comsol simulation diagram Search Results


simulation schematic diagram  (COMSOL Inc)
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COMSOL Inc simulation schematic diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Schematic Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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comsol simulation diagram  (COMSOL Inc)
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COMSOL Inc comsol simulation diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Comsol Simulation Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation diagram of strain distribution on the device  (COMSOL Inc)
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COMSOL Inc simulation diagram of strain distribution on the device
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Diagram Of Strain Distribution On The Device, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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model diagrams  (COMSOL Inc)
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COMSOL Inc model diagrams
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Model Diagrams, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation diagram  (COMSOL Inc)
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COMSOL Inc simulation diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation modeling diagram  (COMSOL Inc)
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COMSOL Inc simulation modeling diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Modeling Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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li-ion concentration distribution simulation diagram  (COMSOL Inc)
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COMSOL Inc li-ion concentration distribution simulation diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Li Ion Concentration Distribution Simulation Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation diagram of li+ concentration distribution  (COMSOL Inc)
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COMSOL Inc simulation diagram of li+ concentration distribution
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Diagram Of Li+ Concentration Distribution, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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structure stress simulation diagram  (COMSOL Inc)
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COMSOL Inc structure stress simulation diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Structure Stress Simulation Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation streamline diagram  (COMSOL Inc)
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COMSOL Inc simulation streamline diagram
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Streamline Diagram, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation tools for band diagram construction for ge/pedot:pss heterojunctions comsol multiphysics modeling software  (COMSOL Inc)
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COMSOL Inc simulation tools for band diagram construction for ge/pedot:pss heterojunctions comsol multiphysics modeling software
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Tools For Band Diagram Construction For Ge/Pedot:Pss Heterojunctions Comsol Multiphysics Modeling Software, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation diagram of strain distribution  (COMSOL Inc)
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COMSOL Inc simulation diagram of strain distribution
a <t>Schematic</t> illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the <t>COMSOL</t> software based on finite-element <t>simulation.</t> d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.
Simulation Diagram Of Strain Distribution, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Image Search Results


a Schematic illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the COMSOL software based on finite-element simulation. d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.

Journal: Nature Communications

Article Title: Self-encapsulated ionic fibers based on stress-induced adaptive phase transition for non-contact depth-of-field camouflage sensing

doi: 10.1038/s41467-024-44848-5

Figure Lengend Snippet: a Schematic illustration about se-HICFs as self-powered sensor based on the principles of electrostatic induction ( b ) The working principle of se-HICFs for noncontact sensing. c The potential distribution during the se-HICFs sensing moving object simulated by the COMSOL software based on finite-element simulation. d The V oc of se-HICFs with different diameters in sensing the test object. e The V oc of se-HICFs in different sensing distance with the test object. f The V oc of se-HICFs when sensing test objects with different sizes. g The V oc of se-HICFs when sensing the PET film with area of 5 ⨯ 5 cm 2 with frequency from 0.5 to 2.5 Hz. h The V oc of se-HICFs when sensing different test objects with various materials. i The V oc of se-HICFs in diameter of 50 μm and 200 μm when sensing a PET film within 60 days. (The se-HICFs length is 10 cm, the PET film is in size of 5 ⨯ 5 cm 2 , the loading distance is 8 cm and the reference distance is 1 cm). The error bar for each data point in ( d – i ) is standard deviation calculated based on 3 parallel measurements.

Article Snippet: The corresponding COMSOL simulation schematic diagram further confirmed the above non-contacting sensing principle through the calculated potential distribution (Fig. ) .

Techniques: Software, Standard Deviation