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computer assisted modeling cam program fusion360  (Autodesk Inc)

 
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    Structured Review

    Autodesk Inc computer assisted modeling cam program fusion360
    Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A <t>Fusion360</t> model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.
    Computer Assisted Modeling Cam Program Fusion360, supplied by Autodesk Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/computer assisted modeling cam program fusion360/product/Autodesk Inc
    Average 86 stars, based on 1 article reviews
    computer assisted modeling cam program fusion360 - by Bioz Stars, 2026-05
    86/100 stars

    Images

    1) Product Images from "Radial TRASE: 2D RF encoding through mechanical rotation and active digital decoupling"

    Article Title: Radial TRASE: 2D RF encoding through mechanical rotation and active digital decoupling

    Journal: Magnetic Resonance in Medicine

    doi: 10.1002/mrm.70104

    Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A Fusion360 model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.
    Figure Legend Snippet: Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A Fusion360 model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.

    Techniques Used:

    Demonstration of sequential slice Radial TRASE imaging. The pulse sequence for each slice consisted of 200‐μs hard pulses, echo train length of 128, echo time of 2000 μs, repetition time of 1000 ms, acquisition window of 1000 μs, four averages, and 201 radial spokes. A uniform B 0 coil within the magnet bore is used to shift the resonance slice due to the static axial gradient. Imaging was performed with a phantom containing nine 8‐mm‐diameter water vials. One vial is positioned centrally, with the remaining eight angled toward the center by 24°. (A) Sequential slice images were obtained for B 0 shift coil currents of −3, −1.5, 0, 1.5, and 3 A. The expected shift between each slice is 10.4 mm with a reconstructed partition thickness of 3.36 mm. From left to right, the ring of vials spreads outward, indicating successful shifting of the resonance slice position by the uniform B 0 coil. (B) Fusion360 model with a different perspective of the imaged vial phantom.
    Figure Legend Snippet: Demonstration of sequential slice Radial TRASE imaging. The pulse sequence for each slice consisted of 200‐μs hard pulses, echo train length of 128, echo time of 2000 μs, repetition time of 1000 ms, acquisition window of 1000 μs, four averages, and 201 radial spokes. A uniform B 0 coil within the magnet bore is used to shift the resonance slice due to the static axial gradient. Imaging was performed with a phantom containing nine 8‐mm‐diameter water vials. One vial is positioned centrally, with the remaining eight angled toward the center by 24°. (A) Sequential slice images were obtained for B 0 shift coil currents of −3, −1.5, 0, 1.5, and 3 A. The expected shift between each slice is 10.4 mm with a reconstructed partition thickness of 3.36 mm. From left to right, the ring of vials spreads outward, indicating successful shifting of the resonance slice position by the uniform B 0 coil. (B) Fusion360 model with a different perspective of the imaged vial phantom.

    Techniques Used: Imaging, Sequencing



    Similar Products

    computer assisted modeling cam program fusion360  (Autodesk Inc)
    86
    Autodesk Inc computer assisted modeling cam program fusion360
    Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A <t>Fusion360</t> model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.
    Computer Assisted Modeling Cam Program Fusion360, supplied by Autodesk Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/computer assisted modeling cam program fusion360/product/Autodesk Inc
    Average 86 stars, based on 1 article reviews
    computer assisted modeling cam program fusion360 - by Bioz Stars, 2026-05
    86/100 stars
    		  Buy from Supplier

    Image Search Results


    Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A Fusion360 model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.

    Journal: Magnetic Resonance in Medicine

    Article Title: Radial TRASE: 2D RF encoding through mechanical rotation and active digital decoupling

    doi: 10.1002/mrm.70104

    Figure Lengend Snippet: Depiction of the mechanical rotation system. (A) Image of the connected motor outside the RF shielding. The drive rod connects to the motor and is passed directly through a waveguide to the coils. (B) A Fusion360 model of the coil pair within the magnet. The RF coils ( red and yellow ) rest on the bore tube ( green ), which positions the coils centrally and guides rotation. A three‐dimensional‐printed connection ( gray ) affixes the coils to the drive rod ( blue ) axially and houses their circuit boards.

    Article Snippet: Using the computer‐assisted modeling (CAM) program Fusion360 (Autodesk, California, USA), both coils were previously 3D‐printed with the optimized wire pattern modeled directly into their formers.

    Techniques:

    Demonstration of sequential slice Radial TRASE imaging. The pulse sequence for each slice consisted of 200‐μs hard pulses, echo train length of 128, echo time of 2000 μs, repetition time of 1000 ms, acquisition window of 1000 μs, four averages, and 201 radial spokes. A uniform B 0 coil within the magnet bore is used to shift the resonance slice due to the static axial gradient. Imaging was performed with a phantom containing nine 8‐mm‐diameter water vials. One vial is positioned centrally, with the remaining eight angled toward the center by 24°. (A) Sequential slice images were obtained for B 0 shift coil currents of −3, −1.5, 0, 1.5, and 3 A. The expected shift between each slice is 10.4 mm with a reconstructed partition thickness of 3.36 mm. From left to right, the ring of vials spreads outward, indicating successful shifting of the resonance slice position by the uniform B 0 coil. (B) Fusion360 model with a different perspective of the imaged vial phantom.

    Journal: Magnetic Resonance in Medicine

    Article Title: Radial TRASE: 2D RF encoding through mechanical rotation and active digital decoupling

    doi: 10.1002/mrm.70104

    Figure Lengend Snippet: Demonstration of sequential slice Radial TRASE imaging. The pulse sequence for each slice consisted of 200‐μs hard pulses, echo train length of 128, echo time of 2000 μs, repetition time of 1000 ms, acquisition window of 1000 μs, four averages, and 201 radial spokes. A uniform B 0 coil within the magnet bore is used to shift the resonance slice due to the static axial gradient. Imaging was performed with a phantom containing nine 8‐mm‐diameter water vials. One vial is positioned centrally, with the remaining eight angled toward the center by 24°. (A) Sequential slice images were obtained for B 0 shift coil currents of −3, −1.5, 0, 1.5, and 3 A. The expected shift between each slice is 10.4 mm with a reconstructed partition thickness of 3.36 mm. From left to right, the ring of vials spreads outward, indicating successful shifting of the resonance slice position by the uniform B 0 coil. (B) Fusion360 model with a different perspective of the imaged vial phantom.

    Article Snippet: Using the computer‐assisted modeling (CAM) program Fusion360 (Autodesk, California, USA), both coils were previously 3D‐printed with the optimized wire pattern modeled directly into their formers.

    Techniques: Imaging, Sequencing