I installed the software and it installed succesfully. but when i start to working wih 3d max there was no message and the problem also did not solve...please can you help me to make it work on 3dmax 2015
Download Phoenix FD 4.20.00 for 3ds Max 2016-2021 is an outstanding 3D application for simulating and modeling various elements such as fire, smoke, oils and liquids, ocean waves, spasms, foam spray, fog and more.It is a powerful and comprehensive application which comes loaded with advanced tools and durable features to help you enhance your simulations and 3D modeling.It is an efficient application which allows you to create realistic liquid simulations with splashes and foam directly in 3ds Max.It is an ideal tool for 3D artists who want to create dynamic FX using quick presets, fast setup and intuitive controls.With this amazing tool, you can easily create all types of physically-based fluid effects with fast, flexible controls for rendering, retiming and refining simulations.It is compatible with top industry tools such as Alembic, Krakatoa, Stoke MX and OpenVDB.It offers a simple and intuitive interface with self-explaining options which makes it easy for you to create simulated elements. You can also download Sitni Sati FumeFX for 3ds Max 2021 Free Download.
FULL 3ds Max 2016 Portable
Download Phoenix FD 4.20.00 for 3ds Max 2016-2021 is a versatile application which introduces new features and improvements including collision between Active Bodies, Color Absorption, and Massive Wave Force, to let artists achieve production-quality simulations in less time. It uses a powerful simulation engine giving you complete control over more complex effects.It enables you to create any type of fire and smoke effects. It provides a wide range of effects including fire, smoke, liquids, flames, explosions, rigid body simulations, ocean waves, mist and splashes. Additionally, it uses a wide range of emission sources including animated meshes, texture maps, particles and more.It also gives you the possibility to speed up or slow down simulation playback to create perfect for slow motion effects.This wonderful tool also offers support for V-Ray 5 and for 3ds Max 2021 and TexUVW to give you extra control and creativity while making under-the-hood tweaks so your fluid dynamics experience is faster and smoother. You can also download Autodesk 3DS MAX 2022 Free Download.
Click on the link below to start Download Phoenix FD 4.20.00 for 3ds Max 2016-2021. This is a full offline installer standalone setup for Windows Operating System. This would be compatible with both 32 bit and 64 bit windows.
Intracranial hemorrhage is a medical emergency that requires rapid detection and medication to restrict any brain damage to minimal. Here, an effective wideband microwave head imaging system for on-the-spot detection of intracranial hemorrhage is presented. The operation of the system relies on the dielectric contrast between healthy brain tissues and a hemorrhage that causes a strong microwave scattering. The system uses a compact sensing antenna, which has an ultra-wideband operation with directional radiation and a portable, compact microwave transceiver for signal transmission and data acquisition. The collected data is processed to create a clear image of the brain using an improved back projection algorithm, which is based on a novel effective head permittivity model. The system is verified in realistic simulation and experimental environments using anatomically and electrically realistic human head phantoms. Quantitative and qualitative comparisons between the images from the proposed and existing algorithms demonstrate significant improvements in detection and localization accuracy. The radiation and thermal safety of the system are examined and verified. Initial human tests are conducted on healthy subjects with different head sizes. The reconstructed images are statistically analyzed and absence of false positive results indicate the efficacy of the proposed system in future preclinical trials.
The conventional medical imaging tools like MRI and CT scans are able to reliably diagnose ICH7,8,9. However, the static and bulky structures or ionization radiation of those tools limit their capability for rapid diagnosis at the incident location. Moreover, their high costs (in Australia, for example, more than one thousand dollars per scan) limit their use as monitoring tools and their availability at rural medical clinics. According to World Health Organization (WHO), about three-quarter of the world population does not have access to reliable and affordable medical imaging systems10. Hence, a portable and low-cost imaging system is widely demanded for the detection of ICH. Several medical imaging modalities, like electrical impedance tomography (EIT)11, magnetic induction tomography (MIT)12, magnetic induction spectroscopy (MIS)13, or phase shift spectroscopy of magnetic induction (PSSMI)14 are recently explored by the researchers. However, these technologies are either invasive or cannot detect ICH in a realistic environment; hence their practical demonstration is scarce.
Microwave based head investigation has recently attracted a huge attention as a non-invasive alternative or complementary non-ionizing diagnostic tool for various biomedical applications15,16,17,18,19,20,21. This work reports a portable microwave head imaging system, which is simple to employ and consists of an imaging platform, a compactly designed ultra-wideband (UWB) antenna22, a microwave transceiver and a data storing and processing unit. The presented head imaging system utilizes radar based back projection algorithm based on effective permittivity model. One of the prime disadvantages of existing radar based algorithms is the presumption of a constant value for the effective permittivity of the imaged body in order to map the head for any significant scatterer21,23,24,25. However, using a constant number for the heterogeneous head that has various tissues leads to significant imaging errors that may lead to incorrect detection and localization26,27. To address this problem, several researchers have utilized the estimation of direct time of flight of the signal through the imaged body28 or time-domain inverse scattering technique that estimates the spatially averaged permittivity29. However, in a multipath environment such as the heterogeneous human head, the penetrating signal faces different tissues with wide range of properties and thicknesses. In this work, a novel location-dependent point-of-entry based effective head permittivity model derived using the numerical analysis of a healthy human head is proposed. An improved delay-and-sum (DAS) algorithm relying on the derived permittivity model is then employed for reconstructing an image of the head interior with enhanced detection accuracy. The system and algorithm are validated in realistic simulation and experimental environment by using anatomically realistic three-dimensional (3D) printed human head phantom. The radiation and thermal safety of the system are also verified. Human trials on healthy volunteers are then conducted to determinate the type, statistics and thresholds of obtained images as a necessary step for future preclinical trials.
How to cite this article: Mobashsher, A. T. et al. Portable Wideband Microwave Imaging System for Intracranial Hemorrhage Detection Using Improved Back-projection Algorithm with Model of Effective Head Permittivity. Sci. Rep. 6, 20459; doi: 10.1038/srep20459 (2016).
The authors gratefully acknowledge Dr. K. Bialkowski for useful discussions and help with the microwave transceiver in experimental validations, K. Lane for platform fabrication, D. Bill for PCB fabrication, M. Lynne for 3D printing of head phantom exterior and School of Chemistry and Molecular Biosciences of University of Queensland for the providing fabrication facilities for tissue emulating materials. A.T.M. acknowledges the financial support from the University of Queensland, Australia. The project was funded by the Australian Research Council (ARC) via the Discovery Grant DP150103425.
The Micca Speck G2 is a compact yet powerful portable digital media player, providing convenient playback of all popular photo, music, and video formats up to 1080p Full-HD resolution on any TV or HDTV! It has a 1080p HDMI output for sending sharp and clear video and audio in pure digital format to HDTVs, as well as composite AV output for use with analog TVs.
Small and sleek, the Micca Speck G2 is a perfect entertainment source for vacations and business trips. Its aluminum exterior is tough enough to withstand the rigors of portable use. With the optional car power adapter, the Micca Speck G2 can be used to play movies on in-car video system and keep everyone entertained on trips short and long.
The affected Seagate Expansion USB hard drives use their own power supply and has a delayed turn-on mechanism that is not supported by the Micca Speck media player. When connected to the Micca Speck, the Speck detects the drive but is not able to read its contents or play any media files from it. Older Seagate Expansion desktop USB hard drives, as well as Seagate portable USB hard drives are not affected by this compatibility issue.
Unlike other techniques such as touch probes or interferometry, the NANOVEA 3D Non-Contact Profilometer, using axial chromatism, can measure nearly any surface, sample sizes can vary widely due to open staging and there is no sample preparation needed. Nano through macro range is obtained during surface profile measurement with zero influence from sample reflectivity or absorption, has advanced ability to measure high surface angles and there is no software manipulation of results. Easily measure any material: transparent, opaque, specular, diffusive, polished, rough etc. The 2D and 2D capabilities of the NANOVEA Portable Profilometers make them ideal instruments for full complete weld surface inspection both in the lab and in the field. 2ff7e9595c
Comments