| Product Introduction: | | MiniEDU MiniExperimental apparatus for magnetic resonance imaging technologyIt is a mini desktop MRI instrument designed for teaching experiments in MRI technology. MiniEDU is equipped with a virtual data acquisition and image reconstruction experimental teaching platform for magnetic resonance imaging, which combines computer operation with virtual magnetic resonance data acquisition, allowing students to understand magnetic resonance and its imaging principles. Compared with the classic nuclear magnetic imaging technology experimental instrument, the new generation of products has a more compact and beautiful appearance while ensuring powerful and stable functions. It realizes the integration of RF temperature control cabinet, spectrometer cabinet, and power control cabinet, with better overall integrity, simpler and more flexible operation. MiniEDU MiniExperimental apparatus for magnetic resonance imaging technologyExperimental courses such as nuclear magnetic resonance principles and magnetic resonance imaging demonstrations can be offered in conjunction with physics related majors (such as modern physics, applied physics, radio physics, electronic information engineering, etc.) and medical related majors (such as large medical devices, medical imaging technology, biomedical engineering, etc.); Open laboratory courses on equipment hardware structure can also be offered in conjunction with nuclear magnetic resonance engineering majors. | | | | Two major characteristics: openness and authenticity. | | Openness: Both software and hardware have a high degree of openness. 1. Hardware openness: This is reflected in the ability to simulate continuous wave nuclear magnetic resonance experiments during experimental teaching, engineering training, and classroom demonstrations. By opening the back cover of the electronic control cabinet, each unit can be seen, and the hardware structure can be disassembled and assembled on site. Combined with auxiliary tools such as oscilloscopes and multimeters, it can not only exercise students' hands-on ability, but also enhance their understanding of the hardware structure of instruments, which can meet the requirements of modern experimental teaching for students' practical ability; 2. Software openness: mainly reflected in the openness of K-space raw data, which can be used for simulation experiments of image reconstruction. For signal processing and data processing directions, it can provide students and teachers with a large amount of real and effective data, so as to carry out more extensive research on algorithm optimization, image post-processing, and other aspects. Authenticity: MiniEDU has the same module as medical magnetic resonance imaging machines, providing a real experience of the principles, instruments, and applications of magnetic resonance imaging. MiniEDU can meet users' requirements for teaching experiments and is an experimental instrument that conforms to the development of modern teaching. | | | | Experimental apparatus for magnetic resonance imaging technologyProduct Features: | | 1. The data acquisition, processing, and storage of nuclear magnetic resonance signals can observe the FID signals (time domain, frequency domain) and spin echo signals (single or multiple) of the sample during the experimental process; 2. Display processing and storage of magnetic resonance images; 3. Provide K-space raw data; 4. Open testing of system hardware signals; 5. Multiple imaging sequences (SE sequence, FSE sequence, IR sequence, GRE sequence); 6. Optional powerful relaxation time inversion fitting software; 7. Conventional 2D imaging, 2D multi-layer imaging at any angle; 8. Optional MRI 3D reconstruction software can perform 3D image reconstruction on IMG format images; 9. Combine the theory and practice of magnetic resonance imaging with a virtual data acquisition and image reconstruction experimental teaching platform. 1) Can demonstrate the data acquisition process of magnetic resonance imaging through animation; 2) Virtual acquisition of magnetic resonance imaging data and image reconstruction process can be performed; 3) Virtual acquisition imaging of no less than four pulse sequences (SE sequence, FSE sequence, IR sequence, GRE sequence, EPI sequence, Spiral sequence) can be achieved; 4) The influence of observable scanning parameters on image weights can be applied; 5) Can avoid the influence of gradient eddies and simulate the acquisition of heavy T2 weighted images; 6) Can achieve normal speed and fast collection; 7) Can simulate the influence of the uniformity of the main magnetic field; 8) Can simulate the impact of electronic noise; 9) Can implement semi Fourier scanning technology; 10) Can provide input/output interface (DICOM) for raw K-space data. | | | | Note: MicroExperimental apparatus for magnetic resonance imaging technologyIf there are any changes to the appearance, the product technical data shall prevail. | |