schematic diagrams Search Results


simulation schematic diagram  (COMSOL Inc)
90
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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schematic 2d diagrams of protein–ligand complexes  (AUTODOCK GmbH)
90
AUTODOCK GmbH schematic 2d diagrams of protein–ligand complexes
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.
Schematic 2d Diagrams Of Protein–Ligand Complexes, supplied by AUTODOCK GmbH, 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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schematic diagram of stretching model  (COMSOL Inc)
90
COMSOL Inc schematic diagram of stretching model
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.
Schematic Diagram Of Stretching Model, 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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schematic diagram of tensile testing device  (Tensil Labglass)
90
Tensil Labglass schematic diagram of tensile testing 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.
Schematic Diagram Of Tensile Testing Device, supplied by Tensil Labglass, 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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schematic diagram  (AUTODOCK GmbH)
90
AUTODOCK GmbH 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.
Schematic Diagram, supplied by AUTODOCK GmbH, 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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schematic food web diagrams  (Barents Group LLC)
90
Barents Group LLC schematic food web diagrams
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Food Web Diagrams, supplied by Barents Group LLC, 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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schematic diagram of the 1d lisbs  (COMSOL Inc)
90
COMSOL Inc schematic diagram of the 1d lisbs
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of The 1d Lisbs, 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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schematic diagram of the first-level structure fdtd biomimetic conditions  (BioMimetic Therapeutics)
90
BioMimetic Therapeutics schematic diagram of the first-level structure fdtd biomimetic conditions
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of The First Level Structure Fdtd Biomimetic Conditions, supplied by BioMimetic Therapeutics, 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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schematic diagram of temperature and saturation profile and heat and mass transfer in coal block  (Tsang MD Inc)
90
Tsang MD Inc schematic diagram of temperature and saturation profile and heat and mass transfer in coal block
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of Temperature And Saturation Profile And Heat And Mass Transfer In Coal Block, supplied by Tsang MD 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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schematic diagram of boundary conditions in studied helical heat exchanger  (ANSYS inc)
90
ANSYS inc schematic diagram of boundary conditions in studied helical heat exchanger
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of Boundary Conditions In Studied Helical Heat Exchanger, supplied by ANSYS 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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schematic diagram of the model plant immune system  (Biomodels LLC)
90
Biomodels LLC schematic diagram of the model plant immune system
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of The Model Plant Immune System, supplied by Biomodels LLC, 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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schematic diagram of rnf207 interaction with herg-encoded k+ channels (kv 11.1) with trafficking and degradation pathways  (bioRENDER Inc)
90
bioRENDER Inc schematic diagram of rnf207 interaction with herg-encoded k+ channels (kv 11.1) with trafficking and degradation pathways
<t>Food</t> <t>web</t> <t>diagrams</t> of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. <t>Schematic</t> food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.
Schematic Diagram Of Rnf207 Interaction With Herg Encoded K+ Channels (Kv 11.1) With Trafficking And Degradation Pathways, supplied by bioRENDER 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

Food web diagrams of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. Schematic food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.

Journal: Proceedings of the Royal Society B: Biological Sciences

Article Title: Climate change alters the structure of arctic marine food webs due to poleward shifts of boreal generalists

doi: 10.1098/rspb.2015.1546

Figure Lengend Snippet: Food web diagrams of the Barents Sea for the ( a ) boreal, ( b ) arctic and ( c ) arctic II food webs. Each dot (node) represents a trophospecies. The lines connecting the nodes represent the feeding links between the trophospecies. The vertical position of the nodes indicates the trophic position of a species, and the horizontal position indicates the module affiliation of a species. The size of the nodes are proportional to the degree (no. of feeding links) of a species. The colour of the nodes indicates which functional group a trophospecies belongs to: grey, detritus; green, basal taxa; cyan, zooplankton; orange, benthos; blue, fish; magenta, sea birds; light pink, marine mammals. Schematic food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web. Each node (circle) represents a module in the corresponding food web. The size of the nodes indicates the number of trophospecies within each module. The colour of the nodes (pie charts) indicates the habitat affiliation of the trophospecies within the module: light blue, pelagic; red, benthic; dark blue, benthopelagic. The arrow width is proportional to the number of feeding links between modules in the direction of the arrowhead.

Article Snippet: Schematic food web diagrams of the modular structure of the Barents Sea food webs: ( d ) boreal, ( e ) arctic and ( f ) arctic II food web.

Techniques: Functional Assay