Simpleware ScanIP 3D Image Segmentation and Processing Software. ScanIP provides a software environment for comprehensively processing 3D image data MRI, CT, micro. Simpleware Scan Ip And Pluscad' title='Simpleware Scan Ip And Pluscad' />The CAD and NURBS addon modules can be used to integrate CAD objects into image data, and to convert scan data into NURBS based models for CAD. ScanIP. Save. Scan. IP, Scan. FE 3. Scan. IP Wikipedia. Scan. IP is a 3. D image processing and model generation app developed by Synopsys Inc. D image data from magnetic resonance imaging MRI, computed tomography CT, microtomography and other modalities for computer aided design CAD, finite element analysis FEA, computational fluid dynamics CFD, and 3. D printing. 2 The app is used in the life sciences, materials science, nondestructive testing, reverse engineering and petrophysics. Segmented images can be exported in the STL file format, surface meshes and point clouds, to CAD and 3. D printing or, with the FE module, exported as surfacevolume meshes directly into leading computer aided engineering CAE solvers. The CAD and NURBS add on modules can be used to integrate CAD objects into image data, and to convert scan data into NURBS based models for CAD. The SOLID, FLOW and LAPLACE add on modules can be used to calculate effective material properties from scanned samples using homogenisation techniques. Application areasedit. Visualisation of composite scan data in Scan. IPScan. IP generates high quality 3. D models from image data suitable for a wide range of design and simulation applications related to the life sciences. Image data from sources like MRI and CT can be visualised, analysed, segmented and quantified, before being exported as CAD, CAE and 3. D printing models. Different tissues, bones and other parts of the body can be identified using a wide range of segmentation and processing tools in the software. Options are also available for integrating CAD and image data, enabling medical device research to be conducted into how CAD designed implants interact with the human body. High quality CAE models can similarly be used in biomechanics research to simulate movement and the effect of different forces on anatomies. An example of this is the US Naval Research LaboratorySimpleware head model, generated from high resolution MRI scans and segmented to create data that can be easily meshed to suit specific finite element FE applications, such as head impact and concussion. Applications for the app have include researching implant position in patient specific data,6 statistical shape analysis,7 and computational fluid dynamics analysis of blood flow in vascular networks. With Simplewares scripting tools, it is possible to explore the best positioning for hip implants. D models can be used to analyse patellofemoral kinematics. Simpleware generated human body models can be used to simulate the effect of electromagnetic radiation in MRI scanners. Other application areas for models created within Simplewares software environment include simulating transcranial direct current stimulation,1. In terms of dental research, evaluations of dental implants have been made by integrating CAD objects with patient data and exporting for simulation. Scan. IP has 5. 10k market clearance from the U. S. Food and Drug Administration FDA as a Class II Medical Device. Scan. IP can reconstruct anatomies from scan data for the investigation of different biological and other organic processes within the Natural Sciences. Paleontological uses of Scan. IP include the reconstruction of dinosaur skeletons,1. STL models of a pseudomorph suitable for 3. D printing. 1. 9 Scan. IP has also been used for biomimicry projects for the Eden Project, and for producing artworks inspired by morphology. Scan. IP can be used to reverse engineer ant necks to improve understanding of their mechanics. Scan. IP has extensive applications in different materials sciences where researchers investigate the properties of scanned samples. Scans of composites and other samples can be visualised and processed in Scan. IP, enabling multiple phases and porous networks to be explored and analysed. Measurements can be taken, for example, of fractures and cracks, and statistics generated for porosity distribution and other features. Scan. IP can be combined with the FE module to generate volume meshes for FE and CFD characterisation of stress or strain distribution, permeability and other material properties. Example applications include fuel cell characterisation,2. Scan. IP is used in the oil and gas industry for generating 3. D models from scans of core samples and rocks. Image data taken from CT, micro CT, FIB SEMexpand acronym and other imaging modalities can be imported and visualised, enabling exploration of pore networks, segmentation of regions of interest, and measurement and quantification of features. Processed data can be exported using the FE module as volume meshes for FEA and CFD in solvers, allowing for insights into fluid structure analysis and other geomechanical properties. Scan. IP can be used to create computational models suitable for detailed visualisation, analysis and export for simulation in CAE solvers. Scanned image data can be easily processed to identify regions of interest, measure defects, quantify statistics such as porosity, and generate CAD and CAE models. Example applications include research into characterising composites,2. With Scan. IP, it is possible to reverse engineer legacy parts and other geometries that cannot be accurately created in CAD. Scans of objects can be visualised and processed in Scan. IP to learn more about their original design, and exported as FE and CFD models for simulation of physical properties. The app has applications in aerospace, automotive and other fields needing to generate accurate 3. D models from scans. Other applications include being able to reverse engineer consumer products in order to analyse their properties,3. Scan. IP is capable of generating robust STL files for 3. D printing. Files created using Scan. IP feature guaranteed watertight triangulations and correct norms, as well as options for volume and topology preserving smoothing. STL files are generated with conforming interfaces, enabling multi material printing. Internal structures, otherwise known as lattices, can also be added to 3. D models of parts in order to reduce weight prior to additive manufacturing. Example applications include the development of patient specific implants,3. Mame 0 153 Rom Set Up. D organ printing. Scan. IP was used to generate STL files of a mans kidney to aid in a procedure at Southampton General Hospital. Lattice techniques have also been used for developing new parts in aerospace, automotive and other industries. Add on modulesedit. Visualisation of engine manifold in Scan. IPThe FE module generates volume meshes with conforming multi parts for FEA and CFD. Finite element contacts, node sets and shell elements can be defined, as can boundary conditions for computational fluid dynamics. Material properties can be assigned based on greyscale values or pre set values. Users can decide between a grid based or a free meshing approach. Meshes can be exported directly into leading Computer aided engineering solvers without the need for further processing. The result can be exported to ABAQUS. ANSYS. ans files, COMSOL Multiphysics. I DEAS. unv files, LS DYNA. MSC. out files, FLUENT. The CAD module allows for the import and interactive positioning of CAD models within image data. The resulting combined models can then be exported as multi part STLs or, using the FE module, converted automatically into multi part finite element or CFD meshes.