→ skos:notation → "5"^^http://id.southampton.ac.uk/ns/building-code-scheme
→ dcterms:spatial → "POLYGON((-1.39507105982364 50.9355985024304,-1.39502425759734 50.9356624730956,-1.39500278786205 50.935691797672,-1.39468011301199 50.9355981061517,-1.39466969255469 50.9356123721839,-1.39464013798185 50.9356037672761,-1.39461193088193 50.9355956152567,-1.39457132703108 50.9355837835038,-1.39451626030417 50.9355677625131,-1.39452937570731 50.9355497035098,-1.39444475440755 50.935525077585,-1.39445454604415 50.935511773919,-1.39453377745221 50.9355348147339,-1.39454078431142 50.9355253040304,-1.3945460843716 50.9355180011674,-1.39455812179641 50.9355015838745,-1.39458956283135 50.93545867244,-1.39464714484106 50.9354753728051,-1.39466609929356 50.9354808641102,-1.39469673184475 50.935489808709,-1.39473428142362 50.9355006780926,-1.39480605681482 50.9355215110707,-1.39492409544316 50.9355557609192,-1.39499901493785 50.9355776128755,-1.39507105982364 50.9355985024304))"^^xsd:string
← is
http://data.ordnancesurvey.co.uk/ontology/spatialrelations/within of
← http://id.southampton.ac.uk/room/5-2011,
http://id.southampton.ac.uk/room/5-2015,
http://id.southampton.ac.uk/room/5-2017,
http://id.southampton.ac.uk/equipment/E10531,
http://id.southampton.ac.uk/equipment/E10533,
http://id.southampton.ac.uk/facility/F10026,
http://id.southampton.ac.uk/equipment/E10544,
http://id.southampton.ac.uk/equipment/E10545,
http://id.southampton.ac.uk/equipment/E10547,
http://id.southampton.ac.uk/equipment/E10552,
http://id.southampton.ac.uk/equipment/E10563,
http://id.southampton.ac.uk/equipment/E10884,
http://id.southampton.ac.uk/facility/F10025,
http://id.southampton.ac.uk/equipment/E10960,
http://id.southampton.ac.uk/floor/5-1,
http://id.southampton.ac.uk/floor/5-2,
http://id.southampton.ac.uk/room/5-1021,
http://id.southampton.ac.uk/room/5-1023,
http://id.southampton.ac.uk/room/5-2025,
http://id.southampton.ac.uk/room/5-2027,
http://id.southampton.ac.uk/floor/5-3
← is
foaf:depicts of
← https://data.southampton.ac.uk/image-archive/buildings/100/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/1000/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/1600/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/1920/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/200/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/220x220/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/240x260/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/300/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/320x198/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/400/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/480x297/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/50/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/600/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/800/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/800x600/5.jpg,
https://data.southampton.ac.uk/image-archive/buildings/raw/5.jpg
→ rdfs:label → "University of Southampton"^^xsd:string
← is
oo:formalOrganization of
← http://id.southampton.ac.uk/building/5,
http://id.southampton.ac.uk/equipment/E10531,
http://id.southampton.ac.uk/equipment/E10533,
http://id.southampton.ac.uk/facility/F10026,
http://id.southampton.ac.uk/equipment/E10544,
http://id.southampton.ac.uk/equipment/E10545,
http://id.southampton.ac.uk/equipment/E10547,
http://id.southampton.ac.uk/equipment/E10552,
http://id.southampton.ac.uk/equipment/E10563,
http://id.southampton.ac.uk/equipment/E10884,
http://id.southampton.ac.uk/facility/F10025,
http://id.southampton.ac.uk/equipment/E10960
→ rdfs:label → "Building 5 is non-residential"^^xsd:string
→ rdfs:label → "Gutteridge & Gutteridge"^^xsd:string
→ rdfs:label → "Lecture Theatre G"^^xsd:string,
"05 / 2011 (L/T G)"^^xsd:string
→ geo:lat → "50.93553578"^^xsd:float
→ skos:notation → "5-2011"^^http://id.southampton.ac.uk/ns/room-code-scheme
→ oo:hasFeature → http://id.southampton.ac.uk/syllabus/room-feature/RSC-+BENCH+PC/RSC-_BENCH_PC,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DATA%2FVIDEO+REPLAY%2FPROJECTION/RSC-_DATA%2FVIDEO_REPLAY%2FPROJECTION,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DISABLED+ACCESS+-+INSTRUCTOR+%28A%29+Ground+Floor+Room+Fully+Accessible/RSC-_DISABLED_ACCESS_-_INSTRUCTOR_%28A%29_Ground_Floor_Room_Fully_Accessible,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DVD/RSC-_DVD,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+LAP/RSC-_LAP,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SEATS+FIXED+TIERED/RSC-_SEATS_FIXED_TIERED,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+WHITEBOARD/RSC-_WHITEBOARD,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SCREEN/RSC-_SCREEN,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SYM/RSC-_SYM,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+WIRELESS+NETWORK/RSC-_WIRELESS_NETWORK,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DISABLED+ACCESS+-+AUDIENCE+%28X%29+Not+Egress+Standard+%28No+access+for+wheelchairs%2C+difficult+access+for+semi-ambulates%29/RSC-_DISABLED_ACCESS_-_AUDIENCE_%28X%29_Not_Egress_Standard_%28No_access_for_wheelchairs%2C_difficult_access_for_semi-ambulates%29
→ dcterms:spatial → "POLYGON((-1.3948060568 50.9355215111,-1.3947720107 50.9355708761,-1.3947005048 50.9355500998,-1.3947342814 50.9355006781,-1.3948060568 50.9355215111))"^^xsd:string
→ rdfs:label → "Lecture Theatre H"^^xsd:string,
"05 / 2015 (L/T H)"^^xsd:string
→ geo:lat → "50.93559114"^^xsd:float
→ skos:notation → "5-2015"^^http://id.southampton.ac.uk/ns/room-code-scheme
→ dcterms:spatial → "POLYGON((-1.3949990149 50.9355776129,-1.3949633518 50.9356264684,-1.3949530212 50.935623468,-1.3948892408 50.9356048995,-1.3949240954 50.9355557609,-1.3949990149 50.9355776129))"^^xsd:string
→ rdfs:label → "Lecture Theatre J"^^xsd:string,
"05 / 2017 (L/T J)"^^xsd:string
→ geo:lat → "50.93562026"^^xsd:float
→ skos:notation → "5-2017"^^http://id.southampton.ac.uk/ns/room-code-scheme
→ oo:hasFeature → http://id.southampton.ac.uk/syllabus/room-feature/RSC-+BENCH+PC/RSC-_BENCH_PC,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DATA%2FVIDEO+REPLAY%2FPROJECTION/RSC-_DATA%2FVIDEO_REPLAY%2FPROJECTION,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DISABLED+ACCESS+-+INSTRUCTOR+%28A%29+Ground+Floor+Room+Fully+Accessible/RSC-_DISABLED_ACCESS_-_INSTRUCTOR_%28A%29_Ground_Floor_Room_Fully_Accessible,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+IND/RSC-_IND,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+LAP/RSC-_LAP,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SEATS+FIXED+TIERED/RSC-_SEATS_FIXED_TIERED,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+WHITEBOARD/RSC-_WHITEBOARD,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SCREEN/RSC-_SCREEN,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+SYM/RSC-_SYM,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+WIRELESS+NETWORK/RSC-_WIRELESS_NETWORK,
http://id.southampton.ac.uk/syllabus/room-feature/RSC-+DISABLED+ACCESS+-+AUDIENCE+%28X%29+Not+Egress+Standard+%28No+access+for+wheelchairs%2C+difficult+access+for+semi-ambulates%29/RSC-_DISABLED_ACCESS_-_AUDIENCE_%28X%29_Not_Egress_Standard_%28No_access_for_wheelchairs%2C_difficult_access_for_semi-ambulates%29
→ dcterms:spatial → "POLYGON((-1.3950710598 50.9355985024,-1.3950242576 50.9356624731,-1.3949629925 50.9356457162,-1.3949515839 50.9356423761,-1.3949585908 50.9356328654,-1.3949633518 50.9356264684,-1.3949990149 50.9355776129,-1.3950710598 50.9355985024))"^^xsd:string
→ rdfs:label → "Scanning Kelvin Probe System"^^xsd:string
→ dcterms:description → "The SKP5050 system is our best-selling Kelvin[nl]
Probe system. This is the configuration we use[nl]
in-house for client samples. It is based upon the[nl]
ASKP system but includes highly recommended[nl]
options including color camera/TFT monitor, 2mm[nl]
and 50µm tips, external digital oscilloscope and an [nl]
extended warranty."^^xsd:string
→ skos:notation → "E10531"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "The SKP5050 system is our best-selling Kelvin[nl]
Probe system. This is the configuration we use[nl]
in-house for client samples. It is based upon the[nl]
ASKP system but includes highly recommended[nl]
options including color camera/TFT monitor, 2mm[nl]
and 50µm tips, external digital oscilloscope and an [nl]
extended warranty."^^xsd:string
→ dc:description → "The SKP5050 system is our best-selling Kelvin[nl]
Probe system. This is the configuration we use[nl]
in-house for client samples. It is based upon the[nl]
ASKP system but includes highly recommended[nl]
options including color camera/TFT monitor, 2mm[nl]
and 50µm tips, external digital oscilloscope and an [nl]
extended warranty."^^xsd:string
→ rdfs:label → "Digital Volume Correlation Software"^^xsd:string
→ dcterms:description → "Quantitative imaging analysis software. DVC is not only capable of identifying defects and cracks before they are visible in the raw image, but it is also able to quantify the full volume strain distribution and actual magnitudes of the material displacements surrounding discontinuities. The level of information is extremely useful in validating Finite Element models of modern complex materials. Volume images can be imported into the software from a variety of sources such as:[nl]
¿X-Ray Computer Tomography [nl]
¿Magnetic Resonance Imaging (MRI)[nl]
¿Optical Coherence Tomography (OCT)[nl]
¿Confocal Microscopy"^^xsd:string
→ skos:notation → "E10533"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "Quantitative imaging analysis software. DVC is not only capable of identifying defects and cracks before they are visible in the raw image, but it is also able to quantify the full volume strain distribution and actual magnitudes of the material displacements surrounding discontinuities. The level of information is extremely useful in validating Finite Element models of modern complex materials. Volume images can be imported into the software from a variety of sources such as:[nl]
¿X-Ray Computer Tomography [nl]
¿Magnetic Resonance Imaging (MRI)[nl]
¿Optical Coherence Tomography (OCT)[nl]
¿Confocal Microscopy"^^xsd:string
→ dc:description → "Quantitative imaging analysis software. DVC is not only capable of identifying defects and cracks before they are visible in the raw image, but it is also able to quantify the full volume strain distribution and actual magnitudes of the material displacements surrounding discontinuities. The level of information is extremely useful in validating Finite Element models of modern complex materials. Volume images can be imported into the software from a variety of sources such as:[nl]
¿X-Ray Computer Tomography [nl]
¿Magnetic Resonance Imaging (MRI)[nl]
¿Optical Coherence Tomography (OCT)[nl]
¿Confocal Microscopy"^^xsd:string
→ dcterms:description → "The centre houses strategic research facilities for the microstructural characterisation of materials by high resolution imaging, crystallographyand nano/micro-area chemical analysis. Both scanning and transmission electron microscopes (SEM & TEM) are available. SEM (JSM6500F) has a resolution of 1.5nm for surface imaging and chemical microanalysis at micron scale. TEM (JEM 3010) has a resolution of 0.21nm with an accelerating voltage 300kv, high tilt polepieces (± 42 degrees) for crystallographic analysis at nano scale. The centre has a full range of preparation facilities including carbon coating, gold sputter coating, ion beam thinning, disc punch/grinding, mechanical dimpling and electropolishing."^^xsd:string
→ skos:notation → "F10026"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "The centre houses strategic research facilities for the microstructural characterisation of materials by high resolution imaging, crystallographyand nano/micro-area chemical analysis. Both scanning and transmission electron microscopes (SEM & TEM) are available. SEM (JSM6500F) has a resolution of 1.5nm for surface imaging and chemical microanalysis at micron scale. TEM (JEM 3010) has a resolution of 0.21nm with an accelerating voltage 300kv, high tilt polepieces (± 42 degrees) for crystallographic analysis at nano scale. The centre has a full range of preparation facilities including carbon coating, gold sputter coating, ion beam thinning, disc punch/grinding, mechanical dimpling and electropolishing."^^xsd:string
→ dc:description → "The centre houses strategic research facilities for the microstructural characterisation of materials by high resolution imaging, crystallographyand nano/micro-area chemical analysis. Both scanning and transmission electron microscopes (SEM & TEM) are available. SEM (JSM6500F) has a resolution of 1.5nm for surface imaging and chemical microanalysis at micron scale. TEM (JEM 3010) has a resolution of 0.21nm with an accelerating voltage 300kv, high tilt polepieces (± 42 degrees) for crystallographic analysis at nano scale. The centre has a full range of preparation facilities including carbon coating, gold sputter coating, ion beam thinning, disc punch/grinding, mechanical dimpling and electropolishing."^^xsd:string
→ skos:notation → "E10544"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ skos:notation → "E10545"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ skos:notation → "E10547"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:label → "Benchtop Ct 160Xi X-Ray Inspection System"^^xsd:string
→ skos:notation → "E10552"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:label → "Pyris 1 Dsc Subambient Rady Sys-Intraco"^^xsd:string
→ skos:notation → "E10563"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:label → "Nikon - HMX: 225kV Microfocus Computed Tomography Scanner"^^xsd:string
→ dcterms:description → "This is a custom Nikon XTEK XTH 225 kVp micro-focus CT system equipped with a robotic sample exchanger (~ 150 mm height limit). It is perfect for relatively small specimens (< 300 mm in height) that can be scanned using a 225 kVp X-Ray source. The source can be configured for high resolution or high flux through a range of different anodes; namely a transmission anode (spot ≥ 1 µm, low flux), a standard multi-material reflection anode (spot ≥ 3 µm, 'normal' flux) and a rotating anode (spot ≥ 10µm, x3 -5 flux). A labyrinth at the rear of the system allows routing of cables and pipes that can control and feed in-situ rigs for time-resolved (4D) µ-CT experiments."^^xsd:string
→ skos:notation → "E10884"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "This is a custom Nikon XTEK XTH 225 kVp micro-focus CT system equipped with a robotic sample exchanger (~ 150 mm height limit). It is perfect for relatively small specimens (< 300 mm in height) that can be scanned using a 225 kVp X-Ray source. The source can be configured for high resolution or high flux through a range of different anodes; namely a transmission anode (spot ≥ 1 µm, low flux), a standard multi-material reflection anode (spot ≥ 3 µm, 'normal' flux) and a rotating anode (spot ≥ 10µm, x3 -5 flux). A labyrinth at the rear of the system allows routing of cables and pipes that can control and feed in-situ rigs for time-resolved (4D) µ-CT experiments."^^xsd:string
→ dc:description → "This is a custom Nikon XTEK XTH 225 kVp micro-focus CT system equipped with a robotic sample exchanger (~ 150 mm height limit). It is perfect for relatively small specimens (< 300 mm in height) that can be scanned using a 225 kVp X-Ray source. The source can be configured for high resolution or high flux through a range of different anodes; namely a transmission anode (spot ≥ 1 µm, low flux), a standard multi-material reflection anode (spot ≥ 3 µm, 'normal' flux) and a rotating anode (spot ≥ 10µm, x3 -5 flux). A labyrinth at the rear of the system allows routing of cables and pipes that can control and feed in-situ rigs for time-resolved (4D) µ-CT experiments."^^xsd:string
→ dcterms:description → "A dedicated centre for computed tomography (CT) at Southampton, providing complete support for 3D imaging science, serving Engineering, Biomedical, Environmental and Archaeological Sciences. The centre encompasses five complementary scanning systems supporting a wide range of sample sizes (imaged volumes up to 1.5 x 1 x 1m) and resolution (down to ~200nm). Both academic and industrial consultancy services are provided."^^xsd:string
→ skos:notation → "F10025"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "A dedicated centre for computed tomography (CT) at Southampton, providing complete support for 3D imaging science, serving Engineering, Biomedical, Environmental and Archaeological Sciences. The centre encompasses five complementary scanning systems supporting a wide range of sample sizes (imaged volumes up to 1.5 x 1 x 1m) and resolution (down to ~200nm). Both academic and industrial consultancy services are provided."^^xsd:string
→ dc:description → "A dedicated centre for computed tomography (CT) at Southampton, providing complete support for 3D imaging science, serving Engineering, Biomedical, Environmental and Archaeological Sciences. The centre encompasses five complementary scanning systems supporting a wide range of sample sizes (imaged volumes up to 1.5 x 1 x 1m) and resolution (down to ~200nm). Both academic and industrial consultancy services are provided."^^xsd:string
→ rdfs:label → "Zeiss - Xradia 510 Versa: High-resolution computed tomography scanner"^^xsd:string
→ dcterms:description → "This scanner uses a two-stage magnification approach to achieve sub-micron spatial resolution at source to object distance much greater than these allowed in conventional XCT systems. Zeiss’s resolution at a distance, RaaDTM, approach combines the geometric magnification of the X-Ray imaging with a smart system of microscope lenses to further magnify the image. The system is fitted with X0.4, X4, X20, and X40 magnification lens mounted on a barrel mount for rapid change over. This means that the operator can achieve submicron resolution (pixel size ≥ 70 nm or spatial resolution ≥ 0.7 µm) at large working distances, allowing for imaging of larger specimens or small specimens in contained in-situ rings. Importantly, the machine is capable of phase-contrast imaging overcoming an imortant limitations of convectional absorption-based CT imaging; i.e. low or complete absence of contrast for low Z materials. The latter is particular useful for biomedical imaging, CFRP and polymer imaging appl"^^xsd:string
→ skos:notation → "E10960"^^http://id.southampton.ac.uk/ns/equipment-code-scheme
→ rdfs:comment → "This scanner uses a two-stage magnification approach to achieve sub-micron spatial resolution at source to object distance much greater than these allowed in conventional XCT systems. Zeiss’s resolution at a distance, RaaDTM, approach combines the geometric magnification of the X-Ray imaging with a smart system of microscope lenses to further magnify the image. The system is fitted with X0.4, X4, X20, and X40 magnification lens mounted on a barrel mount for rapid change over. This means that the operator can achieve submicron resolution (pixel size ≥ 70 nm or spatial resolution ≥ 0.7 µm) at large working distances, allowing for imaging of larger specimens or small specimens in contained in-situ rings. Importantly, the machine is capable of phase-contrast imaging overcoming an imortant limitations of convectional absorption-based CT imaging; i.e. low or complete absence of contrast for low Z materials. The latter is particular useful for biomedical imaging, CFRP and polymer imaging appl"^^xsd:string
→ dc:description → "This scanner uses a two-stage magnification approach to achieve sub-micron spatial resolution at source to object distance much greater than these allowed in conventional XCT systems. Zeiss’s resolution at a distance, RaaDTM, approach combines the geometric magnification of the X-Ray imaging with a smart system of microscope lenses to further magnify the image. The system is fitted with X0.4, X4, X20, and X40 magnification lens mounted on a barrel mount for rapid change over. This means that the operator can achieve submicron resolution (pixel size ≥ 70 nm or spatial resolution ≥ 0.7 µm) at large working distances, allowing for imaging of larger specimens or small specimens in contained in-situ rings. Importantly, the machine is capable of phase-contrast imaging overcoming an imortant limitations of convectional absorption-based CT imaging; i.e. low or complete absence of contrast for low Z materials. The latter is particular useful for biomedical imaging, CFRP and polymer imaging appl"^^xsd:string
→ skos:notation → "5-1021"^^http://id.southampton.ac.uk/ns/room-code-scheme
→ skos:notation → "5-1023"^^http://id.southampton.ac.uk/ns/room-code-scheme
→ geo:lat → "50.93558759"^^xsd:float
→ dcterms:spatial → "POLYGON((-1.3946996065 50.9355713856,-1.394680113 50.9355981062,-1.3946696926 50.9356123722,-1.394640138 50.9356037673,-1.3946701417 50.9355627807,-1.3946768791 50.9355647621,-1.3946996065 50.9355713856))"^^xsd:string
→ geo:lat → "50.9355792"^^xsd:float
→ dcterms:spatial → "POLYGON((-1.3946701417 50.9355627807,-1.394640138 50.9356037673,-1.3946119309 50.9355956153,-1.3946419346 50.9355545721,-1.3946510076 50.9355572894,-1.3946701417 50.9355627807))"^^xsd:string
