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With the explicit modeling, designers quickly and easily create 3D CAD designs, which they then modify through direct, on-the-fly interactions with the model geometry.
The explicit approach is flexible and easy to use, so it’s ideal for companies that create one-off or highly customized products –products that simply don’t require all the extra effort of up-front planning and the embedding of information within models. With an explicit approach to 3D design, the interaction is with the model geometry and not with an intricate sequence of design features. That makes initial training on the software easier. But it also means designers working with an explicit 3D CAD system can easily pick up a design where others left off–much like anyone can open up and immediately continue working on a Microsoft Word document. Thus explicit modeling appeals to a variety of audiences: companies with flexible staff, infrequent users of 3D CAD, and anyone who is concurrently involved in a large number of design projects.
When designers repurpose a model, they take an existing 3D CAD design and radically transform it by cutting/copying/pasting geometry to derive a new model that has no relationship to the original model. With an explicit approach, companies have demonstrated accelerated product development by repurposing existing designs into new and completely different products. This unique characteristic of an explicit approach can shave weeks or even months from project schedules.
Even with direct modeling capabilities, the parametric approach is still designed to leverage embedded product information. The explicit approach, on the other hand, intentionally limits the amount of information captured as part of the model definition in order to provide a genuinely lightweight and flexible product design process.
With a parametric approach, data files include parameters, dimensions, features, and relationships that capture intended behavior. An explicit approach, however, reduces data files to the 3D geometry only, dramatically reducing the design data of each individual part, so large and complex designs don’t overwhelm hardware or software. Smaller file sizes mean designers can load and store data files faster, reload and update parts to new revisions instantly, and make better overall use of their computer memory.
When combined with a data management system, an explicit 3D CAD system can also help manage complex relationships associated with large assemblies. For example, an integrated data management system automates revisioning and encourages true concurrent team design because all designers have access to the most up-to-date design data. When all design data is centralized in a common database, companies can ensure that no one works on the wrong revision of a component, or changes a component reserved by someone else.
Explicit 3D CAD systems excel at importing and modifying of multisource CAD data, which benefits companies working across an extended supply chain for procured components or subcontracted design. STEP and IGES are essentially native 3D design data formats in an explicit approach because explicit 3D CAD systems interact intelligently and on-the-fly with geometry, and geometry is the only common element across all CAD systems. The explicit approach to 3D design, with its lower overhead and flexibility, offers a better solution, especially for companies that rely on the ability to radically adapt and change to new and shifting design requirements.
Companies that develop new-to-market and one-off product designs often face changing customer and product requirements throughout the development cycle. An explicit approach is always open to change, so companies can keep the window for new product information and major product changes open longer. Unlike other 3D design approaches, including hybrids, explicit modeling can offer true flexibility because it doesn’t require any upfront planning or the embedding of design information within models.
Computer-aided design (CAD) is the use of computers to aid in the creation, modification, analysis, or optimization of a design. CAD software is used to increase the productivity of the designer, improve the quality of design, improve communications through documentation, and to create a database for manufacturing. CAD output is often in the form of electronic files for print, machining, or other manufacturing operations. The term CADD is also used.
Creo Elements/Pro, or Creo Elements/Direct Modeling, formerly known, together with Creo Parametric, as Pro/ENGINEER and Wildfire, is a solid modeling or CAD, CAM, CAE, and associative 3D modeling application, running on Microsoft Windows.
Solid modeling is a consistent set of principles for mathematical and computer modeling of three-dimensional solids. Solid modeling is distinguished from related areas of geometric modeling and computer graphics by its emphasis on physical fidelity. Together, the principles of geometric and solid modeling form the foundation of 3D-computer-aided design and in general support the creation, exchange, visualization, animation, interrogation, and annotation of digital models of physical objects.
In industry, product lifecycle management (PLM) is the process of managing the entire lifecycle of a product from inception, through engineering design and manufacture, to service and disposal of manufactured products. PLM integrates people, data, processes and business systems and provides a product information backbone for companies and their extended enterprise.
SolidWorks is a solid modeling computer-aided design (CAD) and computer-aided engineering (CAE) computer program that runs primarily on Microsoft Windows. While it is possible to run SolidWorks on MacOS, It is not supported by SolidWorks. SolidWorks is published by Dassault Systèmes.
Collaborative product development (CPD) is a business strategy, work process and collection of software applications that facilitates different organizations to work together on the development of a product. It is also known as collaborative product definition management (cPDM).
OrCAD Systems Corporation was a software company that made OrCAD, a proprietary software tool suite used primarily for electronic design automation (EDA). The software is used mainly by electronic design engineers and electronic technicians to create electronic schematics, perform mixed-signal simulation and electronic prints for manufacturing printed circuit boards. OrCAD was taken over by Cadence Design Systems in 1999 and was integrated with Cadence Allegro since 2005.
JT is an ISO-standardized 3D data format and is in industry used for product visualization, collaboration, CAD data exchange, and in some also for long-term data retention. It can contain any combination of approximate (faceted) data, boundary representation surfaces (NURBS), Product and Manufacturing Information (PMI), and Metadata either exported from the native CAD system or inserted by a product data management (PDM) system.
Assembly modeling is a technology and method used by computer-aided design and product visualization computer software systems to handle multiple files that represent components within a product. The components within an assembly are represented as solid or surface models.
CAD data exchange is a modality of data exchange used to translate data between different Computer-aided design (CAD) authoring systems or between CAD and other downstream CAx systems.
ARCHICAD is an architectural BIM CAD software for Macintosh and Windows developed by the Hungarian company Graphisoft. ARCHICAD offers computer aided solutions for handling all common aspects of aesthetics and engineering during the whole design process of the built environment — buildings, interiors, urban areas, etc.
Ashlar-Vellum, a dba of Ashlar Incorporated, is a developer of Computer-aided design (CAD) and 3D modeling software for both the Macintosh and Microsoft Windows platforms. Ashlar-Vellum's interface, designed in 1988 by Dr. Martin Newell and Dan Fitzpatrick, featured an automated Drafting Assistant that found useful points in the geometry and allowed the artist to quickly connect to locations like the "midpoint" or "tangent".
T-FLEX CAD by Top Systems (T-FLEX) is a Parasolid-based parametric CAD software application for 3D solid modeling and 2D design and drafting, developed and sold by Russia-based software company Top Systems. T-FLEX CAD is written for Microsoft Windows XP, Vista, and 7 32-bit and 64-bit operating systems, and is distributed in various languages.
GenerativeComponents is parametric CAD software developed by Bentley Systems, was first introduced in 2003, became increasingly used in practice by early 2005, and was commercially released in November 2007. GenerativeComponents has a strong traditional base of users in academia and at technologically advanced design firms. GenerativeComponents is often referred to by the nickname of 'GC'. GC epitomizes the quest to bring parametric modeling capabilities of 3D solid modeling into architectural design, seeking to provide greater fluidity and fluency than mechanical 3D solid modeling.
BricsCAD is a software application for computer-aided design (CAD), developed by Bricsys nv. The company was founded in 2002 by Erik de Keyser, a longtime CAD entrepreneur. In 2011 Bricsys acquired the intellectual property rights from Ledas for constraints-based parametric design tools, permitting the development of applications in the areas of direct modeling and assembly design. Bricsys is headquartered in Ghent, Belgium, has additional development centers in Nizhny Novgorod and Novosibirsk, Russia; Bucharest, Romania and Singapore. Bricsys is a founding member of the Open Design Alliance, and joined the BuildingSMART International consortium in December 2016.
MEDUSA, is a CAD program used in the areas of mechanical and plant engineering by manufacturers and Engineering, Procurement and Construction (EPC) companies. The system's history is closely tied to the beginnings of mainstream CAD and the research culture fostered by Cambridge University and the UK government as well as the resulting transformation of Cambridge into a world-class tech centre in the 1980s.
Cobalt is a parametric-based computer-aided design (CAD) and 3D modeling program that runs on both Macintosh and Microsoft Windows operating systems. The program combines the direct-modeling way to create and edit objects and the highly structured, history-driven parametric way exemplified by programs like Pro/ENGINEER. A product of Ashlar-Vellum, Cobalt is Wireframe-based and history-driven with associativity and 2D equation-driven parametrics and constraints. It offers surfacing tools, mold design tools, detailing, and engineering features. Cobalt includes a library of 149,000 mechanical parts.
Alibre Design is a parametric computer-aided design (CAD) software suite developed by Alibre for Microsoft Windows. Alibre is a brand of Alibre, LLC, a company based out of Texas.
Parametric design is a process based on algorithmic thinking that enables the expression of parameters and rules that, together, define, encode and clarify the relationship between design intent and design response.
Responsive computer-aided design is an approach to computer-aided design (CAD) that utilizes real-world sensors and data to modify a three-dimensional (3D) computer model. The concept is related to cyber-physical systems through blurring of the virtual and physical worlds, however, applies specifically to the initial digital design of an object prior to production.
