications and simulations. This adoption was propelled by demands in , automotive, and defense sectors for managing intricate geometries—such as curved fuselages and engine components—that 2D drawings struggled to convey accurately, thereby minimizing translation errors from orthographic projections to physical builds and streamlining collaboration across global teams.

Evolution to Modern Practices

The shift toward model-based definition (MBD) in the 2000s marked a pivotal integration with Product Lifecycle Management (PLM) systems, facilitating the use of 3D models across manufacturing processes rather than isolated design phases. This evolution allowed for seamless data flow from design to production, reducing errors and enhancing traceability. A foundational development was the 2003 publication of ASME Y14.41, which outlined practices for digital product definition data in 3D models, including annotated models and associated data elements. For instance, enhancements in software like Siemens NX around 2010 introduced capabilities for embedding product manufacturing information (PMI) directly into models, supporting PLM interoperability and enabling manufacturers to leverage 3D data for downstream applications such as assembly and quality control. In the , MBD advanced through the adoption of neutral formats for standardized exchange, exemplified by the 2014 update to STEP AP242, which consolidated functionalities from prior standards like AP203 and AP214 to support comprehensive 3D model sharing across systems. This development was particularly prominent in the automotive sector, where the (AIAG) promoted MBD via white papers and guidelines, encouraging 3D model implementation to streamline supply chain communication and reduce reliance on 2D drawings. The 2020s have seen MBD incorporate AI-driven validation tools to automate PMI checks and ensure model accuracy, alongside cloud-based platforms that enable sharing of data. For example, Onshape's features announced in 2025 allow teams to embed and distribute PMI in cloud-native environments, fostering instant feedback loops without traditional file transfers. Additionally, MBD has linked with digital twins for advanced simulation, where 3D models serve as the foundation for performance predictions in smart assembly processes. A key catalyst was the U.S. Department of Defense's 2018 Digital Engineering Strategy, which promoted model-based practices including MBD for defense systems, accelerating enterprise-wide adoption through 2025 by prioritizing digital artifacts over documents.

Implementation in Engineering

Use of 3D Digital Data Sets

In model-based definition (MBD), workflows begin with the creation of 3D digital data sets in (CAD) software, where geometric models serve as the primary repository for product information, integrating both shape data and associated to eliminate reliance on separate drawings. These data sets are maintained through processes, with revision control achieved via versioned file management systems that track changes to geometry and annotations, ensuring traceability and collaboration across teams. This approach aligns with standards like ASME Y14.41, which specifies practices for digital product data to support unambiguous definition and exchange. The structure of these 3D digital data sets typically follows a hierarchical organization, comprising individual part models that define component geometry, assembly models that integrate multiple parts into complete products, and linked product manufacturing information (PMI) attached directly to relevant features. This hierarchy enables efficient navigation and reference, with PMI enriching the models by associating tolerances, dimensions, and notes to specific elements without altering the core geometry. For interoperability across different software platforms and stakeholders, data sets are exported to neutral formats such as STEP (), which preserves the hierarchical structure, geometry, and PMI for downstream applications. Throughout the , 3D digital data sets function as the authoritative source, facilitating design reviews through interactive 3D viewers that allow stakeholders to visualize and interrogate the model collaboratively. In , these sets support direct CNC programming by providing machinists with precise geometric and data, reducing interpretation errors compared to traditional drawings. For quality inspection, coordinate measuring machines (CMMs) access embedded in the model to automate verification against specifications, streamlining validation processes. Software tools like MBD exemplify these capabilities by enabling users to define, organize, and publish 3D data sets—including dimensions, tolerances, bills of materials, and views—directly within the CAD environment, bypassing the need for 2D drawings while generating outputs like 3D PDFs for distribution. This integrated functionality supports revision management and hierarchical assembly handling, promoting efficient data set maintenance in engineering workflows.

Embedding Product Manufacturing Information

Embedding Product Manufacturing Information (PMI) into 3D models is a core aspect of model-based definition (MBD), where geometric dimensioning and tolerancing (GD&T) symbols, textual notes, and datum identifiers are integrated directly as 3D annotations linked to specific model features, such as surfaces or edges, to provide precise manufacturing instructions without relying on separate 2D drawings. These annotations attach semantically to the geometry, ensuring that changes to the model automatically update associated tolerances and references, thereby maintaining data integrity throughout the design process. A key advancement in embedding techniques involves the use of semantic , which structures annotations in a machine-readable format that includes explicit associations between GD&T elements—like feature control frames and datum targets—and the underlying geometry, enabling automated downstream processes such as and . Unlike graphical , which serves primarily visual purposes, semantic representations use standardized schemas to encode relationships, allowing software tools to interpret and extract data without manual reinterpretation. Automation methods enhance the efficiency of PMI embedding by employing rule-based systems to place tolerances automatically based on predefined rules, such as applying standard fits or surface finishes to specific feature types during model creation. For instance, (BOM) generation can be automated directly from model assemblies by parsing embedded PMI to compile hierarchical parts lists, including attributes like material specifications and quantities derived from the structure. Validation tools further support this by systematically checking PMI completeness, identifying gaps in annotations such as missing datums or inconsistent tolerances, and generating reports to ensure compliance before model release. Interoperability challenges arise when translating PMI between CAD systems, as differences in native formats can lead to loss of semantic associations, resulting in annotations that appear visually but lack machine-readable links to geometry. Neutral formats like JT address this by preserving both geometric and PMI data during export and import, supporting the retention of GD&T semantics across diverse platforms, though full fidelity requires adherence to ISO 14306 standards for JT visualization. Despite these capabilities, incomplete translations can still occur if source systems use proprietary extensions not supported in JT, necessitating pre- and post-translation validation to verify PMI integrity. Best practices for embedding PMI emphasize layering annotations to tailor visibility for different stakeholders, such as restricting manufacturing-specific notes to production teams while exposing only design-relevant data to engineers, thereby reducing cognitive overload in complex models. Color-coding further aids clarity by assigning distinct hues to annotation types—e.g., for dimensions, for critical tolerances—facilitating quick identification and review during collaborative workflows. These techniques, when combined with dynamic views that hide or reveal layers based on user roles, promote efficient model navigation and minimize errors in interpretation.

Comparison to Traditional Approaches

Conventional 2D Drawings

Conventional 2D drawings represent the traditional method of documenting designs through two-dimensional illustrations that convey the , dimensions, and requirements of parts and assemblies. These drawings primarily utilize orthographic projections, which project the object's features onto perpendicular planes to create multiple views—typically front, top, and side—providing a precise, scalable representation without . Detailed views enlarge specific areas for clarity on intricate features, while title blocks in the lower right corner include critical such as drawing number, , units, date, and approver signatures. Dimensions and tolerances are often presented on dedicated sheets or sections to prevent , adhering to international standards like for general principles of presentation in drawings. The workflow for creating conventional 2D drawings traditionally involves manual drafting by hand or, in modern contexts, semi-automated generation using CAD software that extracts views from 3D models. This process begins with sketching or modeling the design, followed by projecting orthographic views, adding annotations, and verifying compliance with standards; however, the resulting drawing functions as an independent artifact, separate from the originating 3D model, establishing dual sources of truth that must be manually synchronized. Despite their precision, conventional drawings exhibit significant limitations, including susceptibility to interpretation errors arising from ambiguous line work, hidden features, or inconsistent scaling across views. Version mismatches frequently occur when updates to the model are not fully propagated to the drawing, leading to outdated specifications in downstream . Scalability issues emerge with complex assemblies, where hundreds of sheets may be needed to capture inter-part relationships, complicating and . Moreover, revisions demand time-intensive manual updates to all affected views and annotations, often consuming hours or days per change. Engineering drawings achieved historical dominance as the primary design communication tool during the 19th-century , when necessitated standardized, reproducible plans for machinery and infrastructure, evolving from artisanal sketches to formalized orthographic methods. This practice was further codified through (GD&T) in the standard, first published in 1966, with subsequent revisions including 1982, which provided a symbolic language for specifying form, orientation, and location tolerances on 2D drawings to ensure interchangeability in .

Limited Dimension Drawings

Limited Dimension Drawings (LDDs) consist of sheets containing only essential views, critical dimensions, tolerances, and notes, with explicit references to the accompanying model as the authoritative source for complete product definition, such as statements like "Refer to model for all unspecified dimensions and details." These drawings minimize redundancy by avoiding full replication of the data, focusing instead on key or requirements that benefit from visual representation. As a hybrid approach, LDDs function as a transitional method between conventional 2D drawings—which offer standalone, comprehensive specifications—and fully integrated Model-Based Definition (MBD) systems. They are particularly useful in engineering sectors transitioning to digital workflows, where legacy processes and tools still predominate, allowing teams to leverage existing CAD models while retaining familiar formats for review, procurement, or . This setup reduces the effort required to produce and maintain extensive documentation, streamlining communication without demanding immediate overhaul of infrastructure or training. In applications, LDDs often include assembly overviews, primary datums, and (GD&T) callouts for critical features, directing users to the model for supplementary geometry and attributes; for instance, the engineering drawings for 's wheels employed LDDs to specify only key wall thickness controls and tolerances, with all other details derived from models. Similarly, engineering practices define LDDs as delineating single parts with limited annotations to establish essential requirements, supplemented by the model to ensure full compliance with intent. These practices align with standards like ASME Y14.41, which supports digital product definition data practices integrating 2D and 3D elements. LDDs facilitate adoption in regulated industries by providing a compliant "" artifact where documentation is mandated, enabling gradual integration of MBD without violating legacy requirements for tangible records. This model-referenced strategy enhances accuracy by centralizing information in the source, mitigating errors from dual documentation while preserving accessibility for stakeholders accustomed to paper-based or PDF formats.

Standards and Adoption

Key Standardization Efforts

The (ASME) Y14.41 standard, first published in 2003 and revised in 2012 and 2019, provides essential guidelines for digital product definition data practices in the United States. It specifies requirements for embedding product manufacturing information (PMI), such as (GD&T), directly into models, enabling the transition from traditional drawings to fully annotated digital representations. This standard addresses the preparation, revision, and interpretation of data sets, ensuring consistency in how PMI is applied and visualized in (CAD) environments. Internationally, ISO 16792, first edition released in 2006, second edition in 2015, and third edition in 2021, establishes requirements for technical product documentation using digital formats. It focuses on the preparation, revision, and presentation of data sets, with particular emphasis on integrating GD&T and other annotations into models to support unambiguous instructions. The standard promotes across software tools by defining rules for PMI syntax and semantics, facilitating global adoption of model-based practices in . For data exchange, the STEP Application Protocol 242 (AP242), defined in ISO 10303-242, serves as a neutral file format that preserves PMI during transfer between systems. The second edition, published in 2020, supports managed model-based 3D engineering by including capabilities for assembly structures, , and process data alongside geometric models. A fourth edition is under development, with publication expected in 2025. This protocol ensures that MBD information remains intact and interpretable, reducing errors in collaborations. Sector-specific efforts complement these core standards. In the , the (AIAG) issued the 3D Model Technical Data Package Exchange Guideline in July 2025, promoting standardized exchange of model data to support model-based practices and streamline design-to-manufacturing workflows. Similarly, ASD-STE100 provides rules for simplified technical English in annotations, ensuring clear, unambiguous text within 3D models for and applications. These guidelines enhance and in PMI elements like notes and callouts.

Industry Implementation

Model-based definition (MBD) has been widely adopted in the aerospace and defense sector, where organizations like NASA and Lockheed Martin have integrated it into their workflows since the mid-2010s to enhance digital engineering practices. NASA launched its Model-Based Systems Engineering (MBSE) Pathfinder in 2016, demonstrating MBD's application in mission-focused areas and establishing it as a core component of digital model-based engineering across more than two-thirds of its field centers by 2017. Lockheed Martin has driven MBD adoption through its Model-Based Enterprise (MBE) Playbook for suppliers, first released in 2024, which outlines practices for mechanical, electronics, and software categories in new programs. By 2025, the U.S. Department of Defense's digital engineering strategy has incorporated MBD requirements into solicitations for major programs, aligning with broader goals for modular open systems and reduced lifecycle costs. In the automotive industry, companies such as and have implemented MBD via product lifecycle management () integration to streamline design-to-manufacturing processes. utilizes systems to synchronize models across its truck brands. 's -driven interoperability strategy incorporates MBD through multi-CAD visualization and JT file generation, enabling global . These implementations leverage standards like ASME Y14.41 as a foundation for consistent exchange, ensuring compliance in supplier ecosystems. Supply chain challenges in MBD adoption often stem from varying levels of maturity among vendors, prompting the of targeted programs and initiatives. For instance, Martin's MBE Playbook includes guidance for supplier transformation, emphasizing to align with MBD requirements in subcontracts. In 2024, PTC expanded its educational offerings with advanced MBD modules in Creo , while Purdue University's MBD , ongoing as of 2025, provides vendor focused on creating compliant 3D models with PMI. These efforts address issues, with compliance strategies involving validation tools to verify model integrity before production handover. A notable metric of MBD's success is evident in Boeing's 787 Dreamliner program, which pioneered 100% digital definition as the first fully digital aircraft definition in the industry. This approach achieved a 62% reduction in product development time and 42% reduction in development costs. Overall, these sector-specific adoptions demonstrate MBD's role in accelerating compliance with digital engineering mandates up to 2025, fostering measurable improvements in efficiency across complex supply chains.

Benefits and Challenges

Advantages Over Legacy Methods

Model-based definition (MBD) significantly reduces errors in product development by embedding all product information () directly into the model, eliminating the transcription and interpretation challenges inherent in traditional drawings. This approach minimizes discrepancies between intent and manufacturing execution. In comparison to conventional drawings and limited dimension drawings, MBD serves as a single authoritative source, preventing the manual recreation of models that plagues downstream manufacturing processes. MBD delivers substantial time and cost savings by streamlining the design-to-manufacturing handoff, bypassing the need for separate creation and maintenance. Industry research indicates that robust MBD implementations can accelerate production by up to 40% and reduce times by 60%. These efficiencies contribute to decreased rework and resource allocation, as the integrated model automates flow and cuts overhead associated with legacy practices. Enhanced is a core advantage of MBD, enabling real-time access to the model via lightweight viewers that support global teams and advanced inspections using () or (). This fosters seamless communication across , , and stakeholders by providing a shared, interactive rather than static 2D views, improving and reducing misalignments in distributed environments. Compared to traditional methods, MBD's centralized supports concurrent reviews and updates, enhancing productivity in multinational projects. MBD promotes by transitioning to a fully that eliminates paper-based drawings and , thereby reducing physical and . The approach also integrates tools directly with the model for , enabling iterative improvements that minimize material use and energy demands in production. As of 2025, advancements such as PTC's MBD capabilities and Siemens' enhancements have accelerated adoption, with some sectors reporting over 70% growth in MBD implementations.

Barriers to Widespread Use

One major technical hurdle to the widespread adoption of model-based definition (MBD) is the incompatibility of legacy software systems with models enriched with product manufacturing information (). Older CAD and tools often fail to fully support or interpret MBD data, leading to workflows that require manual workarounds or hybrid 2D/ processes. Another significant issue arises during file exchanges, where PMI—such as geometric dimensions, tolerances, and annotations—can be lost or degraded when transferring models between different software platforms or to neutral formats. This loss disrupts downstream processes like and , undermining the single-source-of-truth promise of MBD. Solutions are emerging through updated standards like STEP AP242, which enhances by better preserving PMI in neutral exchanges, though full implementation requires software vendors to adopt these revisions. Organizationally, resistance from personnel trained in traditional 2D poses a substantial barrier, as veteran engineers and drafters view MBD as a threat to established practices and fear a loss of familiarity in reviewing . This cultural inertia is compounded by a broader , with 61% of and leaders reporting difficulty finding employees proficient in technical digital tools, including those needed for MBD. Upskilling initiatives, such as Autodesk's expanded training programs in 2025, aim to address this, but persistent —evident in reduced continuous learning adoption from 71% in 2024 to 64% in 2025—highlight the need for targeted to bridge the divide. Regulatory and legal challenges further impede progress, particularly in industries like where 2D drawings remain the legally accepted and authoritative source of product information for and purposes. Some jurisdictions continue to physical or "signed" drawings to establish accountability in case of disputes, creating hesitation around fully transitioning to digital 3D models. However, this is evolving with the broader acceptance of digital signatures under frameworks like the U.S. ESIGN Act, which legally equates electronic approvals to traditional ones when conditions for authenticity are met, facilitating gradual MBD integration in regulated sectors. Cost factors also deter adoption, as initial investments in upgrading CAD and systems to MBD-compliant versions can be substantial, often requiring hardware refreshes, software licenses, and process reengineering. For large enterprises, these upfront costs—potentially in the millions for comprehensive implementations—are offset by long-term ROI through reduced errors and faster time-to-market, with studies showing productivity gains of up to 30% in tasks after full deployment. Smaller organizations, however, face steeper relative barriers without similar to justify the expenditure.

References

  1. [1]
    Model-based Definition (MBD) - Autodesk
    Model-based definition (MBD) makes 3D models your central source for all product manufacturing information (PMI) throughout the lifecycle.
  2. [2]
    What Is MBD? | Model-Based Definition - PTC
    Model-based definition is an approach to creating 3D models so that they effectively contain all the data needed to define a product.
  3. [3]
    Model-based definition (MBD) - Siemens PLM
    Model-based definition (MBD) enables a complete digital definition of a product within a 3D model. Compared to drawing-centric workflows, NX reduces the time ...
  4. [4]
    Model-Based Definition (MBD): Transforming Product Design
    Model-Based Definition (MBD) is a groundbreaking approach to product design and manufacturing that utilizes 3D models as the primary source of information ...
  5. [5]
    What is Model Based Definition? (MBD) - BCT Technology AG
    Model Based Definition is an approach in which a 3D model with Product Manufacturing Information (PMI) supplements or even replaces a 2D model.
  6. [6]
    Standardizing Model-Based Definition (MBD) - Action Engineering
    Sep 27, 2015 · New standards are emerging as supplements to the existing ASME Y14 standards, born from the need to standardize 3D CAD processes and GD&T.
  7. [7]
    [PDF] Promoting Model-Based Definition to Establish a Complete Product ...
    The Model-based Enterprise (MBE) uses MBD as a way to transition away from using traditional paper- based drawings and documentation.
  8. [8]
    Y14.47 - Model Organization Practices - ASME
    In stockASME Y14.47 establishes a schema for organizing a 3D model and outlines model organization schema practices to support model-based definition (MBD).
  9. [9]
    Model-Based Definition (MBD) and The Role it Plays in Modern ...
    Oct 28, 2025 · Widespread adoption of model-based definition (MBD) was cemented by standards like ASME Y14.41 and ISO 16792, which define digital product ...
  10. [10]
    Model Based Enterprise (MBE) - ASME
    Model Based Enterprise (MBE) uses digital data for company-wide communication, with ASME developing rules for model-based datasets and data models.
  11. [11]
    MBD (Model-Based Definition): 2023 Edition - Capvidia
    Model-Based Definition (MBD) is the process of defining product & engineering data within a 3D CAD model. An MBD approach creates a single source of truth that ...What Is Mbd (model-Based... · Process & Automation · Data & Analytics<|control11|><|separator|>
  12. [12]
    Model-Based Definition in 3D CAD: Advances, Methods and Quality ...
    Oct 23, 2025 · A fully annotated 3D model can contain: Geometric dimensioning and tolerancing (GD&T); Material and finish specifications; Assembly instructions ...
  13. [13]
    [PDF] Model Based Definition (MBD) Replacing Technical Drawings
    May 19, 2023 · Technical drawings precede Model Based Definition. The history of technical drawings dates back centuries, with early examples of technical ...
  14. [14]
    What is MBD (Model-Based Definition)? - Onshape
    Jun 18, 2025 · This approach, known as Model-Based Definition (MBD), embeds manufacturing intent directly into the model earlier in the design process — ...
  15. [15]
    The Differences Between MBD, MBE, and MBSE - Action Engineering
    May 14, 2024 · Model-Based Definition (MBD) is the practice of using a 3D CAD model and associated data instead of relying solely on engineering drawings.
  16. [16]
    Model-Based Approaches: MBSE, MBD, and MBE - ATS Global
    Jun 6, 2025 · Explore the distinctions between MBSE, MBD, and MBE in ATS Global's blog, clarifying their roles in modern engineering and manufacturing ...
  17. [17]
    Model-Based Definition and Enterprise: State-of-the-art and future ...
    Nov 17, 2020 · Model-Based Definition (MBD) is based upon the shift from conventional 2D drawings to 3D CAD models as a single source of product definition ...
  18. [18]
    Model-Based Enterprise Program
    ### Summary of Model-Based Definition (MBD), Core Principles, and Historical Context from NIST Model-Based Enterprise Program
  19. [19]
    What Is MBD? A Beginner's Guide to Model-Based Definition
    May 8, 2025 · Model-Based Definition (MBD) replaces traditional 2D engineering drawings with a fully annotated 3D digital model.
  20. [20]
    Y14.5 - Dimensioning and Tolerancing - ASME
    In stockThe Y14.5 standard is considered the authoritative guideline for the design language of geometric dimensioning and tolerancing (GD&T.)
  21. [21]
    Y14.36 - Surface Texture Symbols - ASME
    In stockThis standard establishes the method to designate controls for surface texture of solid materials. It includes methods for controlling roughness, waviness, and ...
  22. [22]
    Y14.41 - Digital Product Definition Data Practices - ASME
    In stockASME Y14.41 establishes requirements for digital product definition data (data sets) such as annotated models with or without a drawing graphic sheet.<|control11|><|separator|>
  23. [23]
    ISO 16792:2021 - Digital product definition data practices
    In stockThis document specifies requirements for the preparation, revision and presentation of digital product definition data, hereafter referred to as data sets.
  24. [24]
    ISO 10303-242:2022 - Industrial automation systems and integration ...
    ISO 10303-242 specifies the application protocol for Managed model based 3d engineering. The following are within the scope of ISO 10303-242:
  25. [25]
    MBE PMI Validation and Conformance Testing Project | NIST
    Sep 24, 2013 · 5 defines the symbology used for specifying PMI. ASME 14.41 specifies how to present PMI in 2D and in 3D. The most current versions of ASME Y14.Mbe Pmi Validation And... · Test Cases · Test Cad Models
  26. [26]
    Sketchpad: a man-machine graphical communication system
    The Sketchpad system makes it possible for a man and a computer to converse rapidly through the medium of line drawings.<|control11|><|separator|>
  27. [27]
    The history of CAD and examples of its use in industry - SINTEF
    ... 1970s. The CAD of the 1960s and early 1970s was dominated by batch systems using punched cards as input, and pen plotters as output to produce engineering ...
  28. [28]
    Autodesk and AutoCAD - History of CAD - Shapr3D
    Mar 27, 2023 · The CAD software shown at that conference was AutoCAD-80, so named because it ran on machines powered by either the Zilog Z80 or Intel 8080 ...
  29. [29]
    History | About - Dassault Systèmes
    Founded in 1981 to revolutionize the aerospace industry with CAD, Dassault Systèmes has consistently built on our strong foundations to shape a brighter future ...
  30. [30]
    The Benefits of Moving from 2D Drawings to 3D CAD Files - Protolabs
    Aug 20, 2020 · 3D CAD technology offers richer design context, a much lower margin for error, and a much swifter route to manufacturing.<|control11|><|separator|>
  31. [31]
    Model-based definition design in the product lifecycle management ...
    Aug 5, 2025 · Model-based definition (MBD) is a new strategy of product lifecycle management (PLM) based on computer-aided design (CAD) models.
  32. [32]
    Fact Sheet: ISO 10303-242 (STEP AP242) - prostep ivip
    STEP AP242 is the successor of AP203 and AP214. STEP AP 242 Edition 1 (published in 2014) provides all the functionalities covered by the AP 203 ed2 and AP 214 ...
  33. [33]
    d-39 sasig white paper: model based enterprise - AIAG
    This paper describes the current and future states of MBE in the automotive industry, promotes the implementation of the 3D-MBD model and provides guidance.Missing: adoption 2010s
  34. [34]
    Framework for circular AI-driven model-based systems engineering
    Aug 27, 2025 · This paper introduces a novel framework integrating Artificial Intelligence into MBSE to enhance sustainability and circularity by automating ...
  35. [35]
    PTC unveils cloud-native MBD in Onshape - DEVELOP3D
    Jun 12, 2025 · “Our new MBD capabilities remove the need to interpret 2D drawings by embedding PMI directly into the 3D model. This will enable teams to work ...Missing: time | Show results with:time
  36. [36]
    An MBD-Enabled Digital Twin Modeling Method for Cognition ...
    Model-based Definition (MBD) expresses the technical information of traditional engineering drawings in a three-dimensional environment. The formed MBD ...
  37. [37]
    [PDF] DIGITAL ENGINEERING STRATEGY - Mission Capabilities
    The strategy addresses a range of disciplines involved in the acquisition and procurement of national defense systems, and it encourages innovation in the way.Missing: mandate | Show results with:mandate
  38. [38]
    Promoting Model-Based Definition to Establish a Complete Product ...
    Aug 31, 2016 · The Model-based Enterprise (MBE) uses MBD as a way to transition away from using traditional paper-based drawings and documentation. MBD has ...
  39. [39]
    [PDF] Based Design and Inspection Data in Augmented Reality
    Feb 7, 2022 · STEP files facilitate interoperability between different CAD software packages and are used to represent. PMI and other information vital for ...
  40. [40]
    Model Based Definition (MBD) | JANUS Engineering USA
    Jul 30, 2024 · MBD is a concept in which a 3D model of a product or component serves as the sole source of information for design, manufacturing and inspection.
  41. [41]
    Model-Based Definition Capabilities - SOLIDWORKS MBD
    SOLIDWORKS Model-Based Definition (MBD) lets you define and organize 3D dimensions, tolerances, datums, notes, Bills of Material (BOMs), and other annotations.
  42. [42]
    SOLIDWORKS MBD - 2020
    SOLIDWORKS MBD (Model Based Definition) lets you create models without the need for drawings giving you an integrated manufacturing solution for the SOLIDWORKS ...Missing: sets | Show results with:sets
  43. [43]
    Inventor 2024 Help | About 3D Annotation and Model-Based Definition
    The term Model-Based Definition (MBD) refers to a fully defined 3D model. The annotated 3D model is often sent directly to manufacturing to create the physical ...
  44. [44]
    Model-Based Definition Puts GD&T Data to Work - Quality Magazine
    Mar 8, 2018 · Although there are many GD&T symbols, most CAD models can be annotated effectively using only position, profile, and flatness callouts.
  45. [45]
    3DEXPERIENCE Model-Based Definition and 2D Drawings
    Apr 28, 2025 · Annotations, including dimensions, tolerance information, and GD&T symbols can be added in two ways. The first way is directly in the 3D model ...
  46. [46]
    Automated PMI Validation in MBD Models - CADIQ - CAD Interop
    Discover how to optimize CAD model validation with PMI to ensure the integrity and quality of technical data. CADIQ provides a comprehensive solution to ...Missing: mechanisms | Show results with:mechanisms
  47. [47]
    Leveraging model-based definition to accelerate adoption of a ...
    The comprehensive MBD capabilities centering around automatic, rule-based PMI creation for GPS within NX allows companies to define, store and manage their own ...Missing: placement | Show results with:placement
  48. [48]
    Integrating MBD with BOM for consistent data transformation during ...
    Aug 9, 2025 · A BoM-generation AI model (BoM-GAIM) is presented that can automate BoM generation based on Mask R-CNN and the image segmentation technique.
  49. [49]
    [PDF] MBD Interoperability Challenges and Solutions
    Are lightweight visualization models (JT, 3D PDF etc...) complete and correct? • Are direct translations to other CAD formats successful? • Can we rely on ...
  50. [50]
    Guide to the NIST PMI CAD Models and CAD System PMI Modeling ...
    Oct 5, 2017 · The verification and validation results measure PMI implementation capabilities in CAD software and derivative STEP, JT, and 3D PDF files.
  51. [51]
    What is JT file format and extension - CAD Exchanger
    The JT format is a widely used lightweight 3D data format designed for efficient visualization, collaboration, and sharing of complex 3D models and assemblies.
  52. [52]
    [PDF] An Analysis of Step, Jt, and Pdf Format Translation Between ...
    Jan 1, 2012 · Interoperability causes problems in the design process leading to significant economic inefficiencies at an estimated cost of $1 billion in the.Missing: challenges | Show results with:challenges
  53. [53]
    MBD Implementation Dos and Don'ts: Organize and Present 3D PMI ...
    Apr 7, 2016 · Organize 3D PMI clearly to avoid "fur ball" issues. Use view layers and SOLIDWORKS tools like dynamic annotation views and 3D views to present ...
  54. [54]
    Here's why 3D models need product manufacturing information
    Aug 22, 2019 · In fact, most design software can organize PMI in annotation layers, showing what's relevant for specific audiences. No one ever has to look ...Missing: color- coding<|control11|><|separator|>
  55. [55]
    Basics of Engineering Working Drawings - IspatGuru
    Aug 8, 2023 · Engineering drawings normally utilize orthographic views rather than axonometric views. Orthographic view helps to record the shapes of objects ...
  56. [56]
    Modern Engineering and Manufacturing Part 2: Integrating Model ...
    Oct 25, 2023 · In this integrated workflow 2D drawings serve as a reference and complementary documentation to the annotated 3D model. They provide a ...
  57. [57]
    [PDF] Model-Based Enterprise Summit Report
    – Drawings are time consuming to create and duplicated effort. • 2D drawing are more prone to interpretation errors than 3D models. – Drawings alone are not ...Missing: limitations | Show results with:limitations
  58. [58]
    Evolution Of Engineering Drawing In Modern Transportation Systems
    Early engineering drawings served as a reference for craft workers to construct a building or manufacture a product. Craft workers viewed the drawings and ...
  59. [59]
    The ASME Y14.5 GD&T Standard
    Jul 24, 2020 · The ASME Y14.5 standard establishes symbols, definitions, and rules for geometric dimensioning and tolerancing. The purpose of the standard is ...
  60. [60]
    Model Based Definition: What is it and Why? - XRG Technologies
    Oct 5, 2021 · Model Based Definition (sometimes Drafting or Dimensioning or Design) is an iteration to mechanical design that uses a CAD generated 3D model ...
  61. [61]
    Why Aren't There Basic Dimensions in MBD? - Action Engineering
    Feb 24, 2021 · What does 'minimally dimensioned' mean? We also used to call that a 'reduced dimension drawing' or a 'limited dimension drawing.' That occurred ...
  62. [62]
    Reaching the Outer Limits with GibbsCAM and the Mars Rover Wheel
    Apr 17, 2019 · The engineering drawings for the Mars Rover wheels were “Limited Dimension Drawings.” Only the key features, datums, and GD&T elements were ...Missing: reduce | Show results with:reduce
  63. [63]
    [PDF] ENGINEERING DRAWING PRACTICES VOLUME I OF II ...
    Aug 11, 2020 · Limited Dimension Drawings ... or paragraph(s) of the standard, the entire standard is invoked. For example,. “Dimensioning and tolerancing ...
  64. [64]
    MBE White Paper Model Based Enterprise
    This white paper describes the current state of MBE in the automotive industry. It will focus on promoting the implementation of the 3D-MBD model to enable ...Missing: adoption 2010s
  65. [65]
    ASD-STE100 HOME PAGE
    ASD-STE100 Simplified Technical English (STE for short) is a controlled natural language and an international standard to write technical documentation. It is ...STE Downloads · About STE · Stemg · Tools for STEMissing: annotations | Show results with:annotations
  66. [66]
    [PDF] Model-Based Systems Engineering Pathfinder
    Abstract. In 2016, the NASA Engineering and Safety Center established a model-based systems engineering (MBSE) Pathfinder. The primary motivations for ...
  67. [67]
    [PDF] Digital Model-Based Engineering: Expectations, Prerequisites, and ...
    NASA has implemented aspects of DMbE on more than three dozen flight programs/ projects at more than two-thirds of its Flight and Research Field Centers, ...
  68. [68]
    [PDF] Lockheed Martin's Model-Based Enterprise Playbook for Suppliers
    Model-Based Definition (MBD)​​ The term MBD refers to the technical data used in the MBE. It includes digital 3D model files and their supporting digital ...Missing: placement | Show results with:placement
  69. [69]
    MBE Playbook Updated | Lockheed Martin
    Apr 17, 2025 · In 2024, Lockheed Martin published our Model-Based Enterprise (MBE) Playbook for Supply Chain. Transformation to MBE is underway across all industries.
  70. [70]
    [PDF] Implementing a Modular Open Systems Approach in Department of ...
    This guidebook provides the Department of Defense (DoD) community, including Military Services, civilians, and DoD support contractors with information to help ...
  71. [71]
    In Defense of Digital Engineering - Ansys
    May 15, 2025 · Digital engineering, mandated by DoDI 5000.97, uses system and data models to incorporate digital engineering into all defense programs.
  72. [72]
    Volkswagen's Epic Challenge to synchronize PLM for its Truck Brands
    Apr 16, 2015 · There's an ongoing battle over which PLM/PDM system Volkswagen Group will use as the backbone for its truck manufacturers.
  73. [73]
    [PDF] PLM-Driven 3D Interoperability @ Ford
    Ford's PLM-driven 3D interoperability uses visualization, multi-CAD, single PDM, and JT generation for seamless integration, enabled by a global PLM strategy.
  74. [74]
    Model-Based Enterprise Approach in the Product Lifecycle ... - MDPI
    It is expected that the configuration of a model-based enterprise could potentially reduce the costs by 50% and the time to market by 45% if compared with ...
  75. [75]
    Now Available: MBE Playbook for Supply Chain - Lockheed Martin
    Mar 12, 2024 · The MBE playbook includes foundational terms and concepts as well as impacts to Lockheed Martin subcontracts.<|control11|><|separator|>
  76. [76]
    PTC University | PTC Product Training | LEARN Online
    PTC University provides comprehensive product training courses and certification programs for PTC products, including Creo, Windchill, Codebeamer, ...
  77. [77]
    MBD Certificate Program | Purdue Polytechnic
    Jun 23, 2025 · The class is targeted at CAD designers or others who are tasked with creating 3D CAD models that contain Product and Manufacturing Information.Missing: PTC | Show results with:PTC
  78. [78]
    [PDF] Implementation of Model-Based Definition in the Defence Industry
    Jul 29, 2025 · Thus, MBD aims to unify 3D models, 2D drawings, and design/manufacturing data into a single source of truth for all product-related information ...
  79. [79]
    https://blogs.sw.siemens.com/solidedge/solid-edge-2025-model-based/
  80. [80]
    https://www.engineering.com/6-reasons-we-still-cant-switch-to-mbd-and-the-ways-forward/
  81. [81]
    Model-Based Product Dev Is Key to Innovative Design - PTC
    Jun 27, 2023 · PTC's customer research shows a robust MBD approach helps companies produce documentation up to 40% faster, reduce first article inspection time ...Missing: study | Show results with:study
  82. [82]
    https://www.researchgate.net/publication/335870398_Challenges_of_Model-Based_Definition_for_High-Value_Manufacturing
  83. [83]
    Promoting Model-based Definition to Establish a Complete Product ...
    Model-based definition is a process that allows the design team to input all their information into the 3D model, thus eliminating the need to create a drawing.Literature Review · Model-Based Definition · Common Information Model
  84. [84]
    6 reasons we still can't switch to MBD—and the ways forward
    Feb 6, 2025 · Model-based definition has many benefits, but ditching 2D drawings has even more challenges. Here's what needs to happen for MBD to succeed.How Mbd Works, And Why We... · Problem 4: Software... · Problem 5: Supplier...<|control11|><|separator|>
  85. [85]
    6 Challenges of Implementing MBD — and How to Overcome Them
    Aug 27, 2025 · Adopting Model-Based Definition (MBD) requires cross-functional alignment, role-specific training, and process integration.Missing: sets hierarchical
  86. [86]
    Challenges of Model-Based Definition for High-Value Manufacturing
    Sep 17, 2019 · This approach needs a standardized neutral exchange format for the 3D model, like STEP AP242 (ISO 10303-242), which can handle the ...Missing: loss | Show results with:loss
  87. [87]
    [PDF] 2025 State of Design & Make
    Apr 16, 2025 · Nearly half of all respondents (48%) say they do not have the resources to design internal training programs, up 10 points over 2024 ...Missing: MBD | Show results with:MBD
  88. [88]
    Electronic Signatures 101: Are they Legal? - Clio
    Aug 7, 2025 · Yes, electronic signatures are legal in the US under the ESIGN Act and UETA. They are as binding as handwritten signatures if certain conditions are met.
  89. [89]
    [PDF] THE ROI OF MBD | Lifecycle Insights
    Here, you will find new research findings on which MBD practices and methods translate to productivity gains and downstream benefits, both for engineering and ...Missing: barriers CAD PLM